Wz -SWW[20000309112924 20000309112924 2|TSTYS STAI@ "STCO HUCOY*SUBH*COCO*ELEV@@*LATD *LNGD  *DESC .  *DARE @N *MINV n (MAXV (MEAN (STDD (SKEW (TCOD@ 2LCOD@6 *ACOD@L *VCOD@b *VLCOx *DCOD@ *GCOD@ *SLOP@ *RMIL@ *LENG *TSBY@ 0TSBM@ (TSBD@: (TSBH@X (TSPRv (TSFI *TSST! 2TGRO" 0RWFL#e *TOLR$@@ (HELP%@@ DONE&@@ ALL '@@ AGEN(  !STFI) *DSCO* *CONT+7 *SITE,Y  STAN- &GUCO. !WELL/ *AQTY0  BASE1@@*DATE2@@d Type of timeseries data. m User-defined four-character descriptor. Used to describe the contents of the data set, for example: PRCP, RAIN, SNOW - Precipitation FLOW, DISC, PEAK - discharge TEMP, TMIN, TMAX - temperature EVAP, PET - evapotranspiration Some models and application programs may require a specific TSTYPE for datasets they use. ; Station identification, up to 16 alpha-numeric characters.  Alpha-numberic station id.  State abbreviation codeNON AL AK AZ AR CA CO CT DE FL GA HI ID IL IN IA KS KY LA ME MD MA MI MN MS MO MT NE NV NH NJ NM NY NC ND OH OK ORBFIM!(,3;qZ-YUQVCzHa/+ZYIUKt]NZP\JOL,` PA RI SC SD TN TX UT VT VA WA WV WI WY PR DC VI PI GU  Standard 2-character post office abbreviation, includes DC - Washington, District of Columbia PR - Puerto Rico VI - Virgin Islands GU - Guam PI - Pacific Trust Territories Use NON for no state abbreviation. ! Hydrologic unit code (8 digits).   Hydrologic unit code (8 digits). These codes are given in the U.S. Geological Survey map series "State Hydrologic Unit Maps," Open File Report 84- 708. , Extension to hydrologic unit code (HUCODE).'  Extension to hydrologic unit code (HUCODE). See the U.S. Geological Survey map series "State Hydrologic unit maps," Open File Report 84-708.  County or parish code.  E County or parish code. See WATSTORE users manual, Appendix C.  Elevation (msl). yy  Elevation (mean sea level).  Latitude (degrees).yy  Latitude in decimal degrees. Longitude (degrees). yy ! Longitude in decimal degrees.  Data-set description. [ Data-set description. Might be name and/or location, or some anecdotal information.  Drainage area. y N Total drainage area, in square miles, including non-contributing areas.  Minimum value in dataset. yy + Minimum value in data set, general use.  Maximum value in dataset. yy + Maximum value in data set, general use. ! Mean value of values in dataset. yy , Mean of values in data set, general use.) Standard deviation of values in dataset. yy = Standard deviation of values in data set, general use.  Skew coefficient yy ; Skew coefficient of values in data set, general use.  Time units code.   Time units code. 1 - seconds 4 - days 2 - minutes 5 - months 3 - hours 6 - years Used in combination with TSSTEP. Length units code.  $ Length units code, user defined. Area units code.  " Area units code, user defined.  Volume units code.  $ Volume units code, user defined. Velocity units code & Velocity units code, user defined.  Attribute DCODE  Attribute DCODE  Angle (slope) code. % Angle (slope) code, user defined.  Slope. yy " Slope, units are user defined.  Distance from mouth, in miles. yy &Distance from basin outlet, in miles.  Channel length.y ' Channel length, units user defined. Base year. @B lO Starting year for time-series data in a data set. Defaults to year 1900. Base month   X Starting month for time-series data in a data set. Defaults to month 1 (January). Base day.  J Starting day for time-series data in a data set. Defaults to day 1. Base hour.  L Starting hour for time-series data in a data set. Defaults to hour 1. New group, new record flag.  New group, new record flag: 0 - start new group at the end of the last group (default) 1 - start new group at the beginning of a record.  Timeseries filler value. yy b Time-series filler value. This value will be used for missing values. The default is 0.0. " Primary timestep, in TCODE units.  B Time step, in TCODE units (used in combination with TCODE).  Unit for group pointers.  q Unit for group pointers, depending on the time step of the data, may effect the speed of data retrievals. The default group pointer is 6 (years). For timeseries data with a timestep of an hour or less, monthly or even daily group pointers may be more efficient. 3 - hours 6 - years 4 - days 7 - centuries 5 - months  Read/Write flag.  ; Read/Write flag: 0 - read and write 1 - read only  Data compression tolerance.yy w+2 Data compression tolerance. Data values within +- of TOLR will be considered the same value and compressed in the data set. Once data has been compressed, the original values can not be retrieved. Agency code. D Agency code. See WATSTORE users manual, volume 1, chapter 3. State FIPS code. c > State FIPS code, see WATSTORE users manual, Appendix B.  District code. c  State code of the Geological Survey office that operates the station. Usually the same as the state code (STPIPS). See WATSTORE Users manual, Appendix B. Contributing drainage area.y J Drainage area, in square miles, that contributes to surface runoff. Site Code SW SP ES GW LK ME  Site code, see WATSTORE users manual, volume 1, chapter 3. SW - stream SP - spring ES - estuary GW - well LK - lake or reservoir ME - meteorological  Station name (48 characters). . Short name or description of the data set. $ Geologic unit code (7 characters).B Geologic unit code. See WATSTORE users manual, Appendix F. Well depth.y  Depth of well, in feet. The greatest depth at which water can enter the well. See WATSTORE users manual, volume 1, chapter 3.  Aquifer type. U N C M X  Aquifer type. See WATSTORE users manual, volume 1, chapter 3.. U - unconfined single aquifer N - unconfined multiple aquifers C - confined single aquifer M - confined multiple aquifers X - mixed multiple aquifers  Base discharge.y ` Base discharge, in cubic feet per second. See WATSTORE user manual, volume 1, chapter ?. Date (year,mo,dy,hr,mi,sc)  # Date string. User defined use.   -SWW[20000309112924 20000309112924 2ISTA3S*STAR4@pEND 5@@LATD6*LNGD7*PARM8*STAT9*PREC: *STOR;m*TSPT<(FORE=*SOIL>*I24-?d\W*JANM@*P1.2Aj@*P2. B@@*P5. C@@U*P10.D@@*P25.E@@*P50.F@@*P100G\@L*P200H\@*P500I\@*MEANJ *SDPKK@@Z*SKWPL@*WRCSM*WRCMN@Z*WRCSO@*YRSPP@*YRSHQ]*CHEAR@*COMPS(TSFOT&0VBTIUd0BSLOV*BLNGW*VALLX*EL10YpjW*EL50Z``*EL60[``*LAKE\@@*GLAC]]*LOES^@*AZMU_*LATC`*LNGCaU*TMTOb*I240cb`*I240ddj4* Station identification number.  2 Integer indentification number, as an integer. " Starting date for timeseries data  ! Ending data for timeseries data.  & Latitude (degrees, minutes, seconds).  4 Latitude in degrees, minutes, seconds (dddmmss).' Longitude (degrees, minutes, seconds).  5 Longitude in degrees, minutes, seconds (dddmmss).  Parameter code. = Parameter code, see WATSTORE users manual, Appendix D.  Statistics code.  > Statistics code, see WATSTORE users m anual, Appendix E.  Mean annual precipitation. y E Mean annual precipitation, in inches, from U.S. Weather Bureau Series "Climates of States;" grid sampling methods used if isohyetal map is available, otherwise anomaly map constructed (Water-Supply Paper 1580-d). Basin and streamflow characteristics no 32, PRECIP. See WATSTORE users manual, Appendix. 0 Area of lakes, ponds, and swamps (% of CONTDA).B  Area of lakes, ponds, and swamps in percent of contributing drainage area, measured by the grid sampling methods. Basin and streamflow chracteristics no 12, STORAGE. See WATSTORE users manual, Appendix.0 Timeseries put aggregation/disaggregation code. 3 Timeseries put aggregation/disaggregation code.  Forested area (% of CONTDA)B  Forested area in percent of contributing drainage area, measured by the grid sampling methods. Basin and streamflow charachteristic no 14, FOREST. See WATSTORE users manual, Appendix. Soils index, in inches.y  Soils index, in inches, a relative measure of potential infiltration (soil water storage), from Soil Conservation Service. Basin and streamflow characteristic no 16, SOIL INF. 0 24-hour rainfall precip intensity 2-year recurry  Precipitation intensity, 24-hour rainfall, in inches, expected on the average of once each 2 years. Basin and streamflow characteristic no 33, I24,2. See WATSTORE users manual, Appendix. ) Mean minimum January temp, in degrees F. yy  Mean minimum January temp, in degrees F. Basin and streamflow characteristic no 60, JANMIN. See WATSTORE users manual, Appendix. ) Annual flood peak, 1.25 year recurrence. y  Annual flood peak, in cubic feet per second, 1.25- year recurrence interval. Basin and streamflow characteristic no 75, P1,25. See WATSTORE users manual, Appendix. & Annual flood peak, 2 year recurrence. y  Annual flood peak, in cubic feet per second, 2- year recurrence interval. Basin and streamflow characteristic no 76, P2. See WATSTORE users manual, Appendix.& Annual flood peak, 5 year recurrence. y  Annual flood peak, in cubic feet per second, 5- year recurrence interval. Basin and streamflow characteristic no 77, P5. See WATSTORE users manual, Appendix.' Annual flood peak, 10 year recurrence. y  Annual flood peak, in cubic feet per second, 10- year recurrence interval. Basin and streamflow characteristic no 78, P10. See WATSTORE users manual, Appendix. ' Annual flood peak, 25 year recurrence. y  Annual flood peak, in cubic feet per second, 25- year recurrence interval. Basin and streamflow characteristic no 79, P25. See WATSTORE users manual, Appendix. ' Annual flood peak, 50 year recurrence. y  Annual flood peak, in cubic feet per second, 50- year recurrence interval. Basin and streamflow characteristic no 80, P50. See WATSTORE users manual, Appendix. ( Annual flood peak, 100 year recurrence.y  Annual flood peak, in cubic feet per second, 100- year recurrence interval. Basin and streamflow characteristic no 81, P100. See WATSTORE users manual, Appendix.( Annual flood peak, 200 year recurrence.y  Annual flood peak, in cubic feet per second, 200- year recurrence interval. Basin and streamflow characteristic no 82, P200. See WATSTORE users manual, Appendix.( Annual flood peak, 500 year recurrence.y  Annual flood peak, in cubic feet per second, 500- year recurrence interval. Basin and streamflow characteristic no 178, P500. See WATSTORE users m anual, Appendix. , Mean of the LOG of systematic annual peak Qy@  Mean of the logarithms, base 10, of systematic annual peak discharges from Bulletin 17B frequency analysis or WATSTORE program J407. Basin and streamflow characteristic no 83, MEANPK. See WATSTORE users manual, Appendix. . Standard deviation of LOG of syst ann peak Q. @  Standard deviation of logarithms, base 10, of systematic annual peak discharges, from Bulletin 17B frequency analysis or WATSTORE program J407.. Basin and streamflow characteristic no 84 SDPK. See WATSTORE users manual, Appendix. 0 Skew of LOG of systematic annual peak Q (J407).A  Skew of logarithms, base 10, of systematic annual peak discharges, from Bulletin 17B frequency analysis or WATSTORE program J407. Basin and streamflow characteristic no 85, SKEWPK. See WATSTORE users manual, Appendix. " WRC skew of LOG of peak Q (J407). A 7 WRC skew of logarithms, base 10, of annual peak discharge after outlier and historic-peak adjustments and generalized skew weighting, from Bulletin 17B grequency analysis or WATSTORE program J407. Basin and streamflow characteristic no 179, WRC SKEW. See WATSTORE users manual, Appendix. " WRC mean of LOG of peak Q (J407). y@  WRC mean of logarithms, base 10, of annual peak discharge after outlier and historic-peak adjustments, from Bulletin 17B frequency analysis or WATSTORE program J407. Basin and streamflow characteristic no 180, WRC MEAN. See WATSTORE users manual, Appendix. 0 WRC standard deviation of LOG of peak Q (J407).@ " WRC standard deviation of logarithms, base 10, of annual peak discharge after outlier and historic- peak adjustments, from Bulletin 17B frequency analysis or WATSTORE program J407. Basin and streamflow characteristics no 181, WR C SD. See WATSTORE users manual, Appendix. 0 Number of years of systematic peak flow record.y  Number of years of systematic peak flow record, used in Bulletin 17B frequency analysis or WATSTORE program J407. Basin and streamflow characteristic no 196, YRSPK. See WATSTORE users manual, Appendix. 0 No. of consecutive yrs used for hist-pk adjust.y  Number of consecutive years used for historic-peak adjustment to flood-frequency data used in Bulletin 17B frequency analysis or WATSTORE program J407. Basin and streamflow characteristic no 197, YRSHISPK. See WATSTORE users manual, Appendix. % Pointer to associated quality flags. } r Pointer to an associated data set. Used to associate quality flags for peak flow data, needed for J407.  Compression flag   Compression flag 1 - yes, data are compressed (default) 2 - no, data are not compressed compressed data will take up less space in the WDM file, but will require a COPY operation to update data values. Form of data   Form of data 1 - mean over the timestep (default) 2 - total over the timestep 3 - instantaneous @ time (end of timestep) 4 - minimum over the timestep 5 - maximum over the timestep  Variable time-step option  y Variable time-step option for the data set 1 - all data are at the same time step 2 - time step may vary (default)  Average basin slopeyy  Average basin slope, in feet per mile. Measured by grid sampling method. Basin and streamflow characteristic no 4, BSLOPE. See WATSTORE users manual, Appendix. . Stream length, gage to end of defined channel y  Stream length, in miles, from gage to end of defined channel, blue line on topographic map. Basin and streamflow characteristic no 6, BLENGTH. See WATSTORE users manual, Appendix.* Valley length, from gage to basin divide. y  Valley length, in miles, measured along general path of flood plain from gage to basin divide. Basin and streamflow characteristic no 7, VALLGH. See WATSTORE users manual, Appendix.  Average of channel elevations yy  Average of channel elevations, in feet above mean sea level, at points 10- and 85-percent of stream length upstream from gage. Basin and streamflow characteristic no 9, ELV10,85. See WATSTORE users manual, Appendix. , Percent of basin above elevation 5000 feet.B  Percent of basin above elevation 5000 feet, mean sea level. Basin and streamflow characteristic no 10, EL5000. See WATSTORE users manual, Appendix. , Percent of basin above elevation 6000 feet.B  Percent of basin above elevation 5000 feet, mean sea level. Basin and streamflow characteristic no 11, EL6000. See WATSTORE users manual, Appendix. # Lakes and ponds area (% of CONTDA) B  Area of lakes and ponds in percent of contributing drainage area. Measured by the grid sampling method. Basin and streamflow characteristic no 13, LAKE. See WATSTORE users manual, Appendix.  Area of glaciers (% of CONTDA) B  Area of glaciers in percent of contributing drainage area. Basin and streamflow characteristic no 15, GLACIER. See WATSTORE users manual, Appendix. # Depth of surficial loess, in feet. y  Depth of surficial loess, in feet. From Soil Conservation Service. Basin and streamflow characteristic no 17, LOESS. See WATSTORE users manual, Appendix. Azimuth, from north. C  Azimuth, in decimal degrees from north of a straight line connecting points 85- and 10-percent of distance from gage to divide. Ba sin and streamflow characteristic no 18, AZIMUTH. See WATSTORE users manual, Appendix. . Latitude of center of basin, decimal degrees. yy  Latitude of center of basin, decimal degrees. Basin and streamflow characteristic no 19, LAT. See WATSTORE users manual, Appendix./ Longitude of center of basin, decimal degrees. yy  Longitude of center of basin, decimal degrees. Basin and streamflow characteristic no 20, LONG. See WATSTORE users guide, Appendix.  Time to peak, in hours.y  Time, in hours, measured as time difference between center of mass of total rainfall and peak discharge. Basin and streamflow characteristic no 21, TIMETOPK. See WATSTORE users manual, Appendix. 0 24-hour rainfall intensity, 10-year recurrence.y > Precipitation intensity, 24-hour rainfall, in inches, expected on the average once each 10 years. Estimated from U.S. Weather Bureau technical Paper 40 except for western states where NOAA Atlas 2 exists). Basin and streamflow characteristic no 34, I24,10. See WATSTORE users manual, Appendix. 0 24-hour rainfall intensity, 25-year recurrence.y > Precipitation intensity, 24-hour rainfall, in inches, expected on the average once each 25 years. Estimated from U.S. Weather Bureau technical Paper 40 except for western states where NOAA Atlas 2 exists). Basin and streamflow characteristic no 35, I24,25. See WATSTORE users manual, Appendix.  -SWW[20000309112924 20000309112924 2,I240ej`S*I241f``*PRCOg *PRCNhW *PRCDi *PRCJj *PRCFk *PRCMl7!*PRCAmm!*PRCMn!*PRCJo!*PRCJp"*PRCAqI"*PRCSr"*SNOFs"*SNOMt"*SNOAuC#*SN00vd@#*SN01w`@#*SN02xj@3$*SN10y`@$*JANAz$*MARM{%*JULM|a%*JULA}%*WEMA~d%*LKEVB&*PNEV&*FROS@&*QANN@@ '*QSDAL'*QOCT@@'*QNOV@@'*QDEC@@%(*QJAN@@j(*QFEB@@(*QMAR@@(*QAPR@@5)*QMAY@@x)*QJUN@@)*QJUL@@)*QAUG@@B**QSEP@@**QSDO**QSDN+*QSDDg+*QSDJ+*QSDF,*QSDMV,*QSDA,*0 24-hour rainfall intensity, 50-year recurrence.y > Precipitation intensity, 24-hour rainfall, in inches, expected on the average once each 50 years. Estimated from U.S. Weather Bureau technical Paper 40 except for western states where NOAA Atlas 2 exists). Basin and streamflow characteristic no 36, I24,50. See WATSTORE users manual, Appendix. 0 24-hour rainfall intensity, 100-year recurrencey @ Precipitation intensity, 24-hour rainfall, in inches, expected on the average once each 100 years. Estimated from U.S. Weather Bureau technical Paper 40 except for western states where NOAA Atlas 2 exists). Basin and streamflow characteristic no 37, I24,100. See WATSTORE users manual, Appendix./ October mean monthly precipitation, in inches. y  October mean monthly precipitation, in inches. Basin and streamflow characteristic no 41, PRC10. See WATSTORE users manual, Appendix. 0 November mean monthly precipitation, in inches.y  November mean monthly precipitation, in inches. Basin and streamflow characteristic no 42, PRC11. See WATSTORE users manual, Appendix.0 December mean monthly precipitation, in inches.y  December mean monthly precipitation, in inches. Basin and streamflow characteristic no 43, PRC12. See WATSTORE users manual, Appendix./ January mean monthly precipitation, in inches. y  January mean monthly precipitation, in inches. Basin and streamflow characteristic no 44, PRC12. See WATSTORE users manual, Appendix. / February mean monthly precipitation, in inches y  February mean monthly precipitation, in inches Basin and streamflow characteristic no 45, PRC2. See WATSTORE users manual, Appendix. , March mean monthly precipitation, in inchesy  March mean monthly precipitation, in inches Basin and streamflow characteristic no 46, PR3. See WATSTORE users manual, Appendix. , April mean monthly precipitation, in inchesy  April mean monthly precipitation, in inches Basin and streamflow characteristic no 47, PR4. See WATSTORE users manual, Appendix. * May mean monthly precipitation, in inches y  May mean monthly precipitation, in inches Basin and streamflow characteristic no 48, PRC5. See WATSTORE users manual, Appendix. + June mean monthly precipitation, in inches y  June mean monthly precipitation, in inches Basin and streamflow characteristic no 49, PRC6. See WATSTORE users manual, Appendix. , July mean monthly precipitation, in inches.y  July mean monthly precipitation, in inches. Basin and streamflow characteristic no 50, PRC7. See WATSTORE users manual, Appendix. . August mean monthly precipitation, in inches. y  August mean monthly precipitation, in inches. Basin and streamflow characteristic no 51, PRC8. See WATSTORE users manual, Appendix. 0 September mean monthly precipitation, in inchesy  September mean monthly precipitation, in inches Basin and streamflow characteristic no 52, PRC9. See WATSTORE users manual, Appendix. ! Mean annual snowfall, in inches. y  Mean annual snowfall, in inches. From U. S. Weather Bureau, "Climates of States". Basin and streamflow characteristic no 53, SNOFALL. See WATSTORE users manual, Appendix. - March 1 mean water equivalent of snow cover. y  Mean water equivalent, in inches, of snow cover as of March 1. From U. S. Weather Bureau, Technical Paper 50. Basin and streamflow characteristic no 54, SNOMAR. See WATSTORE users manual, Appendix. / April 30, mean water equivalent of snow cover. y  Mean water equivalent, in inches, of snow cover as of April 30. From U. S. Weather Bureau, Technical Paper 50. Basin and streamflow characteristic no 55, SNOAPR. See WATSTORE users manual, Appendix. , March 15 max water equiv, 2-year recurrencey  Maximum water equivalent, in inches, of snow cover as of March 15, 2-year recurrence interval. From U.S. Weather Bureau, Technical Paper 50. Basin and streamflow characteristic no 56, SN2. See WATSTORE users manual, Appendix.- March 15 max water equiv, 10-year recurrence y  Maximum water equivalent, in inches, of snow cover as of March 15, 10-year recurrence interval. From U.S. Weather Bureau, Technical Paper 50. Basin and streamflow characteristic no 57, SN10. See WATSTORE users manual, Appendix. - March 15 max water equiv, 25-year recurrence y  Maximum water equivalent, in inches, of snow cover as of March 15, 25-year recurrence interval. From U.S. Weather Bureau, Technical Paper 50. Basin and streamflow characteristic no 58, SN25. See WATSTORE users manual, Appendix. . March 15 max water equiv, 100-year recurrence y  Maximum water equivalent, in inches, of snow cover as of March 15, 100-year recurrence interval. From U.S. Weather Bureau, Technical Paper 50. Basin and streamflow characteristic no 59, SN100. See WATSTORE users manual, Appendix., Mean temperature for January, in degrees F.yy  Mean monthly temperature for January, in degrees F. From U.S. Weather Bureau, "Climates of States". Basin and streamflow characteristic no 61, JANAV. See WATSTORE users manual, Appendix.. Mean maximum March temperature, in degrees F. yy  Mean maximum March temperature, in degrees F. From U.S. Weather Bureau, "Climates of States". Basin and streamflow characteristic no 62, MARMAX. See WATSTORE users manual, Appendix. - Mean maximum July temperature, in degrees F. yy  Mean maximum July temperature, in degrees F. From U.S. Weather Bureau, "Climates of States". Basin and streamflow characteristic no 63, JULYMAX. See WATSTORE users manual, Appendix. ) Mean temperature for July, in degrees F. yy  Mean monthly temperature for July, in degrees F. From U.S. Weather Bureau, "Climates of States". Basin and streamflow characteristic no 64, JULYAV See WATSTORE users manual, Appendix.0 March snow cover water equiv, 2-year recurrencey  Water equivalent, in inches, of snow cover as of the first week in March, 2-year recurrence interval. Data compiled by the New Your District USGS. Basin and streamflow characteristic no 65, WE MAR2. See WATSTORE users manual, Appendix. ) Mean annual lake evaporation, in inches. y  Mean annual lake evaporation, in inches. From U.S. Weather Bureau, Technical Paper 37. Basin and streamflow characteristic no 70, EVAP. See WATSTORE users manual, Appendix. 0 Mean annual Class A pan evaporation, in inches.y  Mean annual Class A pan evaporation, in inches. From U.S. Weather Bureau, Technical Paper 37. Basin and streamflow characteristic no 71, EVAPAN. See WATSTORE users manual, Appendix. , Mean frost depth on February 28, in inches.y  Mean frost depth on February 28, in inches. From U.S. Weather Bureau, "Climates of States". Basin and streamflow characteristic no 72, FROST. See WATSTORE users manual, Appendix.  Mean annual discharge, in cfs. y  Mean annual discharge, in cubic feet per second, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 86, QA. See WATSTORE users manual, Appendix. - Standard deviation of mean annual discharge. y  Standard deviation of mean annual discharge, in cubic feet per second, from WATSTORE flow variabliity program W4422. Basin and streamflow characteristic no 87, QSDANN. See WATSTORE users manual, Appendix. % Mean discharge, in cfs, for October. y  Mean discharge, in cubic feet per second, for October, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 88, Q10. See WATSTORE users manual, Appendix.& Mean discharge, in cfs, for November. y  Mean discharge, in cubic feet per second, for November, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 89, Q11. See WATSTORE users manual, Appendix. & Mean discharge, in cfs, for December. y  Mean discharge, in cubic feet per second, for December, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 90, Q12. See WATSTORE users manual, Appendix. % Mean discharge, in cfs, for January. y  Mean discharge, in cubic feet per second, for January, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 91, Q1. See WATSTORE users manual, Appendix. & Mean discharge, in cfs, for February. y  Mean discharge, in cubic feet per second, for February, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 92, Q2. See WATSTORE users manual, Appendix.# Mean discharge, in cfs, for March. y  Mean discharge, in cubic feet per second, for March, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 93, Q3. See WATSTORE users manual, Appendix. # Mean discharge, in cfs, for April. y  Mean discharge, in cubic feet per second, for April, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 94, Q4. See WATSTORE users manual, Appendix. ! Mean discharge, in cfs, for May. y  Mean discharge, in cubic feet per second, for May, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 95, Q5. See WATSTORE users manual, Appendix. ! Mean discharge, in cfs for June. y  Mean discharge, in cubic feet per second, for June, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 96, Q6. See WATSTORE users manual, Appendix." Mean discharge, in cfs, for July. y  Mean discharge, in cubic feet per second, for July, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 97, Q7. See WATSTORE users manual, Appendix.$ Mean discharge, in cfs, for August.y  Mean discharge, in cubic feet per second, for August, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 98, Q8. See WATSTORE users manual, Appendix. ' Mean discharge, in cfs, for September. y  Mean discharge, in cubic feet per second, for September, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 99, Q9. See WATSTORE users manual, Appendix. . Standard deviation for mean discarge October. y  Standard deviation, in cubic feet per second, of mean discarge for October. From flow variability computer program no. W4422. Basin and streamflow characteristic no 100, SDQ10. See WATSTORE users manual, Appendix.0 Standard deviation for mean discharge November.y  Standard deviation, in cubic feet per second, of mean discarge for November. From flow variability computer program no. W4422. Basin and streamflow characteristic no 101, SDQ11. See WATSTORE users manual, Appendix. 0 Standard deviation for mean discharge December.y  Standard deviation, in cubic feet per second, of mean discarge for December. From flow variability computer program no. W4422. Basin and streamflow characteristic no 102, SDQ12. See WATSTORE users manual, Appendix. / Standard deviation for mean discharge January. y  Standard deviation, in cubic feet per second, of mean discarge for January. From flow variability computer program no. W4422. Basin and streamflow characteristic no 103, SDQ1. See WATSTORE users manual, Appendix. 0 Standard deviation for mean discharge February.y  Standard deviation, in cubic feet per second, of mean discarge for February. From flow variability computer program no. W4422. Basin and streamflow characteristic no 104, SDQ2. See WATSTORE users manual, Appendix.- Standard deviation for mean discharge March. y  Standard deviation, in cubic feet per second, of mean discarge for March. From flow variability computer program no. W4422. Basin and streamflow characteristic no 105, SDQ3. See WATSTORE users manual, Appendix. , Standard deviation for mean discharge Aprily  Standard deviation, in cubic feet per second, of mean discarge for April. From flow variability computer program no. W4422. Basin and streamflow characteristic no 106, SDQ4. See WATSTORE users manual, Appendix.  -SWW[20000309112924 20000309112924 2Z@QSDMS/*QSDJ/*QSDJ/*QSDA;0*QSDS0*L010`d0*L010b`/1*L010d`1*L030`d1*L030b`82*L030d`2*L070`d2*L070`j@3*L070b`3*L070d`3*L140`dI4*L140b`4*L140d`4*L300`dP5*L300b`5*L300d`5*L900`d[6*L900b`6*L900d` 7*H010`dd7*H010`j7*H010b`8*H010d`l8*H010dj8*H010j`9*H011``t9*H030`d9*H030`j&:*H030b`|:*H030d`:*H030dj,;*H030j`;*H031``;*H070`d8<*H070`j<*H070b`<*H070d`<=*H070dj=*H070j`=*H071``H>*H150`d>*H150`j>*H150b`N?*H150d`?*H150dj?*+ Standard deviation for mean discharge May. y  Standard deviation, in cubic feet per second, of mean discarge for May. From flow variability computer program no. W4422. Basin and streamflow characteristic no 107, SDQ5. See WATSTORE users manual, Appendix. , Standard deviation for mean discharge June.y  Standard deviation, in cubic feet per second, of mean discarge for June. From flow variability computer program no. W4422. Basin and streamflow characteristic no 108, SDQ6. See WATSTORE users manual, Appendix., Standard deviation for mean discharge July.y  Standard deviation, in cubic feet per second, of mean discarge for July. From flow variability computer program no. W4422. Basin and streamflow characteristic no 109, SDQ7. See WATSTORE users manual, Appendix.- Standard deviation for mean discharge August y  Standard deviation, in cubic feet per second, of mean discarge for August. From flow variability computer program no. W4422. Basin and streamflow characteristic no 110, SDQ8. See WATSTORE users manual, Appendix. 0 Standard deviation for mean discharge Septembery  Standard deviation, in cubic feet per second, of mean discarge for September. From flow variability computer program no. W4422. Basin and streamflow characteristic no 111, SDQ9. See WATSTORE users manual, Appendix. " 1-day low flow, 2-year recurrence y  Annual minimum 1-day mean discharge, in cubic feet per second, for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 112, M1,2. See WATSTORE users manual, Appendix. # 1-day low flow, 10-year recurrence y  Annual minimum 1-day mean discharge, in cubic feet per second, for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 113, M1,10. See WATSTORE users manual, Appendix. # 1-day low flow, 20-year recurrence y  Annual minimum 1-day mean discharge, in cubic feet per second, for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 114, M1,20. See WATSTORE users manual, Appendix. " 3-day low flow, 2-year recurrence y  Annual minimum 3-day mean discharge, in cubic feet per second, for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 115, M3,2. See WATSTORE users manual, Appendix. # 3-day low flow, 10-year recurrence y  Annual minimum 3-day mean discharge, in cubic feet per second, for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 116, M3,10. See WATSTORE users manual, Appendix. 0 Annual mininum 3-day mean discharge, 20-year rey  Annual minimum 3-day mean discharge, in cubic feet per second, for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 117, M3,20. See WATSTORE users manual, Appendix. " 7-day low flow, 2-year recurrence y  Annual minimum 7-day mean discharge, in cubic feet per second, for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 118, M7,2. See WATSTORE users manual, Appendix. " 7-day low flow, 5-year recurrence y  Annual minimum 7-day mean discharge, in cubic feet per second, for 5-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 119, M7,5. See WATSTORE users manual, Appendix. # 7-day low flow, 10-year recurrence y  Annual minimum 7-day mean discharge, in cubic feet per second, for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 120, M7,10. See WATSTORE users manual, Appendix. # 7-day low flow, 20-year recurrence y  Annual minimum 7-day mean discharge, in cubic feet per second, for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 121, M7,20. See WATSTORE users manual, Appendix. # 14-day low flow, 2-year recurrence y  Annual minimum 14-day mean discharge, in cubic feet per second, for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 122, M14,2. See WATSTORE users manual, Appendix. $ 14-day low flow, 10-year recurrencey  Annual minimum 14-day mean discharge, in cubic feet per second, for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 123, M14,10. See WATSTORE users manual, Appendix. $ 14-day low flow, 20-year recurrencey  Annual minimum 14-day mean discharge, in cubic feet per second, for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 124, M14,20. See WATSTORE users manual, Appendix. # 30-day low flow, 2-year recurrence y  Annual minimum 30-day mean discharge, in cubic feet per second, for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 125, M30,2. See WATSTORE users manual, Appendix. $ 30-day low flow, 10-year recurrencey  Annual minimum 30-day mean discharge, in cubic feet per second, for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 126, M30,10. See WATSTORE users manual, Appendix. $ 30-day low flow, 20 year recurrencey  Annual minimum 30-day mean discharge, in cubic feet per second, for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 127, M30,20. See WATSTORE users manual, Appendix. $ 90-day low flow, 2-year recurrence.y  Annual minimum 90-day mean discharge, in cubic feet per second, for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 128, M90,2. See WATSTORE users manual, Appendix. % 90-day low flow, 10-year recurrence. y  Annual minimum 90-day mean discharge, in cubic feet per second, for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 129, M90,10. See WATSTORE users manual, Appendix. % 90-day low flow, 20-year recurrence. y  Annual minimum 90-day mean discharge, in cubic feet per second, for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 130, M90,20. See WATSTORE users manual, Appendix. # 1-day high flow, 2-year recurrence y  Annual maximum 1-day mean discharge, in cubic feet per second for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 136, V1,2. See WATSTORE users manual, Appendix.$ 1-day high flow, 5-year recurrence.y  Annual maximum 1-day mean discharge, in cubic feet per second for 5-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 137, V1,5. See WATSTORE users manual, Appendix.% 1-day high flow, 10-year recurrence. y  Annual maximum 1-day mean discharge, in cubic feet per second for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 138, V1,10. See WATSTORE users manual, Appendix. % 1-day high flow, 20-year recurrence. y  Annual maximum 1-day mean discharge, in cubic feet per second for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 139, V1,20. See WATSTORE users manual, Appendix. % 1-day high flow, 25-year recurrence. y  Annual maximum 1-day mean discharge, in cubic feet per second for 25-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 140, V1,25. See WATSTORE users manual, Appendix. % 1-day high flow, 50-year recurrence. y  Annual maximum 1-day mean discharge, in cubic feet per second for 50-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 141, V1,50. See WATSTORE users manual, Appendix. & 1-day high flow, 100-year recurrence. y  Annual maximum 1-day mean discharge, in cubic feet per second for 100-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 131, V1,100. See WATSTORE users manual, Appendix.$ 3-day high flow, 2-year recurrence.y  Annual maximum 3-day mean discharge, in cubic feet per second for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 142, V3,2. See WATSTORE users manual, Appendix.$ 3-day high flow, 5-year recurrence.y  Annual maximum 3-day mean discharge, in cubic feet per second for 5-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 143, V3,5. See WATSTORE users manual, Appendix.% 3-day high flow, 10-year recurrence. y  Annual maximum 3-day mean discharge, in cubic feet per second for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 144, V3,10. See WATSTORE users manual, Appendix. % 3-day high flow, 20-year recurrence. y  Annual maximum 3-day mean discharge, in cubic feet per second for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 145, V3,20. See WATSTORE users manual, Appendix. % 3-day high flow, 25-year recurrence. y  Annual maximum 3-day mean discharge, in cubic feet per second for 25-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 146, V3,25. See WATSTORE users manual, Appendix. % 3-day high flow, 50-year recurrence. y  Annual maximum 3-day mean discharge, in cubic feet per second for 50-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 147, V3,50. See WATSTORE users manual, Appendix. & 3-day high flow, 100-year recurrence. y  Annual maximum 3-day mean discharge, in cubic feet per second for 100-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 148, V3,100. See WATSTORE users manual, Appendix.$ 7-day high flow, 2-year recurrence.y  Annual maximum 7-day mean discharge, in cubic feet per second for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 149, V7,2. See WATSTORE users manual, Appendix.$ 7-day high flow, 5-year recurrence.y  Annual maximum 7-day mean discharge, in cubic feet per second for 5-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 150, V7,5. See WATSTORE users manual, Appendix.% 7-day high flow, 10-year recurrence. y  Annual maximum 7-day mean discharge, in cubic feet per second for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 151, V7,10. See WATSTORE users manual, Appendix. % 7-day high flow, 20-year recurrence. y  Annual maximum 7-day mean discharge, in cubic feet per second for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 152, V7,20. See WATSTORE users manual, Appendix. % 7-day high flow, 25-year recurrence. y  Annual maximum 7-day mean discharge, in cubic feet per second for 25-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 153, V7,25. See WATSTORE users manual, Appendix. % 7-day high flow, 50-year recurrence. y  Annual maximu m 7-day mean discharge, in cubic feet per second for 50-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 154, V7,50. See WATSTORE users manual, Appendix. & 7-day high flow, 100-year recurrence. y  Annual maximum 7-day mean discharge, in cubic feet per second for 100-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 155, V7,100. See WATSTORE users manual, Appendix.$ 15-day high flow, 2-year recurrencey  Annual maximum 15-day mean discharge, in cubic feet per second for 2-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 156, V15,2. See WATSTORE users manual, Appendix. $ 15-day high flow, 5-year recurrencey  Annual maximum 15-day mean discharge, in cubic feet per second for 5-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 132, V15,5. See WATSTORE users manual, Appendix. & 15-day high flow, 10-year recurrence. y  Annual maximum 15-day mean discharge, in cubic feet per second for 10-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 157, V15,10. See WATSTORE users manual, Appendix.& 15-day high flow, 20-year recurrence. y  Annual maximum 15-day mean discharge, in cubic feet per second for 20-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 158, V15,20. See WATSTORE users manual, Appendix.& 15-day high flow, 25-year recurrence. y  Annual maximum 15-day mean discharge, in cubic feet per second for 25-year recurrence interval, defined by log-Pearson Type III fitting in ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 159, V15,25. See WATSTORE users manual, Appendix. "  -SWW[20000309112924 20000309112924 2vNH150j`SC*H151``C*H300`dD*H300`j^D*H300b`D*H300d` E*H300djeE*H300j`E*H301``F*DEPHdjqF*QEX9jF*QEX9`G*QEX7jQG*QEX7`G*QEX5`G*QEX2j9H*QEX1`H*YRSDڂH*YRSL۞I*UBC0dhEI*UBC0djoI*UBC0dlI*UBC0dnI*UBC0dpI*UBC0drJ*UBC0f`EJ*UBC0fboJ*UBC0fpJ*UBC0frJ*UBC0h`J*UBC0llK*UBC0lnBK*UBC0lplK*UBC0lrK*UBC0nfK*UBC0nhK*UBC1llL*UBC1lnCL*UBC1lrnL*UBC1n`L*UBC1pdL*UBC1pfL*UBC1phM*UBC1pjEM*UBC1plpM*UBC1pnM*UBC1ppM*UBC1prM*UBC1r` N*UBC1rbKN*& 15-day high flow, 50-year recurrence. y  Annual maximum 15-day mean discharge, in cubic feet per second for 50-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 160, V15,50. See WATSTORE users manual, Appendix. ' 15-day high flow, 100-year recurrence. y  Annual maximum 15-day mean discharge, in cubic feet per second for 100-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 161, V15,100. See WATSTORE users manual, Appendi!#x. % 30-day high flow, 2-year recurrence. y  Annual maximum 30-day mean discharge, in cubic feet per second for 2-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 162, V30,2. See WATSTORE users manual, Appendix. % 30-day high flow, 5-year recurrence. y  Annual maximum 30-day mean discharge, in cubic feet per second for 5-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 133, V30,5. See WATSTORE users manual, Appendix. & 30-day high flow, 10-year recurrence. y  Annual maximum 30-day mean discharge, in cubic feet per second for 10-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 163, V30,10. See WATSTORE users manual, Appendix. & 30-day high flow, 20-year recurrence. y  Annual maximum 30-day mean discharge, in cubic feet per second for 20-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 134, V30,20. See WATSTORE users manual, Appendix. & 30-day high flow, 25-year recurrence. y  Annual maximum 30-day mean discharge, in cubic feet per second for 25-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 164, V30,25. See WATSTORE users manual, Appendix. & 30-day high flow, 50-year recurrence. y  Annual maximum 30-day mean discharge, in cubic feet per second for 50-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow "$ characteristic no 165, V30,50. See WATSTORE users manual, Appendix. ' 30-day high flow, 100-year recurrence. y  Annual maximum 30-day mean discharge, in cubic feet per second for 100-year recurrence interval, defined by log-Pearson Type III fitting ANNIE or WATSTORE program A969. Basin and streamflow characteristic no 135, V30,100. See WATSTORE users manual, Appendix.  Flow depth, in feetyy y Flow depth, in feet. Corresponding to the difference between the 25 percent flow duration gage height and point of zero flow. Basin and streamflow characteristic no 168, DEPH25. See WATSTORE users manual, Appendix. + Discharge exceeded 95 percent of the time. y  Discharge, in cubic feet per second, exceeded 95 percent of time. Defined by daily flow duration, WATSTORE program A969. Basin and streamflow characteristic no 171, D95. See WATSTORE users manual, Appendix. + Discharge exceeded 90 percent of the time. y  Discharge, in cubic feet per second, exceeded 90 percent of time. Defined by daily flow duration, WATSTORE program A969. Basin and streamflow characteristic no 172, D90. See WATSTORE users manual, Appendix. * Discharge exceeded 75 percent of the time y  Discharge, in cubic feet per second, exceeded 75 percent of time. Defined by daily flow duration, WATSTORE program A969. Basin and streamflow characteristic no 173, D75. See WATSTORE users manual, Appendix. + Discharge exceeded 70 percent of the time. y  Discharge, in cubic feet per second, exceeded 70 percent of time. Defined by daily flow duration, WATSTORE program A969. Basin and streamflow characteristic no 174, D70. See WATSTORE users manual, Appendix. + Discharge exceeded 50 percent of the time. y  Discharge, in cubic f#%eet per second, exceeded 50 percent of time. Defined by daily flow duration, WATSTORE program A969. Basin and streamflow characteristic no 175, D50. See WATSTORE users manual, Appendix. + Discharge exceeded 25 percent of the time. y  Discharge, in cubic feet per second, exceeded 25 percent of time. Defined by daily flow duration, WATSTORE program A969. Basin and streamflow characteristic no 176, D25. See WATSTORE users manual, Appendix. + Discharge exceeded 10 percent of the time. y  Discharge, in cubic feet per second, exceeded 10 percent of time. Defined by daily flow duration, WATSTORE program A969. Basin and streamflow characteristic no 177, D10. See WATSTORE users manual, Appendix. & Number of years of daily-flow record. y  Number of years of daily-flow record, from WATSTORE flow variability program W4422. Basin and streamflow characteristic no 198, YRSDAY. See WATSTORE users manual, Appendix. $ Number of years of low-flow record.y  Number of years of low-flow record. Basin and streamflow characteristic no 199, YRSLOW. See WATSTORE users manual, Appendix. User defined yy x Defined by user or application. Basin and streamflow characteristic no 24 See WATSTORE users manual, Appendix. User defined yy x Defined by user or application. Basin and streamflow characteristic no 25 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 26 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 27 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. $& Basin and streamflow characteristic no 28 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 29 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 30 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 31 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 38 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 39 See WATSTORE users manual, Appendix. User defined. yy y Defined by user or application. Basin and streamflow characteristic no 040 See WATSTORE users manual, Appendix.  User defined. yy x Defined by user or application. Basin and streamflow characteristic no 66 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 67 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 68 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 69 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 73 See WATSTORE users manual, Appendix. User defined. yy x Defined by user or application. Basin and %'streamflow characteristic no 74 See WATSTORE users manual, Appendix. User defined. yy y Defined by user or application. Basin and streamflow characteristic no 166 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 167 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 168 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 170 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 182 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 183 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 184 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 185 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 186 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 187 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 188 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user o&r application. Basin and streamflow characteristic no 189 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 190 See WATSTORE users manual, Appendix.  User defined. yy y Defined by user or application. Basin and streamflow characteristic no 191 See WATSTORE users manual, Appendix. )  -SWW[20000309112925 20000309112925 )MWUBC1rdSQ*UBC1rf}Q*UBC1rhQ*UBC1rjQ*UBC2``Q*SEAS)R*SEASmR*XSECR*DEPT@R*RFOO@R*BRAN S*TMZO)S*GRPNS!DATU@S*STDT S STDI S STDI S STDI T J407 "T*J407FT*J407jT*J407T*J407T*J407T*J407T*J407U*J407?U*J407lU*J407U*MEANU*SDNDA@U*SKWN@V*KENTDV*KENPcV*KENS~V*NONZV(NUMZV(IDSC V !IDCO!V !IDLO" W !PCLT,ab"W* User defined. yy x Defined by user or application. Basin and streamflow characteristic no 192 See WATSTORE users guide, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 193 See WATSTORE users guide, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 194 See WATSTORE users guide, Appendix. User defined. yy x Defined by user or application. Basin and streamflow characteristic no 195 See WATSTORE users guide, Appendix. User defined. (*yy x Defined by user or application. Basin and streamflow characteristic no 200 See WATSTORE users guide, Appendix. Month season begins   Beginning month of a user defined season. A starting day may be specified by attribute SEADBG. Used with attributes SEASND and SEADND to define a specific time period, ofter a year. January is month 1.  Month season ends    Ending month of a user defined season. A ending day may be specified by attribute SEADND. Used with attributes SEASBG and SEASND to define a specific time period, often a year. January is month 1. Cross-section locator yy c Cross-section locator, distance in feet from left bank (as determined by facing downstream).  Sampling depth yy > Sampling depth, in feet, at which observation was made.  Distance from mouth, in feet. yy 'Distance from mouth of river, in feet. ' Integer ID number of a single channel.  + Integer ID number of a channel segment. $ Time zone, +- hours from Greenwich.  : Time zone. Each time zone is represented as the number of hours to be added to, or subtracted from, Greenwich time: -4 - Atlantic Standard -8 - Pacific Standard -5 - Eastern Standard -9 - Yukon Standard -6 - Central Standard -10 - Alaska-Hawaii -7 - Mountain Standard Standard  Group name (6 characters). H Six character name for a cluster of message type data-set groups. Reference Elevationyy + Reference elevation, to mean sea level.  Space time data type. INT REALDPRC % Space time dimension in X direction.  ( Space time dimension in X direction.% Space time dimension in Y direction.  ( Space time dimension in Y direction.)+% Space time dimension in Z direction.  ( Space time dimension in Z direction.! Low outlier discharge criterion. (kn(knN I Low outlier discharge criterion (Bulletin 17B frequency analysis). ! High-outlier discharge criterion (kn(knN J High outlier discharge criterion (Bulletin 17B frequency analysis).  Generalized skew option  Generalized skew option (Bulletin 17B frequency analysis): -1 - station skew 0 - weighted skew 1 - generalized skew  Generalized skew. (kn(knN 7 Generalized skew (Bulletin 17B frequency analysis).  Base gage discharge(kn(knN : Base gage discharge (Bulletin 17B frequency analysis).  Number of historic peaks. d B Number of historic peaks (Bulletin 17B frequency analysis). + Root mean square error of generalized skew (kn(knN T Root mean square error of generalized skew (Bulletin 17B frequency analysis). Include urban-regulated peaks  \ Include urban-regulated peaks (Bulletin 17B frequency analysis): 1 - no 2 - yes Historic peak option  z Historic peak option (Bulletin 17B frequency analysis): 1 - include historic peaks 2 - exclude historic peaks  Year to begin analysis   m Year to begin analysis, used to identify subset of available record (Bulletin 17B frequency analysis).  Year to end analysis.   k Year to end analysis, used to identify subset of available record (Bulletin 17B frequency analysis). 0 Mean of the LOG of annual n-day high or low stay@ X Mean of the logarithms, base 10, of annual n-day high-flow or low-flow statistic./ Standard deviation of LOG of annual n-day high @ b Standard deviatio*n of logarithms, base 10, of annual n-day high-flow or low-flow statistic. 0 Skew of LOG of annual n-day high or low statistyy U Skew of logarithms, base 10, of annual n-day high- flow or low-flow statistic. + Kendahl Tau statistic for time series data yy / Kendahl Tau statistic for time-series data. " P-level for Kendahl Tau statistic yy & P-level for Kendahl Tau statistic. " Median slope of time series trend yy & Median slope of time-series trend. . Number of non-zero values in the time series.  1 Number of non-zero values in the time series. & Number of zero values in time series.  ) Number of zero values in time series. Scenario idI 8-character identifier for the scenario associated with this data set.  Constituent id H 8-character identifier of the constituent contained in this data set. Location idI 8-character identifier for the location associated with this data set.  1% of values are less yy t One percent of time values are less than this value. Attribute is computed by the Weibull plotting position. -  -SWW[20000309112925 20000309112925 2 ePCLT-adSY*PCLT.aj~Y*PCLT/c`Y*PCLT0e`Y*PCLT1ejZ*PCLT2k`2Z*PCLT3oj^Z*PCLT4q`Z*PCLT5s`Z*PCLT6sjZ*PCLT7sp[*PCLT8sr?[*LQU09c`l[*LQU0:e`[*LQU0;k`[*LQU1a`\*LQU8?a`\*LQU9@a`\*LQU9Ak`-]*LQU9Bq`e]*LQU9Cs`]*LQU9Dsj]*LQU9Esp^*LDISF@K^ LMOMGc@^*LMOMHe@^*LMOMIg@^*LMOMJi@_*LMOMKk@A_*PQU0Lc`d_*PQU0Me`_*PQU0Nk`_*PQU1Oa`L`*PQU2Pa``*PQU5Qa``*PQU8Ra`3a*PQU9Sa`a*PQU9Tk`a*PQU9Uq`b*PQU9Vs`kb*PQU9Wsjb*PQU9Xspc*GQU0Yc`Tc*GQU0Ze`c*GQU0[k`c*GQU1\a` D 2-year recurrence based on 3-parameter lognormal, method of momentsyy  An event with a 2-year recurrence interval (exceedance probability of 0.50) based on the 3-parameter lognormal distribution, method of moments. Attribute added by program CFA. D 5-year recurrence based on 3-parameter lognormal, method of momentsyy  An event with a 5-year recurrence interval (exceedance probability of 0.20) based on the 3-parameter lognormal distribution, method of moments. Attribute added by program CFA. E 10-year recurrence based on 3-parameter lognormal, method of moments yy  An event with a 10-year recurrence interval (exceedance probab46ility of 0.10) based on the 3-parameter lognormal distribution, method of moments. Attribute added by program CFA. E 20-year recurrence based on 3-parameter lognormal, method of moments yy  An event with a 20-year recurrence interval (exceedance probability of 0.05) based on the 3-parameter lognormal distribution, method of moments. Attribute added by program CFA. E 50-year recurrence based on 3-parameter lognormal, method of moments yy  An event with a 50-year recurrence interval (exceedance probability of 0.02) based on the 3-parameter lognormal distribution, method of moments. Attribute added by program CFA. F 100-year recurrence based on 3-parameter lognormal, method of moments yy  An event with a 100-year recurrence interval (exceedance probability of 0.01) based on the 3-parameter lognormal distribution, method of moments. Attribute added by program CFA.F 200-year recurrence based on 3-parameter lognormal, method of moments yy  An event with a 200-year recurrence interval (exceedance probability of 0.005) based on the 3-parameter lognormal distribution, method of moments. Attribute added by program CFA. F 500-year recurrence based on 3-parameter lognormal, method of moments yy  An event with a 500-year recurrence interval (exceedance probability of 0.002) based on the 3-parameter lognormal distribution, method of moments. Attribute added by program CFA. 2 2-year recurrence based on GEV, method of moments yy  An event with a 2-year recurrence interval (exceedance probability of 0.50) based on the GEV distribution, method of moments. Attribute added by program CFA. 2 5-year recurrence based on GEV, method of moments yy  An event with a 5-year recurrence interval (exceedance probability of 0.20) based on the GEV distribution, method of moments57. Attribute added by program CFA. 3 10-year recurrence based on GEV, method of moments yy  An event with a 10-year recurrence interval (exceedance probability of 0.10) based on the GEV distribution, method of moments. Attribute added by program CFA. 3 20-year recurrence based on GEV, method of moments yy  An event with a 20-year recurrence interval (exceedance probability of 0.05) based on the GEV distribution, method of moments. Attribute added by program CFA. 3 50-year recurrence based on GEV, method of moments yy  An event with a 50-year recurrence interval (exceedance probability of 0.02) based on the GEV distribution, method of moments. Attribute added by program CFA. 4 100-year recurrence based on GEV, method of momentsyy  An event with a 100-year recurrence interval (exceedance probability of 0.01) based on the GEV distribution, method of moments. Attribute added by program CFA. 4 200-year recurrence based on GEV, method of momentsyy  An event with a 200-year recurrence interval (exceedance probability of 0.005) based on the GEV distribution, method of moments. Attribute added by program CFA.4 500-year recurrence based on GEV, method of momentsyy  An event with a 500-year recurrence interval (exceedance probability of 0.002) based on the GEV distribution, method of moments. Attribute added by program CFA.? 2-year recurrence based on Pearson Type III, method of moments yy  An event with a 2-year recurrence interval (exceedance probability of 0.50) based on the Pearson Type III distribution, method of moments. Attribute added by program SWSTAT. ? 5-year recurrence based on Pearson Type III, method of moments yy  An event with a 5-year recurrence interval (exceedance probability of 0.20) based on the Pearson Typ68e III distribution, method of moments. Attribute added by program SWSTAT. @ 10-year recurrence based on Pearson Type III, method of momentsyy  An event with a 10-year recurrence interval (exceedance probability of 0.10) based on the Pearson Type III distribution, method of moments. Attribute added by program SWSTAT. @ 20-year recurrence based on Pearson Type III, method of momentsyy  An event with a 20-year recurrence interval (exceedance probability of 0.05) based on the Pearson Type III distribution, method of moments. Attribute added by program SWSTAT. @ 50-year recurrence based on Pearson Type III, method of momentsyy  An event with a 50-year recurrence interval (exceedance probability of 0.02) based on the Pearson Type III distribution, method of moments. Attribute added by program SWSTAT. A 100-year recurrence based on Pearson Type III, method of moments yy  An event with a 100-year recurrence interval (exceedance probability of 0.01) based on the Pearson Type III distribution, method of moments. Attribute added by program SWSTAT. A 200-year recurrence based on Pearson Type III, method of moments yy  An event with a 200-year recurrence interval (exceedance probability of 0.005) based on the Pearson Type III distribution, method of moments. Attribute added by program SWSTAT.A 500-year recurrence based on Pearson Type III, method of moments yy  An event with a 500-year recurrence interval (exceedance probability of 0.002) based on the Pearson Type III distribution, method of moments. Attribute added by program SWSTAT.E 2-year recurrence based on 3-parameter lognormal, maximum likelihood yy  An event with a 2-year recurrence interval (exceedance probability of 0.50) based on the 3-parameter lognormal distribution, maximum likelihood estimate79. Attribute added by program CFA or MAX. E 5-year recurrence based on 3-parameter lognormal, maximum likelihood yy  An event with a 5-year recurrence interval (exceedance probability of 0.20) based on the 3-parameter lognormal distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. F 10-year recurrence based on 3-parameter lognormal, maximum likelihood yy  An event with a 10-year recurrence interval (exceedance probability of 0.10) based on the 3-parameter lognormal distribution, maximum likelihood estimate. Attribute added by program CFA or MAX.F 20-year recurrence based on 3-parameter lognormal, maximum likelihood yy  An event with a 20-year recurrence interval (exceedance probability of 0.05) based on the 3-parameter lognormal distribution, maximum likelihood estimate. Attribute added by program CFA or MAX.F 50-year recurrence based on 3-parameter lognormal, maximum likelihood yy  An event with a 50-year recurrence interval (exceedance probability of 0.02) based on the 3-parameter lognormal distribution, maximum likelihood estimate. Attribute added by program CFA or MAX.G 100-year recurrence based on 3-parameter lognormal, maximum likelihood yy  An event with a 100-year recurrence interval (exceedance probability of 0.01) based on the 3-parameter lognormal distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. G 200-year recurrence based on 3-parameter lognormal, maximum likelihood yy  An event with a 200-year recurrence interval (exceedance probability of 0.005) based on the 3-parameter lognormal distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. G 500-year recurrence based on 3-parameter lognormal, maximum likelihood yy  An event with a 500-year recurrence interval (exce8:edance probability of 0.002) based on the 3-parameter lognormal distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. 3 2-year recurrence based on GEV, maximum likelihood yy  An event with a 2-year recurrence interval (exceedance probability of 0.50) based on the GEV, maximum likelihood estimate. Attribute added by program CFA or MAX. 3 5-year recurrence based on GEV, maximum likelihood yy  An event with a 5-year recurrence interval (exceedance probability of 0.20) based on the GEV, maximum likelihood estimate. Attribute added by program CFA or MAX. 4 10-year recurrence based on GEV, maximum likelihoodyy  An event with a 10-year recurrence interval (exceedance probability of 0.10) based on the GEV, maximum likelihood estimate. Attribute added by program CFA or MAX. 4 20-year recurrence based on GEV, maximum likelihoodyy  An event with a 20-year recurrence interval (exceedance probability of 0.05) based on the GEV, maximum likelihood estimate. Attribute added by program CFA or MAX. 4 50-year recurrence based on GEV, maximum likelihoodyy  An event with a 50-year recurrence interval (exceedance probability of 0.02) based on the GEV, maximum likelihood estimate. Attribute added by program CFA or MAX. 5 100-year recurrence based on GEV, maximum likelihood yy  An event with a 100-year recurrence interval (exceedance probability of 0.01) based on the GEV, maximum likelihood estimate. Attribute added by program CFA or MAX. 5 200-year recurrence based on GEV, maximum likelihood yy  An event with a 200-year recurrence interval (exceedance probability of 0.005) based on the GEV, maximum likelihood estimate. Attribute added by program CFA or MAX.5 500-year recurrence based on GEV, maximum likelihood yy 9 An event with a 500-year recurrence interval (exceedance probability of 0.002) based on the GEV, maximum likelihood estimate. Attribute added by program CFA or MAX.D 2-year recurrence based on log-Pearson Type III, maximum likelihoodyy  An event with a 2-year recurrence interval (exceedance probability of 0.50) based on the log-Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. D 5-year recurrence based on log-Pearson Type III, maximum likelihoodyy  An event with a 5-year recurrence interval (exceedance probability of 0.20) based on the log-Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. E 10-year recurrence based on log-Pearson Type III, maximum likelihood yy  An event with a 10-year recurrence interval (exceedance probability of 0.10) based on the log-Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. <  -SWW[20000309112925 20000309112925 .LCML0e`Sw*CML0k`w*CML1a`w*CML2a`;x*CML5a`x*PML0adx*PML0ajy*PML0c`ey*PML0e`y*PML0k`y*PML1a`Az*PML2a`z*PML5a`z*NQU0c`{*NQU0e`i{*NQU0k`{*NQU1a`|*NQU2a`T|*NQU5a`|*NQU8a`|*NQU9a`;}*NQU9k`}*NQU9q`}*NQU9s`&~*NQU9sjs~*NQU9sp~*QEX9s*QEX9qH*QEX8k*QEX8a*QEX6k*QEX6a(*QEX5k_*QEX4k*QEX4à*QEX3k*QEX3a;*QEX2ar*QEX1k*QEXOk*QEX0e*QEX0cR*DATC "DATM "SEAD҂*SEAD*E 20-year recurrence based on log-Pearson Type III, maximum likelihood yy  An event with a 20-year recurrence interval (exceedance probability of 0.05) based on the log-Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. E 50-year recurrence based on log-Pearson Type III, maximum likelihood yy  An event with a 50-year recurrence interval (exceedance probability of 0.02) based on the log-Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. F 100-year recurrence based on log-Pearson Type III, maximum likelihood yy;=  An event with a 100-year recurrence interval (exceedance probability of 0.01) based on the log-Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX.F 200-year recurrence based on log-Pearson Type III, maximum likelihood yy  An event with a 200-year recurrence interval (exceedance probability of 0.005) based on the log-Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. F 500-year recurrence based on log-Pearson Type III, maximum likelihood yy  An event with a 500-year recurrence interval (exceedance probability of 0.002) based on the log-Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. @ 2-year recurrence based on Pearson Type III, maximum likelihoodyy  An event with a 2-year recurrence interval (exceedance probability of 0.50) based on the Pearson Type III distribution, maximum likelihood estimate. Attribute added by program CFA or MAX. @ 5-year recurrence based on Pearson Type III, maximum likelihoodyy  An event with a 5-year recurrence interval (exceedance probability of 0.20) based on the Pearson Type III distribution, maximum likelihood estimate. Attribute added by program MAX. A 10-year recurrence based on Pearson Type III, maximum likelihood yy  An event with a 10-year recurrence interval (exceedance probability of 0.10) based on the Pearson Type III distribution, maximum likelihood estimate. Attribute added by program MAX.A 20-year recurrence based on Pearson Type III, maximum likelihood yy  An event with a 20-year recurrence interval (exceedance probability of 0.05) based on the Pearson Type III distribution, maximum likelihood estimate. Attribute added by program MAX.A 50-year recurrence based on Pearson Type III<>, maximum likelihood yy  An event with a 50-year recurrence interval (exceedance probability of 0.02) based on the Pearson Type III distribution, maximum likelihood estimate. Attribute added by program MAX.B 100-year recurrence based on Pearson Type III, maximum likelihood yy  An event with a 100-year recurrence interval (exceedance probability of 0.01) based on the Pearson Type III distribution, maximum likelihood estimate. Attribute added by program MAX. B 200-year recurrence based on Pearson Type III, maximum likelihood yy  An event with a 200-year recurrence interval (exceedance probability of 0.005) based on the Pearson Type III distribution, maximum likelihood estimate. Attribute added by program MAX. B 500-year recurrence based on Pearson Type III, maximum likelihood yy  An event with a 500-year recurrence interval (exceedance probability of 0.002) based on the Pearson Type III distribution, maximum likelihood estimate. Attribute added by program MAX. D .01 quantile based on 3-parameter lognormal distribution, L-momentsyy  .01 quantile based on the 3-parameter lognormal distribution using L-moments. 1 percent chance of being less than this value or a nonexceedance probability of .01. Attribute added by program LMOMNT. D .02 quantile based on 3-parameter lognormal distribution, L-momentsyy  .02 quantile based on the 3-parameter lognormal distribution using L-moments. 2 percent chance of being less than this value or a nonexceedance probability of .02. Attribute added by program LMOMNT. D .05 quantile based on 3-parameter lognormal distribution, L-momentsyy  .05 quantile based on the 3-parameter lognormal distribution using L-moments. 5 percent chance of being less than this value or a nonexceedance probability of .05. Attribute added by program LMOMN=?T. D .10 quantile based on 3-parameter lognormal distribution, L-momentsyy  .10 quantile based on the 3-parameter lognormal distribution using L-moments. 10 percent chance of being less than this value or a nonexceedance probability of .10. Attribute added by program LMOMNT.D .20 quantile based on 3-parameter lognormal distribution, L-momentsyy  .20 quantile based on the 3-parameter lognormal distribution using L-moments. 20 percent chance of being less than this value or a nonexceedance probability of .20. Attribute added by program LMOMNT.D .50 quantile based on 3-parameter lognormal distribution, L-momentsyy  .50 quantile based on the 3-parameter lognormal distribution using L-moments. 50 percent chance of being less than this value or a nonexceedance probability of .50. Attribute added by program LMOMNT.D .80 quantile based on 3-parameter lognormal distribution, L-momentsyy  .80 quantile based on the 3-parameter lognormal distribution using L-moments. 80 percent chance of being less than this value or a nonexceedance probability of .80. Attribute added by program LMOMNT.D .90 quantile based on 3-parameter lognormal distribution, L-momentsyy  .90 quantile based on the 3-parameter lognormal distribution using L-moments. 90 percent chance of being less than this value or a nonexceedance probability of .90. Attribute added by program LMOMNT.D .95 quantile based on 3-parameter lognormal distribution, L-momentsyy  .95 quantile based on the 3-parameter lognormal distribution using L-moments. 95 percent chance of being less than this value or a nonexceedance probability of .95. Attribute added by program LMOMNT.D .98 quantile based on 3-parameter lognormal distribution, L-momentsyy  .98 quantile based on the 3-parameter lognormal distribution using L-moments>@. 98 percent chance of being less than this value or a nonexceedance probability of .98. Attribute added by program LMOMNT.D .99 quantile based on 3-parameter lognormal distribution, L-momentsyy  .99 quantile based on the 3-parameter lognormal distribution using L-moments. 99 percent chance of being less than this value or a nonexceedance probability of .99. Attribute added by program LMOMNT.E .995 quantile based on 3-parameter lognormal distribution, L-moments yy  .995 quantile based on the 3-parameter lognormal distribution using L-moments. 99.5 percent chance of being less than this value or a nonexceedance probability of .995. Attribute added by program LMOMNT.E .998 quantile based on 3-parameter lognormal distribution, L-moments yy  .998 quantile based on the 3-parameter lognormal distribution using L-moments. 99.8 percent chance of being less than this value or a nonexceedance probability of .998. Attribute added by program LMOMNT.+ Discharge exceeded 99 percent of the time. y  Discharge, in cubic feet per second, exceeded 99 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 98 percent of the time. y  Discharge, in cubic feet per second, exceeded 98 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 85 percent of the time. y  Discharge, in cubic feet per second, exceeded 85 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 80 percent of the time. y  Discharge, in cubic feet per second, exceeded 80 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 65 percent of the time. y  Discha?Arge, in cubic feet per second, exceeded 65 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 60 percent of the time. y  Discharge, in cubic feet per second, exceeded 60 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 55 percent of the time. y  Discharge, in cubic feet per second, exceeded 55 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 45 percent of the time. y  Discharge, in cubic feet per second, exceeded 45 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 40 percent of the time. y  Discharge, in cubic feet per second, exceeded 40 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 35 percent of the time. y  Discharge, in cubic feet per second, exceeded 35 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 30 percent of the time. y  Discharge, in cubic feet per second, exceeded 30 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 20 percent of the time. y  Discharge, in cubic feet per second, exceeded 20 percent of the time. Calculated by daily flow duration, program swstat, option duration. + Discharge exceeded 15 percent of the time. y  Discharge, in cubic feet per second, exceeded 15 percent of the time. Calculated by daily flow duration, program swstat, option duration. * Discharge exceeded 5 percent of the time. y  Discharge, in cubic feet per second, exceeded 5 percent of@ the time. Calculated by daily flow duration, program swstat, option duration. * Discharge exceeded 2 percent of the time. y  Discharge, in cubic feet per second, exceeded 2 percent of the time. Calculated by daily flow duration, program swstat, option duration. * Discharge exceeded 1 percent of the time. y  Discharge, in cubic feet per second, exceeded 1 percent of the time. Calculated by daily flow duration, program swstat, option duration. < System date and time of dataset creation "yyyymmddhhmmss "> System date and time of dataset creation "yyyymmddhhmmss " E System date and time of last dataset modification "yyyymmddhhmmss " G System date and time of last dataset modification "yyyymmddhhmmss "  Day season begins   Beginning day of a user defined season that begins in the month specified by attribute SEASBG. Used with attributes SEASND and SEADND to define a specific time period, ofter a year.  Day season ends  Ending day of a user defined season that ends in the month specified by attribute SEASND. Used with attributes SEASBG and SEADBG to define a specific time period, ofter a year. C -SWW[_20000309112925 20000309112925 QRESP WSYapxą؅&3?JÆІ݆4KeÇׇ͇1fz1щ!7ʊӊ !*6JV} (Use return for (Use return for &) 2 Min allowed value is &, Max allowed value is &.   Valid responses are: !  Conflicting response, could be:  Incorrect response - try again$ FIELD MINIMUM MAXIMUM DEFAULT ROW>  Enter changes ( ? for help, D for done ) in correct columns. . Using DEFAULT instead of bad value in field '  Help not available for this question. H  End of your command file, enter response to the above question... $ CHECK out of range value in field D DONE ? HELP VIEW EDIT PLOT TRANSFORMFILE Currently viewing the top row. BD" Currently viewing the bottom row. * Can not change PROTECTED value in field  Can not copy over a row. + Rw &, fld &, bad new value, NOT updated. ( Rw &, fld &, bad new value, CHECK it. ! No new value input for CHANGE. b DONE - done with this screen of dataHELP - get general help for screen or specific help for fieldVIEW - REFRESH screen, refresh LIMITS, move UP or DOWN rowsEDIT - modify data in window (cursor moves to window)PLOT - plot either row numbers or a field vs desired fieldsTRANSFORM - perform transformations on screen of dataFILE - put data onto files Commands:  Out of EDIT mode. @ In EDIT mode. To quick exit type % "cr". To backup, < (n) "cr".) Max allowable row is &, you specified &. + Max allowable field is &, you specified &. + Min allowable row is 1, you specified &. - Min allowable field is 1, you specified &. * REFRESHLIMITS UP DOWN ? CANCEL 2 & data errors exist, first one in row &, field &. $ Parameter out of range. Try again.I START-ROW END-ROW LEFT-FIELD RIGHT-FIELDGO ? CANCEL T START-ROW END-ROW LEFT-FIELD RIGHT-FIELDVALUE GO ? CANCEL_ START-ROW END-ROW LEFT-FIELD RIGHT-FIELDVALUE INCREMENT GO ? CANCEL _ START-ROW END-ROW LEFT-FIELD RIGHT-FIELDNEW-ROW FINAL-ROW GO ? CANCEL - current: & & & & ? current: & & & & & &  Min &, Max &, now: &  Enter STARTING ROW: Enter ENDING ROW:  Enter LEFT FIELD:  Enter RIGHT FIELD: Enter STARTING ROW (copy from): Enter ENDING ROW (copy from):  Enter NEW ROW (copy to):  Enter FINAL ROW (copy to): Enter VALUE:  Enter INCREMENT:  Enter MULTIPLE: Enter NUMBER OF CEROWS:  Enter FIELD NUMBER:+ Options: "<" to cancel or "cr" to accept L  Unable to INCREMENT, no value to increment by. Use any key to continue.  REFRESH - refresh whole screen with current values LIMITS - refresh limits portion of screen UP - move up desired number of rows of data DOWN - move down desired number of rows of data F  Unable to CHANGE, no value to change to. Use any key to continue. 9  Field number & contains values which are out of order.  0.0 0.0 0.03 INCREMENT the data in the window defined by Row (TOP,BOT) andField (LEF,RGT) Ranges. The TOP, BOTTOM, LEFT, RIGHT commandsare used to set the desired values to describe the window.When the GO command is used, all defined data values in thewindow will be incremented by VAL. (Use any key to continue). 1 MULTIPLY the data in the window defined by Row (TOP,BOT) andField (LEF,RGT) Ranges. The TOP, BOTTOM, LEFT, RIGHT commandsare used to set the desired values to describe the window.When the GO command is used, all defined data values in thewindow will be multiplied by VAL. (Use any key to continue). < COPY the rows of data described by Row Range (from) (TOP,BOT)to the rows of data described by Row Range (to) (NEWBEG,FINAL).The fields to be copied are described by Field Range (LEF,RGT).The TOP, BOTTOM, NEWBEG, FINAL, LEFT, RIGHT commands set thedesired values. GO will do the COPY. (Use any key to continue).4 CHANGE the data in the window defined by Row (TOP,BOT) andField (LEF,RGT) Ranges. The TOP, BOTTOM, LEFT, RIGHT commandsare used to set the desired values to describe the window.GO changes the top row to VAL and all additional rows will bechanged to VAL and incremented by INC. (Use any key to continue)' EDIT the data in the window described by row (TOP,BOT) andfield (LEF,RGT) ranges. The TOP, BOTTOM, LEFT, RIGHT commandsare used to set the desired values to describe the window.When GOD is used, the cursor will move to the top left ofthe window you wish to EDIT. (Use any key to continue). M ADD_CONST MULT_CONSTROWCOPY FIELDCOPY SUBSTITUTEFUNCTION ? CANCEL g ADD_CONST - increment defined values in window by a constantMULT_CONST - multiply defined values in window by a constantROWCOPY - copy rows of values from one window to anotherFIELDCOPY - copy values from one field to anotherSUBSTITUTE - chage values in window to a value and add incrementFUNCTION - perform desired mathematical functions on data % WDM FLAT ROWS FIELDS? CANCEL WDM - write data to WDM fileFLAT - write data to flat fileROWS - specify rows of data to write to fileFIELDS - specify fields of data to write to file  GENERALFIELD ? CANCEL\ GENERAL - get general help for this screen of dataFIELD - get help for a specified field EDIT ADD_CONSTANT  MULT_CONSTANT  ROWCOPY SUBSTITUTE HELP FIELD  MOVE UP MOVE DOWN / & values out of a desired & have been input.  & values have been input. (  / can't be used. Must enter & values.E  * is repeat symbol and no digits preceed it. data will be ignored. '  Repeat number too large, reduce to &.  Is this input acceptable? @ 4` Yes& - values have been entered as desired a No 0 - go back to last screen to modify input values & more. Bad values, start line over.  Previous & values ok.  Input complete.G -SWW[_20000309112925 20000309112925 QFOPEN @S[mǍ $kʎHuΏُnxȐ File already in use. = Could not open file. No Fortran unit numbers are available. Z ( Name of output file? @FILE........................................................... @(@FILE `(NEW (SEQUENTIAL (FORMATTED ! Do you want to use another file? @ D` YESa NO 1 File not found. Do you want to try another name? @ D` YESa NO . Status must be old, new, scratch, or unknown. + File exists. Do you want to write over it? @ D` YESa NO x YES - try to open file again and continue. NO - will not open file. will either end or ask for another name.4 You do not have write accessFH to the specified file. File name is blanks. @(ANNIE.LOG `(UNKNOWN (SEQUENTIAL (FORMATTED i ( Name of file to log your responses? @FILE........................................................... @(@FILE `(UNKNOWN (SEQUENTIAL (FORMATTED j( The default file (ANNIE.LOG) is in use. Make up a name or kill program and restart when file not in use ^ ( Name of file with dates? @FILE........................................................... @(@FILE `(OLD (SEQUENTIAL (FORMATTED b ( Name of file to store dates? @FILE........................................................... @(@FILE `(NEW (SEQUENTIAL (FORMATTED @(HSPMESS.DA `(OLD(DIRECT (FORMATTED (\ ( Name of your WDM file? @FILE...........................................................@(@FILE `(OLD(DIRECT (UNFORMATTED(m ( Name of sequential file with variables. @FILE........................................................... @(@FILE `(OLD (SEQUENTIAL (FORMATTED s ( Name of sequential file with years of record. @FILE........................................................... @(@FILE `(OLD (SEQUENTIAL (FORMATTED v ( Name of sequential file with cross-correlations. @FILE........................................................... @(@FILE `(OLD (SEQUENTIAL (FORMATTED y ( Name of input file created from ANNIE/GLS analysis. @FILE........................................................... @(@FILE `(OLD (SEQUENTIAL (FORMATTED m ( Name of output file for telegraf input? @FILE........................................................... @(@FILE `(NEW (SEQUENTIAL (FORMATTED $ Could not open file, I/O status = &  Specify Output options Output type [@OUTTYP.] (Terminal, File) Lines per page [@LINES] Page width [@WIDTH]@@OUTTYP`GTERMINAL, FILE TERMINAL  Destination for output A@LINES a@ 20 o! For terminal output, lines output before a pauseFor file output, lines output before fortran carriage control A@WIDTH a(80 .! Maximum allowable characters output on a line ^ The user may direct output to the screen or to a file forprinting or use by another program.   Selected file already exists.   Selected file not found. ` ( Name of file for printout? @FILE...........................................................@(@FILE `(UNKNOWN (SEQUENTIAL (FORMATTED v( This will be file for printed output to be printed after this ANNIE session. It may use Fortran carriage control. 0 Do you want to copy the log file to a new name?@ D` NO a YES The log file of this run is stored as ANNIE.LOG and will be overwrote the next time you run the program. Use YES to save this log file under another name.k ( Name of new file to copy log file to? @FILE........................................................... @(@FILE `(NEW (SEQUENTIAL (FORMATTED =( The log file from this run will be saved as this file name. J -SWW[_20000309112926 20000309112926 UPARMS SnҘX4  1 CMPTYP C 6 1 PC PRIME VAX UNIX AVIION 2 TRMTYP C 6 1 PC VT100 OTHER 3 TRMINP I 5 0 10 4 TRMOUT I 6 0 10 5 TRMPAU I 124 33 127 6 TRMFIL I 64 33 127 7 TRMDLM I 59 33 127 8 TRMLRN I 33 33 127 9 MENCRA C 5 3 NONE DOWN NEXT 10 TRMDDD I 124 33 127 11 SCRWID I 80 40 256 12 SCRLEN I 24 10 100 13 FILMAX I 15 10 99 14 FILUNI I 30 7 99 15 RECTYP C 7 3 WORD HWORD BYTE UIKNKNOWN 16 GRAPHS C 4 1 YES NO 17 PLTDV1 C 8 1 DISPLAY PRINTER PLOTTER 18 PLTDV2 C 8 2 DISPLAY PRINTER PLOTTER 19 PLTDV3 C 8 3 DISPLAY PRINTER PLOTTER 20 INPDV1 C 8 1 NONE MOUSE DIGITIZ 21 COLORS C 22 CLRFRM I 15 0 15 23 CLRFRT I 11 0 15 24 CLRFRL I 13 0 15 25 CLRFRE I 7 0 15 26 CLRFRC I 14 0 15 27 CLRFRP I 7 0 15 28 CLRFRD I 14 0 15 29 CLRFRN I 14 0 15 30 CLRFRS I 15 0 15 31 CLRBKO I 2 0 15 32 CLRBKE I 4 0 15 33 CLRBKD I 0 0 15 34 CLRBKS I 1 0 15 35 BUGFLG C 5 1 NONE SOME LOTS 36 IOERR1 I 18 0 1000 37 IOERR2 I 15 0 1000 38 IOERR3 I 5 0 1000 39 IOERR4 I 57 0 1000 40 GKSDIS I 1 0 9999 41 GKSPRT I 2 0 9999 42 GKSPLT I 3 0 9999 43 GKSMET I 4 0 9999 44 GKSDSP I 102 0 9999 45 USRLEV I 0 0 2 46 RSPTYP C 6 2 ANNIE EMIFE 47 GKPREC C 7 2 STRING CHAR STROKE 48 GKSCFT I 1 -9999 9999 49 GKPRFT I 1 -9999 9999 50 GKPLFT I 1 -9999 9999 51 LSOLID I 1 -9999 9999 52 LDASH I 2 -9999 9999 53 LDOT I 3 -9999 9999 54 LMIXED I 4 -9999 9999 55 1LUSER I 1 -9999 9999 56 2LUSER I 1 -9999 9999 57 3LUSER I 1 -9999 9999 58 4LUSER I 1 -9999 9999 59 5LUSER I 1 -9999 9999 60 6LUSER I 1 -9999 9999 61JL CBLACK I 0 -9999 9999 62 CWHITE I 15 -9999 9999 63 CRED I 4 -9999 9999 64 CGREEN I 2 -9999 9999 65 CBLUE I 1 -9999 9999 66 CCYAN I 3 -9999 9999 67 CMAGNT I 5 -9999 9999 68 CYELLW I 14 -9999 9999 69 1CUSER I 1 -9999 9999 70 2CUSER I 1 -9999 9999 71 CDOT I 1 -9999 9999 72 CPLUS I 2 -9999 9999 73 CSTAR I 3 -9999 9999 74 CZERO I 4 -9999 9999 75 CX I 5 -9999 9999 76 1SUSER I 6 -9999 9999 77 2SUSER I 7 -9999 9999 78 3SUSER I 8 -9999 9999 79 4SUSER I 9 -9999 9999 80 5SUSER I 19 -9999 9999 81 PSOLID I 1 -9999 9999 82 PHORIZ I 2 -9999 9999 83 PVERT I 3 -9999 9999 84 PDIAG I 4 -9999 9999 85 1PUSER I 2 -9999 9999 86 2PUSER I 2 -9999 9999 87 3PUSER I 2 -9999 9999 88 4PUSER I 2 -9999 9999 89 5PUSER I 2 -9999 9999 90 6PUSER I 2 -9999 9999 91 PFKEY1 C 2 1 H C A P G L S O W M V T J D U I E Z K Q X 92 PFKEY2 C 2 3 H C A P G L S O W M V T J D U I E Z K Q X 93 PFKEY3 C 2 0 H C A P G L S O W M V T J D U I E Z K Q X 94 PFKEY4 C 2 4 H C A P G L S O W M V T J D U I E Z K Q X 95 PFKEY5 C 2 6 H C A P G L S O W M V T J D U I E Z K Q X 96 PFKEY6 C 2 16 H C A P G L S O W M V T J D U I E Z K Q X 97 PFKEY7 C 2 7 H C A P G L S O W M V T J D U I E Z K Q X 98 PFKEY8 C 2 20 H C A P G L S O W M V T J D U I E Z K Q X 99 PFKEY9 C 2 21 H C A P G L S O W M V T J D U I E Z K Q X 100 PFKEY0 C 2 12 H C A P G L S O W M V T J D KU I E Z K Q X 101 BCOLOR C 6 2 WHITE BLACK OTHER 102 SYMSIZ I 100 1 10000 103 TXTEXF I 133 0 200 104 TXTCHS I 0 0 200 105 BGRED I 0 0 100 106 BGREEN I 0 0 100 107 BGBLUE I 0 0 100 108 WEIBA I 0 0 1000 109 PBCOLR C 6 1 WHITE BLACK COLOR 8NONE 0WHITE 1RED 2GREEN 3BLUE 4CYAN 5MAGENTA 6YELLOW 7ORANGE 8BROWN 9VIOLET 10GREY 11LTRED 12LTGREEN 13LTBLUE 14 LINETYPE 8 1NONE -1SOLID 0DOT 1DASH 2DASHDOT 3DOT2DASH 4  SYMBOL 8 1NONE 0. 1+ 2* 3O 4X 5SQUARE 6TRIANGLE 7DIAMOND 8OCTOGON 9TRIPTDWN 10WATSURF 11STAR 12OPENUPAR 13SPIDER 14OCTWIND 15CROSBOX 16WINDOW 17CROSDIAM 18DIAMWIND 19 FILL 8 1NONE 0HOLLOW 1SOLID 2HORIZON -1VERTICAL -2BOX -5 N -SWW[_20000309112926 20000309112926 EMIFE NSoɛқܛ'2=IRakvƜ%6gw֝>QƞמܞFgş3a̠7WwΡ 3jڢf TEXT MENU 1D-DATA 2D-DATA FILE STATUS HELP LIMITS TUTOR COMMANDSXPAD INSTRUCTERROR x Help Cmhlp AcceptPrev Guide LimitsStatusOops WindowMove View Top Jump Dnpg Uppg IntrptExit Zap Keys Quiet Xpad F B R Y N End of input from macro, ! now reading input from keyboard. " Too many macros currently in use.  Enter macro name: Unable to open specified macro. Use any key to continue. Help display help in this box! Cmhlp display what you see here 5 Accept contents of current screen, go to next screen  Prev go to previous screen MO& Guide display tutorial for new users " Limits display limits in this box " Status display status in this box " Oops undo changes made in error " Window specify data to operate on ( Move move rows and/or columns of data View plot specified data 3 Top go to first (opening) screen of application  Jump go to screen specifed ! Dn pg display more text or data % Up pg display previous text or data % Intrpt interrupt current calculation / Exit clean up and return to operating system  Zap STOP right now  Keys redefine function keys 5 Quiet turn off this box to allow more room for data  Xpad use scratch pad  Select an option using arrow keys then confirm selection with the F2 key, or Type the first letter of an option.H  Additional characters required to select from highlighted options.-  Unknown option. 3  Undefined Function Key. ;  Undefined command in this context.  Enter a command by typing first letter of name or move highlight to desired command with left or right arrow, then 6  No more commands to the left 7  No more commands to the right 1  Unknown keystroke :  'Accept' command to go to next screen >  Waiting for computer to complete a task j  Space bar for more text, 'Accept' command to go to next screen g  Page Down or Down Arrow for more text F3 to return to Data k  Page Up or Up Arrow to review previous tNPext F3 to return to Data  Page Down or Down Arrow for more text Page Up or Up Arrow to review previous text F3 to return to Data C  Data values not in correct order for current field  Invalid data input in highlighted field. Use 'Limits' command to see acceptable range, or 'Help' command to see field definition.  Null data input, please enter data in highlighted field. Use 'Limits' command to see acceptable range, or 'Help' command to see field definition. ?  No Help available for this field. <  Default: Minimum: Maximum:  Valid:  Invalid: 3  Any integer is acceptable. 2  Any number is acceptable. 9  Any character string is acceptable.  Enter data in highlighted field(s). Use carriage return or arrow keys to enter data and move between fields. Use 'Accept' command to go to next screen when done entering data. {  Use cursor keys to define window of data. Enter desired operation when window is defined. x  View data in highlighted field. Use 'Help' command to see field definition(s).H  Current field is protected, data value may not be modified.  The value for the number of rows for this 2-dimensional parameter screen is zero, thus the screen is not able to be generated. l  Page Down or Down Arrow for more scratch pad F3 to return to Datat  Page Up or Up Arrow to review previous parts of scratch pad F3 to return to DataOQ  Page Down or Down Arrow for more scratch pad Page Up or Up Arrow to review previous parts of scratch pad F3 to return to Data  Page Down or Down Arrow for more scratch pad Page Up or Up Arrow to review previous parts of scratch pad F3 to return to Data  Option field: use space bar to toggle between ON (X) and OFF ( ). Use carriage return or arrow keys to move between fields. Use 'Accept' command to go to next screen when done entering data.  Unable to toggle on option(s) as the number of allowable selected options for this set would be exceeded. Use the 'Help' command to see field definition.  Not enough options selected for this set. Select more options within this set before continuing. Use the 'Help' command to see field definition.  Use arrow keys to highlight the desired file. Press F2 or RETURN to confirm selection. Or use arrow keys to highlight one of the first 3 fields to change directory/wild card or to type a file name. u  Enter a new directory search path. Press F2 or RETURN to confirm selection. v  Enter a new wild card search string. Press F2 or RETURN to confirm selection. v  Enter a pathname of an existing file. Press F2 or RETURN to confirm selection.  File already exists for the file name entered in this data field. To open the file as a NEW file, you must specify to Overwrite the file. To do so, toggle ON the associated Overwrite field.  File already exists for the file name entered in this data field. Overwriting or Appending to the file may be possible. Use Limits (F5) to see valid options for the field associatedP with this file.  File already exists for the file name entered in this data field. This file may not be opened as a NEW file as overwriting it is not permitted.  File does not exist for the file name entered in this data field. Enter the name of an existing file or use wild card entries (e.g. *.dat) to display available files in the Limits window.  File already in use for the file name entered in this data field. Enter the name of another file or use wild card entries (e.g. *.dat) to display other available files in the Limits window.  Unable to open file specified by the name entered in this data field. Enter the name of another file or use wild card entries (e.g. *.dat) to display other available files in the Limits window.  File name specified in this data field does not match any of the valid file names required for this file. To view the list of valid file names, use the Limits (F5) command.SegC to F Display negative data A B THRSH1 THRSH2 TRt is not. PYRFG DFIELD9 d0,1,2,3,4,5,6,70 u$DIGIT2 is the no. of decimal digits to be used to printdata in the long-span display. Valid values are 0 to 7. DIGIT2 DFIELD10d(c4 Z$FILE2 is the Fortran unit no. of the file to which a long-span display will be routed. FILE2 EFIELD11e( 9 h%PYREND is the calendar month which will appear at theright-hand extremity of an annual summary.PYREND QThis table contains most of the information necessary togenerate data displays.  (1X,7A4,8X,A4,I10,9X,A1,I10,5X,I10,9X,A1,2I10)Title of display Transform Data for short-span display Data for long-span display code PIVL Digits File-no. PYRFG Digits File-no. PYREND i DISPLY Convert DegC to F Display negative data x - x Mult Add THRSH1 THRSH2 DISPLY-INFO2 @@FIELD1 " DISPLY to which these data apply. OPNID `QAFIELD3 aPyy1. w!A is a parameter to convert data from internal units todisplay units: Display value = A * (internal value) + B MULTA AFIELD4 aPyy0. w!B is a parameter to convert data from internal units todisplay units: Display value = A * (internal value) + B ADDB BFIELD5 bPyy0. 0"THRSH1 is the threshhold value for a short-span display.When the individual values in a row of the display have beenaggregated to get the "row value" (hour- or day-value,depending on the display interval), if the row-value isgreater than THRSH1 the row is printed, else it is omitted.THRES1 BFIELD6 bPyy0. "THRSH2 is not presently used. THRES2 WAdditional optional information for module DISPLY.This table is usually not supplied. g (1X,4(1PE10.3)) Convert DUS 1 1DISPLY-INFO1 101 101 301 301 4 1 2DISPLY-INFO2 102 102 302 302 0 0 0END DISPLY 000 000 000 000 J  Select DISPLY table(s) to modify. @ADISPLY-INFO1 @BDISPLY-INFO2 @@A r Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the DISPLY DISPLY-INFO1 table. ` ;A@B r! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the DISPLY DISPLY-INFO2 table. a ; DISPLY<----------Title--------> <-short-span-> x - x <---disply---> x - x TRAN PIVL DIG1 FIL1 PYR DIG2 FIL2 YRND DISPLY-INFO1 @@FIELD1 " DISPLY to which these data apply. OPNID `AAFIELD3 m!TITLE is the title (up to 28 characters) that will beprinted at the top of each page of the display. TITLE aAFIELD4 a SUM ,AVER,MAX ,MIN ,LAST SUM!TRAN is the "transformation code", used to aggregate datafrom the basic interval (internal time step) to the variousdisplay intervals (for both short- and long-span displays).Valid values are: SUM, AVER, MAX, MIN, LAST.TRAN BFIELD5 b(0 "PIVL is the no. of basic time intervals (DELT mins each) tobe aggregated to get to the interval of the data printed ina shortspan display. If PIVL=0, a short-span display is notproduced. PIVL BFIELD6 b0,1,2,3,4,5,6,70 v"DIGIT1 is the no. of decimal digits to be used to printdata in the short-span display. Valid values are 0 to 7. DIGIT1 CFIELD7 c(c4 Z#FILE1 is the Fortran unit no. of the file to which a short-span display will be routed. FILE1 CFIELD8 c(0 n#PYRFG: value of 1 means a long-span display (annual summaryof daily values) is required; 0 means ijT~ $!20000607144801 20000607144801 DISPLY ,  15 W $!20000309112926 20000309112926 GENER  E?f8M  1 VX 1 1OPCODE 101 101 301 301 1 1 1NTERMS 102 102 302 302 7 1 2COEFFS 103 103 303 303 1 1 2PARM 104 104 304 304 0 0 0END GENER 000 000 000 000 O  Select GENER table(s) to modify. @ OPCODE @ NTERMS @ COEFFS @ PARM @@ Ok Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the GENER OPCODE table. ` 1A@ Nk! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the GENER NTERMS table. a 1A@ Ck! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the GENER COEFFS table. a 1 B@ Pi" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the GENER PARM table. b 1  GENER OP- x - x CODE OPCODE @@FIELD1 , GENER operations to which these data apply.OPNID `QAFIELD3 a(-999 \!OPCODE is the GENER operation code. For further details,see Section 4.2(15) of Part E.OPCODE +Operation code for time series generation.  (1X,I10) OPCODE GENER NTERMS x - x NTERMS @@FIELD1 , GENER operations to which these data apply.OPNID `QAFIELD3 a(2 f!NTERMS is the total no. of terms in the power series.This table is only relevant if POCODE=8. NTERMS !Number of terms in power series.  (1X,I10) NTERMSX GENER K1 K2 K3 K4 K5 K6 K7 x - x COEFFS @@FIELD1 , GENER operations to which these data apply.OPNID `AAFIELD3 aPyy0. q!K(1) - K(NTERMS) are the coefficients in the powerfunction. This table is only relevant if OPCODE=8. K1 AFIELD4 aPyy0. K2 BWFIELD5 bPyy0. K3 BFIELD6 bPyy0. K4 CFIELD7 cPyy0. K5 CFIELD8 cPyy0. K6 DFIELD9 dPyy0. K7 +Coefficients in generating power function. Y (1X,10(1PE10.3)) K1 K2 K3 K4 K5 K6 K7  GENER K x - x PARM @@FIELD1 , GENER operations to which these data apply.OPNID `QAFIELD3 aPyy1. F!K is the constant required in the operation. (OPCODE =9,10,11) CONSTK Constant for GENER operation.  (1X,(1PE10.3)) K $!20000309112926 20000309112926 DURANLTS INPUT 10  TIMSER TIMSER 1 1 1 1 2 0 2 0 109 ENG any 0 1 0 1 A mean-valued input time series MET any 0 1 0 1 + $!20000309112926 20000309112926 DISPLYTS INPUT 10  TIMSER TIMSER 1 1 1 1 2 0 2 0 2470 ENG any 0 1 0 1 A mean-valued input time series MET any 0 1 0 1 \ 0 1707 ENG qty/ft3 0 3630. 0 102833. Conc of QUAL in surface outflow MET qty/l 0 3630. 0 102833. IQADDR 10 1 -624 1 2 6 0 1717 ENG qty/aciv 0 1 0 .4047 Dry atmospheric deposition flux to PLS MET qty/haiv 0 1 0 .4047 IQADWT 10 1 -624 1 2 6 0 1727 ENG qty/aciv 0 1 0 .4047 Wet atmospheric deposition flux to PLS MET qty/haiv 0 1 0 .4047 IQADEP 10 1 -624 1 2 6 0 1737 ENG qty/aciv 0 1 0 .4047 Total atmospheric deposition flux to PLS MET qty/haiv 0 1 0 .4047 ][.555 0 1 Temp of surface outflow MET Deg C -32 .555 0 1 SODOX 1 1 1 1 1 5 0 502 ENG mg/l 0 1 0 1 DO conc in surface outflow MET mg/l 0 1 0 1 SOCO2 1 1 1 1 1 5 0 503 ENG mg/l 0 1 0 1 CO2 conc in surface outflow MET mg/l 0 1 0 1 SOHT 1 1 1 1 2 5 0 521 ENG BTU/aciv 0.02.455E-6 0.03.942E-6 Heat in surf outflow (rel. to 0 DEG C) MET kcl/haiv 0.02.455E-6 0.03.942E-6 SODOXM 1 1 1 1 2 5 0 522 ENG lb/aciv 0 4.411 0 3.937 Flux of DO in surface outflow MET kg/haiv 0 4.411 0 3.937 SOCO2M 1 1 1 1 2 5 0 523 ENG lb/aciv 0 4.411 0 3.937 Flux of CO2 in surface outflow MET kg/haiv 0 4.411 0 3.937 SQO 7 1 -626 1 1 6 0 1407 ENG qty/ac 0 1 0 .4047 Storage of QUALOF on the surface MET qty/ha 0 1 0 .4047 SOQSP 7 1 -625 1 1 6 0 1417 ENG qty/ton 0 1 0 .9072 Pot factor of QUALSD on sediment outflow MET qty/tonn 0 1 0 .9072 SOQS 7 1 -625 1 2 6 0 1667 ENG qty/aciv 0 1 0 .4047 Total flux of QUALSD from surface MET qty/haiv 0 1 0 .4047 SOQO 7 1 -626 1 2 6 0 1677 ENG qty/aciv 0 1 0 .4047 Washoff of QUALOF from surface MET qty/haiv 0 1 0 .4047 SOQOC 7 1 -626 1 2 6 0 1687 ENG qty/ft3 0 3630. 0 102833. Conc of QUALOF in surface outflow MET qty/l 0 3630. 0 102833. SOQUAL 10 1 -624 1 2 6 0 1697 ENG qty/aciv 0 1 0 .4047 Total outflow of QUAL from the surface MET qty/haiv 0 1 0 .4047 SOQC 10 1 -624 1 2 6 ^\ MET mm/iv 0 1 0 .0394 IMPS 1 1 1 1 1 3 0 376 ENG in 0 1 0 .0394 Total water stored in the ILS MET mm 0 1 0 .0394 RETS 1 1 1 1 1 3 0 377 ENG in 0 1 0 .0394 Retention storage MET mm 0 1 0 .0394 SURS 1 1 1 1 1 3 1 0 378 ENG in 0 1 0 .0394 Surface (overland flow) storage MET mm 0 1 0 .0394 PETADJ 1 1 1 1 1 3 1 0 379 ENG none 0 1 0 1 Potential ET adjustment factor MET none 0 1 0 1 SUPY 1 1 1 1 2 3 1 0 412 ENG in/iv 0 1 0 .0394 Moisture supply MET mm/iv 0 1 0 .0394 SURO 1 1 1 1 2 3 1 0 413 ENG in/iv 0 1 0 .0394 Surface outflow from ILS MET mm/iv 0 1 0 .0394 PET 1 1 1 1 2 3 0 414 ENG in/iv 0 1 0 .0394 Pot. E-T, adj for snow cover + air temp MET mm/iv 0 1 0 .0394 IMPEV 1 1 1 1 2 3 0 415 ENG in/iv 0 1 0 .0394 Total simulated E-T from ILS MET mm/iv 0 1 0 .0394 SURI 1 1 1 1 2 3 0 416 ENG in/iv 0 1 0 .0394 Surface inflow to ILS MET mm/iv 0 1 0 .0394 SLDS 1 1 1 1 1 4 0 454 ENG tn/ac 0 1 0 .4462 Storage of solids on surface of ILS MET tne/ha 0 1 0 .4462 SOSLD 1 1 1 1 2 4 1 0 462 ENG tn/aciv 0 1 0 .4462 Washoff of solids from surface of ILS MET tne/haiv 0 1 0 .4462 SOTMP 1 1 1 1 1 5 0 501 ENG Deg F -32 _] none 0 1 0 1 SNOCOV 1 1 1 1 1 2 1 0 272 ENG none 0 1 0 1 Fraction of PLS covered by pack MET none 0 1 0 1 DULL 1 1 1 1 1 2 0 273 ENG none 0 1 0 1 Dullness index of the pack MET none 0 1 0 1 ALBEDO 1 1 1 1 1 2 0 274 ENG none 0 1 0 1 Albedo of the pack MET none 0 1 0 1 PAKTMP 1 1 1 1 1 2 0 275 ENG Deg F 0 117.8 1.8 Mean temp of the pack MET Deg C 0 117.8 1.8 DEWTMP 1 1 1 1 1 2 0 276 ENG Deg F 0 117.8 1.8 Effective dewpoint temp MET Deg C 0 117.8 1.8 SNOTMP 1 1 1 1 1 2 0 277 ENG Deg F 0 117.8 1.8 Curren max temp for precip as snowfall MET Deg C 0 117.8 1.8 SNOWF 1 1 1 1 2 2 0 314 ENG in/iv 0 1 0 .0394 Snowfall, water equivalent MET mm/iv 0 1 0 .0394 PRAIN 1 1 1 1 2 2 0 315 ENG in/iv 0 1 0 .0394 Rainfall on pack MET mm/iv 0 1 0 .0394 SNOWE 1 1 1 1 2 2 0 316 ENG in/iv 0 1 0 .0394 Evap from PACKF (sublimation) MET mm/iv 0 1 0 .0394 WYIELD 1 1 1 1 2 2 1 0 317 ENG in/iv 0 1 0 .0394 Water yielded by pack (to land-surface) MET mm/iv 0 1 0 .0394 MELT 1 1 1 1 2 2 0 318 ENG in/iv 0 1 0 .0394 Quantity of melt from PACKF(water equiv) MET mm/iv 0 1 0 .0394 RAINF 1 1 1 1 2 2 1 0 319 ENG in/iv 0 1 0 .0394 Rainfall `^7 IQADCN 10 1 -624 1 2 0 2 0 614 ENG qty/ft3 0 3630. 0 102833. Atmoshperic deposition of QUAL to ILS MET qty/l 0 3630. 0 102833. AIRTMP 1 1 1 1 2 1 1 0 144 ENG Deg F 0 117.8 1.8 Estimated surf air temp over PLS MET Deg C 0 117.8 1.8 PACK 1 1 1 1 1 2 0 262 ENG in 0 1 0 .0394 Total contents of pack(water equiv) MET mm 0 1 0 .0394 PACKF 1 1 1 1 1 2 1 0 263 ENG in 0 1 0 .0394 Frozen contents of pack (water equiv) MET mm 0 1 0 .0394 PACKW 1 1 1 1 1 2 0 264 ENG in 0 1 0 .0394 Liquid water in pack MET mm 0 1 0 .0394 PACKI 1 1 1 1 1 2 1 0 265 ENG in 0 1 0 .0394 Ice in pack (water equiv) MET mm 0 1 0 .0394 PDEPTH 1 1 1 1 1 2 0 266 ENG in 0 1 0 .0394 Pack depth MET mm 0 1 0 .0394 COVINX 1 1 1 1 1 2 0 267 ENG in 0 1 0 .0394 Snowfall cover index for complete cover MET mm 0 1 0 .0394 NEGHTS 1 1 1 1 1 2 0 268 ENG in 0 1 0 .0394 Negative heat storage of pack (water eq) MET mm 0 1 0 .0394 XLNMLT 1 1 1 1 1 2 0 269 ENG in 0 1 0 .0394 Curr max increment to ice in pack MET mm 0 1 0 .0394 RDENPF 1 1 1 1 1 2 0 270 ENG none 0 1 0 1 Rel density of frozen contents of pack MET none 0 1 0 1 SKYCLR 1 1 1 1 1 2 0 271 ENG none 0 1 0 1 Fraction of sky assumed clear METa_ 1 2 0 2 0 154 ENG mi/iv 0 1 0 .621 Measured wind movement over ILS MET km/iv 0 1 0 .621 SOLRAD 1 1 1 1 2 0 2 0 155 ENG Ly/iv 0 1 0 1 Measured solar radiation over ILS MET Ly/iv 0 1 0 1 CLOUD 1 1 1 1 2 0 2 0 156 ENG tenths 0 1 0 1 Cloud cover (range 0 thru 10) MET tenths 0 1 0 1 SURLI 1 1 1 1 2 0 2 0 326 ENG in/iv 0 1 0 .0394 Surface lateral inflow to ILS MET mm/iv 0 1 0 .0394 PETINP 1 1 1 1 2 0 2 0 327 ENG in/iv 0 1 0 .0394 Input potential E-T from ILS MET mm/iv 0 1 0 .0394 SLSLD 1 1 1 1 2 0 2 0 422 ENG tn/ 0 1 0 .4462 Lateral input of solids to ILS MET tne/ 0 1 0 .4462 SLITMP 1 1 1 1 2 0 2 0 466 ENG Deg F -32 .555 0 1 Temp of surface lateral inflow MET Deg C -32 .555 0 1 SLIDOX 1 1 1 1 2 0 2 0 467 ENG mg/l 0 1 0 1 Conc of DO in surface lateral inflow MET mg/l 0 1 0 1 SLICO2 1 1 1 1 2 0 2 0 468 ENG mg/l 0 1 0 1 Conc of CO2 in surface lateral inflow MET mg/l 0 1 0 1 SLIQO 7 1 -626 1 2 0 2 0 584 ENG qty/aciv 0 1 0 .4047 Lateral input of QUALOF to ILS MET qty/haiv 0 1 0 .4047 SLIQSP 7 1 -625 1 2 0 2 0 594 ENG qty/ton 0 1 0 .9072 Pot fac of QUALSD on lat sediment inflow MET qty/tonn 0 1 0 .9072 IQADFX 10 1 -624 1 2 0 2 0 604 ENG qty/aciv 0 1 0 .4047 Atmoshperic deposition of QUAL to ILS MET qty/haiv 0 1 0 .4043` $!20030814161355 20030814161355 IMPLNDTSJ $JX]iz*U,W2]޾ 4_:e<gBmúDoŻJu˸!Lw͹'R}M EXTNL 20ATEMP 40SNOW 50IWATER 80SOLIDS 90IWTGAS 100IQUAL 110 h GATMPPRECDTMPGWINMOVSOLRADCLOUDSURLIPETINPSLSLDSLITMPSLIDOXSLICO2SLIQOSLIQSPIQADFXIQADCN AIRTMP PACKPACKFPACKWPACKIPDEPTHCOVINXNEGHTSXLNMLTRDENPFSKYCLRSNOCOVDULLALBEDOPAKTMPDEWTMPSNOTMPSNOWFPRAINSNOWEWYIELDMELTRAINF / IMPSRETSSURSPETADJSUPYSUROPETIMPEVSURI SLDSSOSLD % SOTMPSODOXSOCO2SOHTSODOXMSOCO2M ; SQOSOQSPSOQSSOQOSOQOCSOQUALSOQCIQADDRIQADWTIQADEP GATMP 1 1 1 1 2 0 2 0 115 ENG Deg F 0 117.8 1.8 Measured air temp over ILS MET Deg C 0 117.8 1.8 PREC 1 1 1 1 2 0 2 0 116 ENG in/iv 0 1 0 .0394 Measured precipitation on ILS MET mm/iv 0 1 0 .0394 DTMPG 1 1 1 1 2 0 2 0 153 ENG Deg F 0 117.8 1.8 Measured dewpoint temp over ILS MET Deg C 0 117.8 1.8 WINMOV 1 1 1 sc2 218 332 418 34 71 12 10 2MON-POTFW 133 219 333 419 35 71 12 10 2MON-ACCUM 134 220 334 420 36 71 12 10 2MON-SQOLIM 135 221 335 421 37 71 0 0 0END IMPLND 000 000 000 000 38T GENERAL 1ATEMP 2SNOW 3IWATER 4SOLIDS 5IWTGAS 6IQUAL 7 QUAL-PROPS QUALIDQUAL-INPUT QUALIDMON-POTFW QUALID QSDFGMON-POTFS QUALID QSDFGMON-ACCUM QUALID QSOFGMON-SQOLIM QUALID QSOFG *  0 17 19 18 }  Select IMPLND section(s) to modify. @ GENERAL, ATEMP, SNOW, IWATER @ SOLIDS, IWTGAS, IQUAL @@ GEN Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the tables in the GENERAL, ATEMP, SNOW, orIWATER sections. ` yA@ SOL ! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the tables in the SOLIDS, IWTGAS, or IQUALsections.a ]  Select IMPLND table(s) to modify. GENERAL ATMP/SNOW IWATER-General IWATER-Monthly @ ACTIVITY @ ATEMP-DAT @FIWAT-PARM1 @ MON-RETN @ PRINT-INFO @ ICE-FLAG @GIWAT-PARM2 @ MON-MANNING @ BINARY-INFO @ SNOW-FLAGS @HIWAT-PARM3 @ GEN-INFO @BSNOW-PARM1 @ IWAT-STATE1 @CSNOW-PARM2 @ MON-MELT-FAC @DSNOW-INIT1 @ESNOW-INIT2 @@ ACTIVn Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND ACTIVITY table. ` )A@ PRINTp! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND PRINT-INFO table.a 1 A@ BINARY q! Toggle field On (X) or Obdff ( ) using the space bar. Toggle this field on to edit the IMPLND BINARY-INFO table. a 5  B@ GEN-IN n" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND GEN-INFO table. b )B@ ATEMPo" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND ATEMP-DAT table. b - C@ ICE-FLAG n# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND ICE-FLAG table. c ) C@ SNOW-FLAGS p# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND SNOW-FLAGS table.c 1D@B p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND SNOW-PARM1 table.d 3 D@C p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND SNOW-PARM2 table.d 3$E@ MON-MELT-FAC r% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-MELT-FAC table. e 9(E@D p% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND SNOW-INIT1 table.e 3,F@E p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND SNOW-INIT2 table.f 30F@F p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND IWAT-PARM1 table.f 34G@G p' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND IWAT-PARM2 table.g 38G@H p' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND IWAT-PARM3 table.g 3< H@ MON-RE n( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-RETN table. h )@ H@ MON-MA q( Toggle field On (X) or Off (ce ) using the space bar. Toggle this field on to edit the IMPLND MON-MANNING table. h 5D I@ IWAT-S q) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND IWAT-STATE1 table. i 5H  Select IMPLND table(s) to modify. SOLIDS IWTGAS IQUAL @ASLD-PARM1 @CIWT-PARM1 @ NQUALS @ MON-POTFW @BSLD-PARM2 @DIWT-PARM2 @ IQL-AD-FLAGS @ MON-ACCUM @ MON-SACCUM @ LAT-FACTOR @ QUAL-PROPS @ MON-SQOLIM @ MON-REMOV @ MON-AWTF @ QUAL-INPUT @ SLD-STOR @ MON-BWTF @ IWT-INIT @@A o Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND SLD-PARM1 table. ` /A@B o! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND SLD-PARM2 table. a / A@ MON-SACCUM p! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-SACCUM table.a 1  B@ MON-REMOVo" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-REMOV table. b - B@ SLD-STOR n" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND SLD-STOR table. b )C@C o# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND IWT-PARM1 table. c /C@D o# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND IWT-PARM2 table. c / D@ LAT-FACTOR p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND LAT-FACTOR table.d /  D@ MON-AWTF n$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-AWTF table. d )$ E@ MON-BWTF n% Toggle field On df(X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-BWTF table. e )( E@ IWT-INIT n% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND IWT-INIT table. e ), F@ NQUALS l& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND NQUALS table.f 10F@ IQL-AD-FLAGS r& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND IQL-AD-FLAGS table. f 94 G@ QUAL-PROPS p' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND QUAL-PROPS table.g 18 G@ QUAL-INPUT p' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND QUAL-INPUT table.g 1< H@ MON-POTFWo( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-POTFW table. h -@ H@ MON-ACCUMo( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-ACCUM table. h -D I@ MON-SQOLIM p) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the IMPLND MON-SQOLIM table.i 1H^ 201 1 0. 3.28 ATEMP-DAT ELDAT201 2 17.77 1.8 ATEMP-DAT AIRTMP202 2 0. 3.28 SNOW-PARM1 MELEV202 5 0. 0.0394 SNOW-PARM1 COVIND202 6 0. 0.0219 SNOW-PARM1 KMELT202 7 17.77 1.8 SNOW-PARM1 TBASE203 2 17.77 1.8 SNOW-PARM2 TSNOW203 6 0. 0.0394 SNOW-PARM2 MGMELT204 0 0. 0.0219 MON-MELT-FAC KMELTM205 1 0. 0.0394 SNOW-INIT1 Pack-snow205 2 0. 0.0394 SNOW-INIT1 Pack-ice205 3 0. 0.0394 SNOW-INIT1 Pack-water205 6 17.77 1.8 SNOW-INIT1 PAKTMP206 1 0. 0.0394 SNOW-INIT2 COVINX206 2 0. 0.0394 SNOW-INIT2 XLNMLT207eg 1 0. 3.28 IWAT-PARM2 LSUR207 4 0. 0.0394 IWAT-PARM2 RETSC208 0 17.77 1.8 IWAT-PARM3 (ALL)209 0 0. 0.0394 MON-RETN RETSCM210 0 0. 0.0394 IWAT-STATE1 (ALL)211 3 0. 0.446 SLD-PARM2 ACCSDP212 0 0. 0.446 MON-SACCUM ACCSDM213 0 0. 0.446 SLD-STOR SLDS214 1 0. 3.28 IWT-PARM2 ELEV124 2 -32. .555 IWT-PARM2 AWTF126 0 -32. .555 MON-AWTF AWTFM128 1 -32. .555 IWT-INIT SOTMP218 1 0. 0.4047 QUAL-INPUT SQO218 2 0. 0.907 QUAL-INPUT POTFW218 3 0. 0.4047 QUAL-INPUT ACQOP218 4 0. 0.4047 QUAL-INPUT SQOLIM218 5 0. 0.0394 QUAL-INPUT WSQOP219 0 0. 0.907 MON-POTFW POTFWM220 0 0. 0.4047 MON-ACCUM ACQOPM221 0 0. 0.4047 MON-SQOLIM SQOLIM R Active Sections x - x ATMP SNOW IWAT SLD IWG IQAL ACTIVITY @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(0 .!value of 1 indicates section ATEMP is active ATMPFG AFIELD4 a(0 -!value of 1 indicates section SNOW is active SNOWFG BFIELD5 b(0 0"value of 1 indicates section IWATER is active.IWATFG BFIELD6 b(0 0"value of 1 indicates section SOLIDS is active.SLDFG CFIELD7 c(0 0#value of 1 indicates section IWTGAS is active.IWGFG CFIELD8 c(0 .#value of 1 indicates section IQUAL is active IQALFG Active sections of IMPLND. G (1X,6I10) AIRTFG SNOWFG IWATFG SLDFG IWGFG IQALFG f ******** Print-flags ******** PIVL PYR x - x ATMP SNOW IWAT SLD IWG IQAL ********* PRINT-INFO @@FIELD1  ILS to which these data apply. OPNIfhD `QAFIELD3 a(4 !!Printout level for section ATMP. ATMPPR AFIELD4 a(4 !!Printout level for section SNOW. SNOWPR BFIELD5 b(4 !"Printout level for section IWAT. IWATPR BFIELD6 b(4 "Printout level for section SLD.SLDPR CFIELD7 c(4 #Printout level for section IWG.IWGPR CFIELD8 c(4 !#Printout level for section IQAL. IQALPR DFIELD9 d(1 $A value need only be supplied for PIVL if one or more sectionshave a printout level of 2. For those sections, printout willoccur every PIVL intervals (that is, every PDELT=PIVL*DELTmins). PIVL must be chosen such that there are an integerno. of PDELT periods in a day.PIVL DFIELD10d( 9 €$PYREND is the calendar month which will terminate the yearfor printout purposes. Thus, the annual summary can reflectthe situation over the past water year or the past calendaryear, etc. PYREND Printout information of IMPLND.HSPF permits the user to vary the printout level (maximumfrequency) for the various active sections of an operation.2 means every PIVL intervals, 3 means every day, 4 meansevery month, 5 means every year, 6 means never. | (1X,6I5,I10,I12) Printout level flags Print-ivl Print-yrendATEMP SNOW IWAT SLD IWTG IQAL PIVL PYRENDf **** Binary-Output-flags **** PIVL PYR x - x ATMP SNOW IWAT SLD IWG IQAL ********* BINARY-INFO@@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(4 !Output level for section ATMP. ATMPPR AFIELD4 a(4 !Output level for section SNOW. SNOWPR BFIELD5 b(4 "Output level for section IWAT. IWATPR BFIELD6 b(gi4 "Output level for section SLD. SLDPR CFIELD7 c(4 #Output level for section IWG. IWGPR CFIELD8 c(4 #Output level for section IQAL. IQALPR DFIELD9 d(1 $A value need only be supplied for PIVL if one or more sectionshave a output level of 2. For those sections, output willoccur every PIVL intervals (that is, every PDELT=PIVL*DELTmins). PIVL must be chosen such that there are an integerno. of PDELT periods in a day.PIVL DFIELD10d( 9 $PYREND is the calendar month which will terminate the yearfor output purposes. Thus, the annual summary can reflectthe situation over the past water year or the past calendaryear, etc.PYREND Binary Output information of IMPLND.HSPF permits the user to vary the output level (maximumfrequency) for the various active sections of an operation.2 means every PIVL intervals, 3 means every day, 4 meansevery month, 5 means every year, 6 means never. | (1X,6I5,I10,I12) Binary Output level flags Print-ivl Print-yrendATEMP SNOW IWAT SLD IWTG IQAL PIVL PYREND Name Unit-systems Printer BinaryOut t-series Engl Metr Engl Metr x - x in out GEN-INFO @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 T!Any string of up to 20 characters may be supplied as theidentifier for an ILS.LSID aAFIELD4 a(1 v!IUNITS indicates the system of units for data in the inputtime series; 1 means English units, 2 means Metric units. IUNITS BFIELD5 b(1 w"OUNITS indicates the system of units for data in the outputtime series; 1 means English units, 2 means Metric units. OUNITS BFIELD6 b(c0 Ձ"PUNIT(1) indichjates the destinations of printout in Englishunits. A value 0 means no printout is required in Englishunits. A non-zero value means printout is required inEnglish units and the value is the Fortran unit no. of thefile to which the printout is to be written. Note thatprintout for each Impervious Land Segment can be obtained ineither the English or Metric systems, or both (irrespectiveof the system used to supply the inputs). PUNIT1 CFIELD7 c(c0 #PUNIT(2) indicates the destinations of printout in Metricunits. A value of 0 means no printout is required in Metricunits. A non-zero value means printout is required inMetric units and the value is the Fortran unit no. of thefile to which the printout is to be written. Note thatprintout for each Impervious Land Segment can be obtained ineither the English or Metric systems, or both (irrespectiveof the system used to supply the inputs). PUNIT2 CFIELD8 c(c0 #BUNIT(1) is the destination of binary output in Englishunits. A value of 0 means no binary output is required inEnglish units. A non-zero value means binary output isrequired in English units and the value is the Fortran unitno. of the file to which the binary output is to be written.Note that binary output for each Impervious Land Segment canbe obtained in either the English or Metric systems, or both(irrespective of the system used to supply the inputs). BUNIT1 DFIELD9 d(c0 $BUNIT(2) is the destination of binary output in Metricunits. A value of 0 means no binary output is required inMetric units. A non-zero value means binary output isrequired in Metric units and the value is the Fortran unitno. of the file to which the binary output is to be written.Note that binary output for each Impervious Land Segment canbe obtained in either the English or Metric systems, or both(irrespective of the systikem used to supply the inputs). BUNIT2 General information for IMPLND. (1X,5A4,2I10,2I10,2I10)Imperv Land-segment id Unit systems Print-file nos BinaryOutfileNos IUNITS OUNITS English Metric English Metric @ ELDAT AIRTEMP x - x (ft) (deg F) ATEMP-DAT @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPyy0. !ELDAT is the difference in elevation between thetemperature gage and the ILS; it is used to estimate thetemperature over the ILS by application of a lapse rate. Itis positive if the ILS is higher than the gage, and viceversa. ELDAT AFIELD4 aPp C60.F!AIRTMP is the air temperature over the ILS at the start ofthe RUN. AIRTMP Data for section ATEMP.: (1X,2(1PE10.3)) ELDAT AIRTEMP (ft) (deg F) ? ELDAT AIRTEMP x - x (m) (deg C) ATEMP-DAT @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPyy0. !ELDAT is the difference in elevation between thetemperature gage and the ILS; it is used to estimate thetemperature over the ILS by application of a lapse rate. Itis positive if the ILS is higher than the gage, and viceversa. ELDAT AFIELD4 aPHpB15.F!AIRTMP is the air temperature over the ILS at the start ofthe RUN. AIRTMP Data for section ATEMP.: (1X,2(1PE10.3)) ELDAT AIRTEMP (m) (deg C)  Ice- x - x flag ICE-FLAG @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(0 Y!A value of 0 means ice formation in snow pack will not besimulated; 1 means it will. ICEFG Flag to simulate ice formation. (1X,I10) Ice- flag jl  x - x SNOP VKM SNOW-FLAGS @@FIELD1 ILSs to which these data apply.OPNID `QAFIELD2 a(0 !A value of 0 means that the atmospheric heat exchange portion ofsnowmelt will be based on the energy balance; 1 means it will bebased on a degree-day factor.SNOPFG AFIELD3 a(0 S!VKMFG:value of 1 means vary degree-day factor monthly;0 means use annual value. VKMFG Snow flags. (1X,2I10) SNOPFG VMKFG  LAT MELEV SHADE SNOWCF COVIND KMELT TBASE x - x degrees (ft) (in) (in/d.F) (F) SNOW-PARM1 @@FIELD1 ILSs to which these data apply.OPNID `AAFIELD2 aPB40.x!LAT is the latitude of the ILS. It is positive for thenorthern hemisphere, negative for the southern hemisphere.LATAFIELD3 aP`F0. )!MELEV is the mean elevation of the ILS. MELEV BFIELD4 bP?0. _"SHADE is the fraction of the ILS which is shaded from solarradiation by, for example, trees. SHADE BFIELD5 bP?B-999. À"SNOWCF is the factor by which recorded precipitation datawill be multiplied if the simulation indicates it issnowfall, to account for poor catch efficiency under snowconditions. SNOWCF CFIELD6 cP #<y-999. #COVIND is the maximum pack (water equivalent) at which theentire ILS will be covered with snow (see functionaldescription of SNOW section).COVIND CFIELD7 cPy0.06#KMELT is the degree-day snowmelt factor when SNOPFG=1 KMELT DFIELD8 dPpB32.T$TBASE is the base temperature for the degree-day snowmeltcalculation when SNOPFG=1TBASE First group of SNOW parameters. (1X,5(1PE10.3)) LAT MELEV SHAkmDE SNOWCF COVIND KMELT TBASE degrees (ft) (in) (in/d.F) (F)  LAT MELEV SHADE SNOWCF COVIND KMELT TBASE x - x degrees (m) (mm) (mm/d.C) (C) SNOW-PARM1 @@FIELD1 ILSs to which these data apply.OPNID `QAFIELD2 aPB40.x!LAT is the latitude of the ILS. It is positive for thenorthern hemisphere, negative for the southern hemisphere.LATAFIELD3 aP@F0. )!MELEV is the mean elevation of the ILS. MELEV BFIELD4 bP?0. _"SHADE is the fraction of the ILS which is shaded from solarradiation by, for example, trees. SHADE BFIELD5 bP?B-999. À"SNOWCF is the factor by which recorded precipitation datawill be multiplied if the simulation indicates it issnowfall, to account for poor catch efficiency under snowconditions. SNOWCF CFIELD6 cP>y-999. #COVIND is the maximum pack (water equivalent) at which theentire ILS will be covered with snow (see functionaldescription of SNOW section).COVIND CFIELD7 cPy0.06#KMELT is the degree-day snowmelt factor when SNOPFG=1 KMELT DFIELD8 dPA0. T$TBASE is the base temperature for the degree-day snowmeltcalculation when SNOPFG=1TBASE First group of SNOW parameters. (1X,5(1PE10.3)) LAT MELEV SHADE SNOWCF COVIND KMELT TBASE degrees (m) (mm) (mm/d.C) (C)  RDCSN TSNOW SNOEVP CCFACT MWATER MGMELT x - x (deg F) (in/day) SNOW-PARM2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aP #<?0.15 !RDCSN is the delnnsity of cold, new snow relative to water.This value applies to snow falling at air temps <= 0degF.At higher temperatures the density of snow is adjusted. RDCSN AFIELD4 aPA B32.!TSNOW is the air temperature below which precipitation willbe snow, under saturated conditions. Under non-saturatedconditions the temperature is adjusted slightly. TSNOW BFIELD5 bP?0.1i"SNOEVP is a parameter which adapts the snow evaporation(sublimation) equation to field conditions. SNOEVP BFIELD6 bP A1. x"CCFACT is a parameter which adapts the snowcondensation/convection melt equation to field conditions.CCFACT CFIELD7 cP?0.03 e#MWATER is the maximum water content of the snow pack, indepth water per depth water equivalent. MWATER CFIELD8 cP?0.01 #MGMELT is the maximum rate of snowmelt by ground heat, indepth of water equivalent per day. This is the value whichapplies when the pack temperature is at freezing point. MGMELT !Second group of SNOW parameters. (1X,6(1PE10.3)) RDCSN TSNOW SNOEVP CCFACT MWATER MGMELT (deg F) (in/day)  RDCSN TSNOW SNOEVP CCFACT MWATER MGMELT x - x (deg C) (mm/day) SNOW-PARM2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aP #<?0.15 !RDCSN is the density of cold, new snow relative to water.This value applies to snow falling at air temps <= 0degF.At higher temperatures the density of snow is adjusted. RDCSN AFIELD4 aP@0. !TSNOW is the air temperature below which precipitation willbe snow, under saturated conditions. Under non-saturatedconditions the temperature is adjusted slightlmoy. TSNOW BFIELD5 bP?0.1i"SNOEVP is a parameter which adapts the snow evaporation(sublimation) equation to field conditions. SNOEVP BFIELD6 bP A1. x"CCFACT is a parameter which adapts the snowcondensation/convection melt equation to field conditions.CCFACT CFIELD7 cP?0.03 e#MWATER is the maximum water content of the snow pack, indepth water per depth water equivalent. MWATER CFIELD8 cPA0.25 #MGMELT is the maximum rate of snowmelt by ground heat, indepth of water equivalent per day. This is the value whichapplies when the pack temperature is at freezing point. MGMELT !Second group of SNOW parameters. (1X,6(1PE10.3)) RDCSN TSNOW SNOEVP CCFACT MWATER MGMELT (deg C) (mm/day)  Degree-day snowmelt factor at start of each month (in/d.F) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-MELT-FAC @`KMELT @FIELD1 ILSs to which these data apply.OPNID `QAFIELD2 a(y0. @!KMJAN is the degree-day snowmelt factor at the start of JanuaryKMJAN AFIELD3 a(y0. KMFEB BFIELD4 b(y0. KMMAR BFIELD5 b(y0. KMAPR CFIELD6 c(y0. KMMAY CFIELD7 c(y0. KMJUN DFIELD8 d(y0. KMJUL DFIELD9 d(y0. KMAUG EFIELD10e(y0. KMSEP EFIELD11e(y0. KMOCT FFIELD12f(y0. KMNOV FFIELD13f(y0. KMDEC Monthly values of degree-day snowmelt factor at start of each month.This table is only required if VKMFG in Table-type SNOW-FLAnpGS is 1. (1X,12(1PE10.3))Values of Degree-day snowmelt factor at start of each calendar month (in/d.F): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Degree-day snowmelt factor at start of each month (mm/d.C) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-MELT-FAC @`KMELT @FIELD1 ILSs to which these data apply.OPNID `QAFIELD2 a(y0. @!KMJAN is the degree-day snowmelt factor at the start of JanuaryKMJAN AFIELD3 a(y0. KMFEB BFIELD4 b(y0. KMMAR BFIELD5 b(y0. KMAPR CFIELD6 c(y0. KMMAY CFIELD7 c(y0. KMJUN DFIELD8 d(y0. KMJUL DFIELD9 d(y0. KMAUG EFIELD10e(y0. KMSEP EFIELD11e(y0. KMOCT FFIELD12f(y0. KMNOV FFIELD13f(y0. KMDEC Monthly values of degree-day snowmelt factor at start of each month.This table is only required if VKMFG in Table-type SNOW-FLAGS is 1. (1X,12(1PE10.3))Values of Degree-day snowmelt factor at start of each calendar month (mm/d.C): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Pack-snow Pack-ice Pack-watr RDENPF DULL PAKTMP x - x (in) (in) (in) (deg F) SNOW-INIT1 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPy0. J!Pack-snow is the quantity of snow in the pack (waterequivalent). PKSNOW AFIELD4 aPy0. I!Pack-ice is the quantity of ice in the oqpack (waterequivalent) PKICE BFIELD5 bPy0. 8"Pack-watr is the quantity of liquid water in the pack.PKWATR BFIELD6 bP #<?0.2Z"RDENPF is the density of the frozen contents (snow+ice) ofthe pack, relative to water. RDENPF CFIELD7 cPHD400. X#DULL is an index to the dullness of the pack surface, fromwhich albedo is estimated.DULL CFIELD8 cPyB32.G#PAKTMP is the mean temperature of the frozen contents ofthe pack. PAKTMP 3First group of initial values for SNOW simulation. (1X,6(1PE10.3)) Pack-snow Pack-ice Pack-watr RDENPF DULL PAKTMP (in) (in) (in) (deg F)  Pack-snow Pack-ice Pack-watr RDENPF DULL PAKTMP x - x (mm) (mm) (mm) (deg C) SNOW-INIT1 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPy0. J!Pack-snow is the quantity of snow in the pack (waterequivalent). PKSNOW AFIELD4 aPy0. I!Pack-ice is the quantity of ice in the pack (waterequivalent) PKICE BFIELD5 bPy0. 8"Pack-watr is the quantity of liquid water in the pack.PKWATR BFIELD6 bP #<?0.2Z"RDENPF is the density of the frozen contents (snow+ice) ofthe pack, relative to water. RDENPF CFIELD7 cPHD400. X#DULL is an index to the dullness of the pack surface, fromwhich albedo is estimated.DULL CFIELD8 cPy0. G#PAKTMP is the mean temperature of the frozen contents ofthe pack. PAKTMP 3First group of initial values for SNOW simulation. (1X,6(1PE10.3)) Pack-snow Pack-ice Pack-watr RDENPF DULL PAKTMP (mm) (mm) (mm) (deg C) prH COVINX XLNMLT SKYCLR x - x (in) (in) SNOW-INIT2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aP #<y0.01 !COVINX is the current pack (water equivalent) required toobtain complete areal coverage of the ILS. If the pack isless than this amount, areal cover is prorated(PACKF/COVINX). COVINX AFIELD4 aPy0. À!XLNMLT is the current remaining possible increment to icestorage in the pack (see functional description). Thisvalue is only relevant if ice formation is being simulated(ICEFG= 1). XLNMLT BFIELD5 bP>?1. R"SKYCLR is the fraction of sky which is assumed to be clearat the present time. SKYCLR 4Second group of initial values for SNOW simulation.D (1X,3(1PE10.3)) COVINX XLNMLT SKYCLR (in) (in)H COVINX XLNMLT SKYCLR x - x (mm) (mm) SNOW-INIT2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aP>y0.25 !COVINX is the current pack (water equivalent) required toobtain complete areal coverage of the ILS. If the pack isless than this amount, areal cover is prorated(PACKF/COVINX). COVINX AFIELD4 aPy0. À!XLNMLT is the current remaining possible increment to icestorage in the pack (see functional description). Thisvalue is only relevant if ice formation is being simulated(ICEFG= 1). XLNMLT BFIELD5 bP>?1. R"SKYCLR is the fraction of sky which is assumed to be clearat the present time. SKYCLR 4Second group of initial values for SNOW simulation.D (1X,3(1PE10.3)) COVINX XLNMLT SKYCLR (mm) (mm)< Flags x - x CSNO RTOP VRS VNN RTLI IWAT-PARM1 @@FIELD1  ILS to which theqsse data apply. OPNID `QAFIELD3 a(0 !If CSNOFG is 1, section IWATER assumes that snowaccumulation and melt is being considered. It will,therefore, expect that the time series produced by sectionSNOW are available, either internally (produced in this RUN)or from external sources (produced in a previous RUN). IfCSNOFG is 0, no such time series are expected. See thefunctional description for further information. CSNOFG AFIELD4 a(0 !If RTOPFG is 1, routing of overland flow is done in exactlythe same way as in NPS. A value of 0 results in a newalgorithm being used.RTOPFG BFIELD5 b(0 `"VRSFG: value of 1 means vary retention storage capacitymonthly; 0 means use annual value.VRSFG BFIELD6 b(0 k"VNNFG: value of 1 means vary Manning's n for the overlandflow plane monthly; 0 means use annual value. VNNFG CFIELD7 c(0 w#If RTLIFG is 1, any lateral surface inflow to the ILS willbe subject to retention storage; if it is 0, it will not. RTLIFG *First group of IWATER parameters (flags). = (1X,5I10) CSNOFG RTOPFG VRSFG VNNFG RTLIFG f LSUR SLSUR NSUR RETSC x - x (ft) (in) IWAT-PARM2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aP?y-999. 8!LSUR is the length of the assumed overland flow plane.LSUR AFIELD4 aP75 A-999. 8!SLSUR is the slope of the assumed overland flow plane.SLSUR BFIELD5 bPn:?0.12"NSUR is Manning's n for the overland flow plane. NSUR BFIELD6 bP A0. J"RETSC is the retention (interception) storage capacity ofthe surface. RETSC #Second group of IWATER parameterrts. b (1X,4(1PE10.3)) LSUR SLSUR NSUR RETSC (ft) (nManning) (in) f LSUR SLSUR NSUR RETSC x - x (m) (mm) IWAT-PARM2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aP>y-999. 8!LSUR is the length of the assumed overland flow plane.LSUR AFIELD4 aP75 A-999. 8!SLSUR is the slope of the assumed overland flow plane.SLSUR BFIELD5 bPn:?0.12"NSUR is Manning's n for the overland flow plane. NSUR BFIELD6 bPzC0. J"RETSC is the retention (interception) storage capacity ofthe surface. RETSC #Second group of IWATER parameters. b (1X,4(1PE10.3)) LSUR SLSUR NSUR RETSC (m) (nManning) (mm) > PETMAX PETMIN x - x (deg F) (deg F) IWAT-PARM3 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPyy40.!PETMAX is the air temperature below which E-T willarbitrarily be reduced below the value obtained from theinput time series. PETMAX AFIELD4 aPyy35.o!PETMIN is the temperature below which E-T will be zeroregardless of the value in the input time series. PETMIN "Third group of IWATER parameters. : (1X,2(1PE10.3)) PETMAX PETMIN (deg F) (deg F) > PETMAX PETMIN x - x (deg C) (deg C) IWAT-PARM3 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPyy4.4!PETMAX is the air temperature below which E-T willarbitrarily be reduced below the value obtained from theinput time series. PETMAX AFIELD4 aPyy1.7o!PETMIN is the temperature below which E-T wsuill be zeroregardless of the value in the input time series. PETMIN "Third group of IWATER parameters. : (1X,2(1PE10.3)) PETMAX PETMIN (deg C) (deg C)  Retention storage capacity at start of each month (in) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-RETN @`RETSC @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a( A0. 4!RETS1 is the retention storage capacity in January.RETS1 AFIELD4 a( A0. RETS2 BFIELD5 b( A0. RETS3 BFIELD6 b( A0. RETS4 CFIELD7 c( A0. RETS5 CFIELD8 c( A0. RETS6 DFIELD9 d( A0. RETS7 DFIELD10d( A0. RETS8 EFIELD11e( A0. RETS9 EFIELD12e( A0. RETS10 FFIELD13f( A0. RETS11 FFIELD14f( A0. RETS12 Monthly Values of retention storage capacity at start of each moThis table is only required if VRSFG in Table-type IWAT-PARM1 is (1X,12(1PE10.3))Values of Retention Storage at start of each calendar month (inches): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Retention storage capacity at start of each month (mm) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-RETN @`RETSC @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(zC0. 4!RETS1 is the retention storage capacity in January.RETS1 AFIELD4 a(zC0. RETS2 BFIELD5 b(zC0. RETS3 BFIELD6 b(zC0. RETS4 CFIELD7 c(zC0. RETStv5 CFIELD8 c(zC0. RETS6 DFIELD9 d(zC0. RETS7 DFIELD10d(zC0. RETS8 EFIELD11e(zC0. RETS9 EFIELD12e(zC0. RETS10 FFIELD13f(zC0. RETS11 FFIELD14f(zC0. RETS12 Monthly Values of retention storage capacity at start of each moThis table is only required if VRSFG in Table-type IWAT-PARM1 is (1X,12(1PE10.3))Values of Retention Storage at start of each calendar month (mm): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DECv Manning's n at start of each month x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-MANNING@`NSUR @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(n:?0.1+!NSUR1 is the Manning's n value in January. NSUR1 AFIELD4 a(n:?0.1NSUR2 BFIELD5 b(n:?0.1NSUR3 BFIELD6 b(n:?0.1NSUR4 CFIELD7 c(n:?0.1NSUR5 CFIELD8 c(n:?0.1NSUR6 DFIELD9 d(n:?0.1NSUR7 DFIELD10d(n:?0.1NSUR8 EFIELD11e(n:?0.1NSUR9 EFIELD12e(n:?0.1NSUR10 FFIELD13f(n:?0.1NSUR11 FFIELD14f(n:?0.1NSUR12 Values of Manning's n for the overland flow plane at start of eamonth. This table is only required if VNNFG in Table-typeIWAT-PARM1 is 1. (1X,12(1PE10.3))Values of Manning's N at start of each calendar month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC K IWATER state variables (inches) x - uw x RETS SURS IWAT-STATE1@@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPB0.001 (!RETS is the initial retention storage.RETS AFIELD4 aPB0.001 6!SURS is the initial surface (overland flow) storage. SURS 9This table is used to specify the inital water storages. 8 (1X,2(1PE10.3))Storages (inches): RETS SURSG IWATER state variables (mm) x - x RETS SURS IWAT-STATE1@@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aP@E0.025 (!RETS is the initial retention storage.RETS AFIELD4 aP@E0.025 6!SURS is the initial surface (overland flow) storage. SURS 9This table is used to specify the inital water storages. 4 (1X,2(1PE10.3))Storages (mm): RETS SURS/ Flags x - x VASD VRSD SDOP SLD-PARM1 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(0 g!VASDFG: value of 1 means vary the accumulation rate ofsolids monthly; 0 means use annual value. VASDFG AFIELD4 a(0 g!VRSDFG: value of 1 means vary the unit removal rate ofsolids monthly; 0 means use annual value. VRSDFG BFIELD5 b(0 "If SDOPFG is 1, removal of sediment from the land surfacewill be simulated with the algorithm used in the NPS model.If it is 0, the new algorithm will be used. SDOPFG +First group of SOLIDS parameters (IMPLND). ) (1X,3I10) VASDFG VRSDFG SDOPFG  KEIM JEIM ACCSDP REMSDP tons/ /day x - x ac.day SLD-PARM2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPvxy0. 9!KEIM is the coefficient in the solids washoff equation. KEIM AFIELD4 aPyy-999. 6!JEIM is the exponent in the solids washoff equation. JEIM BFIELD5 bPy0. "ACCSDP is the rate at which solids are placed on the landsurface. If monthly values are being supplied, value suppliedin this table is not relevant. ACCSDP BFIELD6 bP?0. "REMSDP is the fraction of solids storage which is removedeach day. If monthly values are being supplied, value suppliedin this table is not relevant.REMSDP ,Second group of SOLIDS parameters (IMPLND).b (1X,4(1PE10.3)) KEIM JEIM ACCSDP REMSDP (tns/ac.d) (/day)  KEIM JEIM ACCSDP REMSDP tne/ /day x - x ha.day SLD-PARM2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPy0. 9!KEIM is the coefficient in the solids washoff equation. KEIM AFIELD4 aPyy-999. 6!JEIM is the exponent in the solids washoff equation. JEIM BFIELD5 bPy0. "ACCSDP is the rate at which solids are placed on the landsurface. If monthly values are being supplied, value suppliedin this table is not relevant. ACCSDP BFIELD6 bP?0. "REMSDP is the fraction of solids storage which is removedeach day. If monthly values are being supplied, value suppliedin this table is not relevant.REMSDP ,Second group of SOLIDS parameters (IMPLND).b (1X,4(1PE10.3)) KEIM JEIM ACCSDP REMSDP (tne/ha.d) (/day)  Monthly values for solids accumulation (tons/ac.day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-SACCUM @`ACCSDP @FIELwyD1  ILS to which these data apply. OPNID `QAFIELD3 a(y0. 2!ACCS1 is the solids accumulation rate in January. ACCS1 AFIELD4 a(y0. AACS2 BFIELD5 b(y0. ACCS3 BFIELD6 b(y0. ACCS4 CFIELD7 c(y0. ACCS5 CFIELD8 c(y0. ACCS6 DFIELD9 d(y0. ACCS7 DFIELD10d(y0. ACCS8 EFIELD11e(y0. ACCS9 EFIELD12e(y0. ACCS10 FFIELD13f(y0. ACCS11 FFIELD14f(y0. ACCS12 qMonthly values for solids accumulation rate.This table is only required if VASDFG in Table-type SLD-PARM1 is 1. (1X,12(1PE10.3))Values for start of each calendar month for solids accumulation rate (tons/ac.day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly values for solids accumulation (tonnes/ha.day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-SACCUM @`ACCSDP @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(y0. 2!ACCS1 is the solids accumulation rate in January. ACCS1 AFIELD4 a(y0. AACS2 BFIELD5 b(y0. ACCS3 BFIELD6 b(y0. ACCS4 CFIELD7 c(y0. ACCS5 CFIELD8 c(y0. ACCS6 DFIELD9 d(y0. ACCS7 DFIELD10d(y0. ACCS8 EFIELD11e(y0. ACCS9 EFIELD12e(y0. ACCS10 FFIELD13f(y0. ACCS11 FFIELD14f(y0. ACCS12 qMontxzhly values for solids accumulation rate.This table is only required if VASDFG in Table-type SLD-PARM1 is 1. (1X,12(1PE10.3))Values for start of each calendar month for solids accumulation rate(tonnes/ha. JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC { Monthly solids unit removal rate (/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-REMOV @`REMSDP @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(?0. -!REMS1 is the solids removal rate in January. REMS1 AFIELD4 a(?0. REMS2 BFIELD5 b(?0. REMS3 BFIELD6 b(?0. REMS4 CFIELD7 c(?0. REMS5 CFIELD8 c(?0. REMS6 DFIELD9 d(?0. REMS7 DFIELD10d(?0. REMS8 EFIELD11e(?0. REMS9 EFIELD12e(?0. REMS10 FFIELD13f(?0. REMS11 FFIELD14f(?0. REMS12 pMonthly values of solids unit removal rate.This table is only required if VRSDFG in Table-type SLD-PARM1 is 1. (1X,12(1PE10.3))Values for start of each calendar month for solids removal (per day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC 2 Solids storage (tons/acre) x - x SLD-STOR @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPy0. (!SLDS is the initial storage of solids.SLDS $Initial storage of solids (IMPLND).3 (1X,5(1PE10.3))Initial solids storage (tons/acre) 1 Solids storage (tonne/ha) x - x SLD-STOR @@FIELD1  y{ILS to which these data apply. OPNID `QAFIELD3 aPy0. (!SLDS is the initial storage of solids.SLDS $Initial storage of solids (IMPLND).2 (1X,5(1PE10.3))Initial solids storage (tonne/ha) : Flags for section IWTGAS x - x WTFV CSNO IWT-PARM1 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(0 !WTFVFG: value of 1 means to vary the water temperatureregression parameters (AWTF and BWTF) monthly; 0 means useannual values. WTFVFG AFIELD4 a(0 !If CSNOFG=1, the effects of snow accumulation and melt arebeing considered; if it is zero, they are not. If sectionIWATER is active the value of CSNOFG supplied here isignored because it was first supplied in the input for thatsection. CSNOFG #Flags for section IWTGAS (IMPLND). ; (1X,2I10) Flags for section IWTGAS WTFVFG CSNOFG { Second group of IWTGAS parms ELEV AWTF BWTF x - x (ft) (deg F) (deg F/F) IWT-PARM2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPz`F0. !ELEV is the elevation of the ILS above sea level (used toadjust saturation concentrations of dissolved gases insurface outflow).ELEV AFIELD4 aPB32.!AWTF is the surface water temperature, when the airteperature is 32 degrees F (0 degrees C). It is theintercept of the surface water temperature regressionequation. AWTF BFIELD5 bPn:@1. R"BWTF is the slope of the surface water temperatureregression equation. BWTF ,Second group of IWTGAS parameters (IMPLND).m (1X,3(1PE10.3)) Second group of IWTGAS parms ELEV AWTF BWTF (ft) (deg F) (deg F/F) { Second gz|roup of IWTGAS parms ELEV AWTF BWTF x - x (m) (deg C) (deg C/C) IWT-PARM2 @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aP0F0. !ELEV is the elevation of the ILS above sea level (used toadjust saturation concentrations of dissolved gases insurface outflow).ELEV AFIELD4 aPB0. !AWTF is the surface water temperature, when the airteperature is 32 degrees F (0 degrees C). It is theintercept of the surface water temperature regressionequation. AWTF BFIELD5 bPn:@1. R"BWTF is the slope of the surface water temperatureregression equation. BWTF ,Second group of IWTGAS parameters (IMPLND).m (1X,3(1PE10.3)) Second group of IWTGAS parms ELEV AWTF BWTF (m) (deg C) (deg C/C) > Sediment Surface x - x SDLFAC SLIFAC LAT-FACTOR @@FIELD1 ILSs to which these data apply.OPNID `QAFIELD2 aP?0.0! SDLFAC is the weighting factor which accounts for the influence of lateral inflow on the outflow concentration for sediment-associated constituents which do not maintain a mass balance (QUALSD) SDLFAC AFIELD3 aP?0.0! SLIFAC is the weighting factor which accounts for the influence of lateral inflow on the surface outflow concentration for constituents which do not maintain a mass balance (temp, DO, CO2)SLIFAC 7 Lateral inflow weighting factors for IWGTAS and IQUAL % (1X,2(1PE10.3)) SDLFAC SLIFAC  Value of AWTF at start of each month (deg F) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-AWTF @`AWTF @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(B32.a!AWTF1 is the interce{}pt of surface water temperature regressionequation at the start of January. AWTF1 AFIELD4 a(B32.AWTF2 BFIELD5 b(B32.AWTF3 BFIELD6 b(B32.AWTF4 CFIELD7 c(B32.AWTF5 CFIELD8 c(B32.AWTF6 DFIELD9 d(B32.AWTF7 DFIELD10d(B32.AWTF8 EFIELD11e(B32.AWTF9 EFIELD12e(B32.AWTF10 FFIELD13f(B32.AWTF11 FFIELD14f(B32.AWTF12 Monthly values of AWTF (intercept of surface water temperatureregression equation) at start of each month.This table is only required if WTFVFG in Table-type IWT-PARM1 is 1. (1X,12(1PE10.3))Value of AWTF at start of each calendar month (deg f) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value of AWTF at start of each month (deg C) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-AWTF @`AWTF @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(B0. a!AWTF1 is the intercept of surface water temperature regressionequation at the start of January. AWTF1 AFIELD4 a(B0. AWTF2 BFIELD5 b(B0. AWTF3 BFIELD6 b(B0. AWTF4 CFIELD7 c(B0. AWTF5 CFIELD8 c(B0. AWTF6 DFIELD9 d(B0. AWTF7 DFIELD10d(B0. AWTF8 EFIELD11e(B0. AWTF9 EFIELD12e(B0. AWTF10 FFIELD13f(B0. AWTF11 FFIELD14f(B0. AWTF12 Monthly values o|~f AWTF (intercept of surface water temperatureregression equation) at start of each month.This table is only required if WTFVFG in Table-type IWT-PARM1 is 1. (1X,12(1PE10.3))Value of AWTF at start of each calendar month (deg c) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value of BWTF at start of each month (deg F/F) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-BWTF @`BWTF @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(n:@1. ]!BWTF1 is the slope of surface water temperature regression equationat the start of January. BWTF1 AFIELD4 a(n:@1. BWTF2 BFIELD5 b(n:@1. BWTF3 BFIELD6 b(n:@1. BWTF4 CFIELD7 c(n:@1. BWTF5 CFIELD8 c(n:@1. BWTF6 DFIELD9 d(n:@1. BWTF7 DFIELD10d(n:@1. BWTF8 EFIELD11e(n:@1. BWTF9 EFIELD12e(n:@1. BWTF10 FFIELD13f(n:@1. BWTF11 FFIELD14f(n:@1. BWTF12 Monthly values of BWTF (slope of surface water temperatureregression equation) at start of each month.This table is only required if WTFVFG in Table-type IWT-PARM1 is 1. (1X,12(1PE10.3))Value of BWTF at start of each calendar month (deg f/f) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of BWTF at start of each month (deg C/C) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-BWTF @`BWTF @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(n:@1. ]!BWTF1 is the slope of surface water }temperature regression equationat the start of January. BWTF1 AFIELD4 a(n:@1. BWTF2 BFIELD5 b(n:@1. BWTF3 BFIELD6 b(n:@1. BWTF4 CFIELD7 c(n:@1. BWTF5 CFIELD8 c(n:@1. BWTF6 DFIELD9 d(n:@1. BWTF7 DFIELD10d(n:@1. BWTF8 EFIELD11e(n:@1. BWTF9 EFIELD12e(n:@1. BWTF10 FFIELD13f(n:@1. BWTF11 FFIELD14f(n:@1. BWTF12 Monthly values of BWTF (slope of surface water temperatureregression equation) at start of each month.This table is only required if WTFVFG in Table-type IWT-PARM1 is 1. (1X,12(1PE10.3))Value of BWTF at start of each calendar month (deg c/c) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC R SOTMP SODOX SOCO2 x - x (deg F) (mg/l) (mg C/l) IWT-INIT @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 aPBB60./!SOTMP is initial surface outflow temperature. SOTMP AFIELD4 aPA0. 7!SODOX is initial DO concentration in surface outflow. SODOX BFIELD5 bP?0. 8"SOCO2 is initial CO2 concentration in surface outflow.SOCO2 Initial conditions for section IWTGAS. The values given in thistable do not affect anything in the simulation beyond the startof the first interval of the run. Therefore, in most runs, thistable should be omitted. N (1X,3(1PE10.3)) SOTMP SODOX SOCO2 (deg F) (mg/l) (mgC/l) R SOTMP SODOX SOCO2 x - x (deg C) (mg/l) (mg C/l) IWT-INIT @@FIELD1  ILS to which these data apply. OPNID `Q~AFIELD3 aP #<B16./!SOTMP is initial surface outflow temperature. SOTMP AFIELD4 aPA0. 7!SODOX is initial DO concentration in surface outflow. SODOX BFIELD5 bP?0. 8"SOCO2 is initial CO2 concentration in surface outflow.SOCO2 Initial conditions for section IWTGAS. The values given in thistable do not affect anything in the simulation beyond the startof the first interval of the run. Therefore, in most runs, thistable should be omitted. N (1X,3(1PE10.3)) SOTMP SODOX SOCO2 (deg C) (mg/l) (mgC/l)  x - xNQUAL  NQUALS @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a( 1 H!NQUAL is the total number of quality constituents beingsimulated.NQUAL `The total number of quality constituents simulated in SectionIQUAL is indicated in this table. (1X,I10) NQUAL Atmospheric Deposition Flags QUAL1 QUAL2 QUAL3 QUAL4 QUAL5 QUAL6 QUAL7 QUAL8 QUAL9 QUAL10 x - x IQL-AD-FLAGS @@FIELD1  ILS to which these data apply. OPNID `AAFIELD3 a0 !Value of 0 indicates that atmospheric deposition flux of qualityconstituent #1 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(1) AAFIELD4 a0 !Value of 0 indicates that concentration of quality constituent #1 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(2) ABFIELD5 b0 "Value of 0 indicates that atmospheric deposition flux of qualityconstituent #2 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(3) BBFIELD6 b0 "Value of 0 indicates that concentration of quality constituent #2 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(4) BCFIELD7 c0 #Value of 0 indicates that atmospheric deposition flux of qualityconstituent #3 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(5) CCFIELD8 c0 #Value of 0 indicates that concentration of quality constituent #3 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(6) CDFIELD9 d0 $Value of 0 indicates that atmospheric deposition flux of qualityconstituent #4 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(7) DDFIELD10d0 $Value of 0 indicates that concentration of quality constituent #4 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(8) DEFIELD11e0 %Value of 0 indicates that atmospheric deposition flux of qualityconstituent #5 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(9) EEFIELD12e0 %Value of 0 indicates that concentration of quality constituent #5 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(10) EFFIELD13f0 &Value of 0 indicates that atmospheric deposition flux of qualityconstituent #6 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(11) FFFIELD14f0 &Value of 0 indicates that concentration of quality constituent #6 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(12) FGFIELD15g0 'Value of 0 indicates that atmospheric deposition flux of qualityconstituent #7 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(13) GGFIELD16g0 'Value of 0 indicates that concentration of quality constituent #7 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(14) GHFIELD17h0 (Value of 0 indicates that atmospheric deposition flux of qualityconstituent #8 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(15) HHFIELD18h0 (Value of 0 indicates that concentration of quality constituent #8 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(16) HIFIELD19i0 )Value of 0 indicates that atmospheric deposition flux of qualityconstituent #9 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(17) IIFIELD20i0 )Value of 0 indicates that concentration of quality constituent #9 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(18) IJFIELD21j0 *Value of 0 indicates that atmospheric deposition flux of qualityconstituent #10 is either absent or is supplied as a direct time seriesas IQADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(19) JJFIELD22j0 *Value of 0 indicates that concentration of quality constituent #10 inprecipitation is either absent or is supplied as a direct time seriesas IQADCN. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. IQADFG(20) J2Quality constituent atmospheric deposition flags.  (1X,10(2X,2I4)) Atmospheric Deposition Flags QUAL1 QUAL2 QUAL3 QUAL4 QUAL5 QUAL6 QUAL7 QUAL8 QUAL9 QUAL10 FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON W Identifiers and Flags x - x QUALID QTID QSD VPFW QSO VQO QUAL-PROPS @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 V!QUALID is a string of up to 10 characters which identifiesthe quality constituent. QUALID a`AFIELD4 !QTYID is a string of up to 4 characters which identifiesthe units associated with this constituent (e.g., kg,(for coliforms)).These are the units refered to as "qty" insubsequent tables (eg. Table-type QUAL-INPUT). QTYID a BFIELD5 b(0 J"If QSDFG is 1, this constituent is a QUALSD (sedimentassociated). QSDFG BFIELD6 b(0 F"If VPFWFG is 1, the washoff potency factor may varymonthly. VPFWFG CFIELD7 c(0 0#If QSOFG is non-zero, this constituent is a QUALOF (directlyassociated with overland flow). If 1, then accumulation andremoval are performed daily, and the removal rate is dependentonly on the accumulation and storage limit parameters (ACQOPand SQOLIM). If 2, accumulation and removel are performedevery interval, and the removal rate also takes into accountatmospheric deposition plus lateral inflows. If -1, then theoutflow concentration is specified in ACQOP rather than theaccumulation rate, and buildup and washoff processes are notsimulated.QSOFG CFIELD8 c(0 a#If VQOFG is 1 then rate of accumulation and the limitingstorage of QUALOF may vary monthly. VQOFG oIdentifiers and flags for a quality constituent in IQUAL.This table is repeated for each quality constituent. Q (1X,3A4,4X,A4,4I10) CON NAME QTYID QSDFP VPFWFG QSOFP VQOFG  Storage on surface and nonseasonal parameters SQO POTFW ACQOP SQOLIM WSQOP qty/ac qty/ton qty/ qty/ac in/hr x - x ac.day QUAL-INPUT @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a@y0. B!SQO is the initial storage of QUALOF on the surface of theILS. SQOAFIELD4 a@y0. !POTFW is the washoff potency factor for a QUALSD. A potencyfactor is the ratio of constituent yield to sedimentoutflow. POTFW BFIELD5 b@y0. "ACQOP is the rate of accumulation of QUALOF if QSOFG is positive.If QSOFG is negative, then ACQOP is the concentration of QUALOFin the surface outflow in mg/l. ACQOP BFIELD6 b@75y 0.000001 ?"SQOLIM is the maximum storage of QUALOF if QSOFG is positive. SQOLIM CFIELD7 c@ #<y1.64 `#WSQOP is the rate of surface runoff which will remove 90percent of stored QUALOF per hour.WSQOP vStorage on surface and nonseasonal parameters for IQUAL (IMPLND)This table is repeated for each quality constituent. (1X,5(1PE10.3)) Storage on surface and nonseasonal parameters SQO POTFW ACQOP SQOLIM WSQOP (qty/ac) (qty/ton) (qty/ (qty/ac) (in/hr) ac.day)  Storage on surface and nonseasonal parameters SQO POTFW ACQOP SQOLIM WSQOP qty/ha qty/tonn qty/ qty/ha mm/hr x - x ha.day QUAL-INPUT @@FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a@y0. B!SQO is the initial storage of QUALOF on the surface of theILS. SQOAFIELD4 a@y0. !POTFW is the washoff potency factor for a QUALSD. A potencyfactor is the ratio of constituent yield to sedimentoutflow. POTFW BFIELD5 b@y0. ."ACQOP is the rate of accumulation of QUALOF. ACQOP BFIELD6 b@76y 0.000002 *"SQOLIM is the maximum storage of QUALOF. SQOLIM CFIELD7 c@>y41.7 `#WSQOP is the rate of surface runoff which will remove 90percent of stored QUALOF per hour.WSQOP vStorage on surface and nonseasonal parameters for IQUAL (IMPLND)This table is repeated for each quality constituent. (1X,5(1PE10.3)) Storage on surface and nonseasonal parameters SQO POTFW ACQOP SQOLIM WSQOP (qty/ha)(qty/tonn) (qty/ (qty/ha) (mm/hr) ha.day)  Value at start of each month for washoff potency factor (qty/ton) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-POTFW @`POTFW @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(y0. =!POTF1 is the washoff potency factor at the start of January. POTF1 AFIELD4 a(y0. POTF2 BFIELD5 b(y0. POTF3 BFIELD6 b(y0. POTF4 CFIELD7 c(y0. POTF5 CFIELD8 c(y0. POTF6 DFIELD9 d(y0. POTF7 DFIELD10d(y0. POTF8 EFIELD11e(y0. POTF9 EFIELD12e(y0. POTF10 FFIELD13f(y0. POTF11 FFIELD14f(y0. POTF12 Monthly values of washoff potency factor at start of each month.This table is only required if VPFWFG in Table-type QUAL-PROPS is 1.and is repeated for each quality constituent. (1X,12(1PE10.3))values for POTFW at start of each month (qty/ton) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value at start of each month for washoff potency factor (qty/tonn) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-POTFW @`POTFW @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(y0. =!POTF1 is the washoff potency factor at the start of January. POTF1 AFIELD4 a(y0. POTF2 BFIELD5 b(y0. POTF3 BFIELD6 b(y0. POTF4 CFIELD7 c(y0. POTF5 CFIELD8 c(y0. POTF6 DFIELD9 d(y0. POTF7 DFIELD10d(y0. POTF8 EFIELD11e(y0. POTF9 EFIELD12e(y0. POTF10 FFIELD13f(y0. POTF11 FFIELD14f(y0. POTF12 Monthly values of washoff potency factor at start of each month.This table is only required if VPFWFG in Table-type QUAL-PROPS is 1.and is repeated for each quality constituent. (1X,12(1PE10.3))values for POTFW at start of each month (qty/tonne) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of each month for accum rate of QUALOF (qty/ac.day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ACCUM @`ACQOP @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(y0. A!ACQO1 is the accumulation rate of QUALOF at the start of January ACQO1 AFIELD4 a(y0. ACQO2 BFIELD5 b(y0. ACQO3 BFIELD6 b(y0. ACQO4 CFIELD7 c(y0. ACQO5 CFIELD8 c(y0. ACQO6 DFIELD9 d(y0. ACQO7 DFIELD10d(y0. ACQO8 EFIELD11e(y0. ACQO9 EFIELD12e(y0. ACQO10 FFIELD13f(y0. ACQO11 FFIELD14f(y0. ACQO12 Monthly values of accumulation rate of QUALOF at start of each month.This table is only required if VQOFG in Table-type QUAL-PROPS is 1.and is repeated for each quality constituent. (1X,12(1PE10.3))values for ACCUM at start of each month (qty/ac.d) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of each month for accum rate of QUALOF (qty/ha.day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ACCUM @`ACQOP @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(y0. A!ACQO1 is the accumulation rate of QUALOF at the start of January ACQO1 AFIELD4 a(y0. ACQO2 BFIELD5 b(y0. ACQO3 BFIELD6 b(y0. ACQO4 CFIELD7 c(y0. ACQO5 CFIELD8 c(y0. ACQO6 DFIELD9 d(y0. ACQO7 DFIELD10d(y0. ACQO8 EFIELD11e(y0. ACQO9 EFIELD12e(y0. ACQO10 FFIELD13f(y0. ACQO11 FFIELD14f(y0. ACQO12 Monthly values of accumulation rate of QUALOF at start of each month.This table is only required if VQOFG in Table-type QUAL-PROPS is 1.and is repeated for each quality constituent. (1X,12(1PE10.3))values for ACCUM at start of each month (qty/ha.d) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of month for limiting storage of QUALOF (qty/ac) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-SQOLIM @`SQOLIM @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(75y 0.000001 A!SQOL1 is the limiting storage of QUALOF at the start of January. SQOL1 AFIELD4 a(75y 0.000001 SQOL2 BFIELD5 b(75y 0.000001 SQOL3 BFIELD6 b(75y 0.000001 SQOL4 CFIELD7 c(75y 0.000001 SQOL5 CFIELD8 c(75y 0.000001 SQOL6 DFIELD9 d(75y 0.000001 SQOL7 DFIELD10d(75y 0.000001 SQOL8 EFIELD11e(75y 0.000001 SQOL9 EFIELD12e(75y 0.000001 SQOL10 FFIELD13f(75y 0.000001 SQOL11 FFIELD14f(75y 0.000001 SQOL12 Monthly values limiting storage of QUALOF at start of each month.This table is only required if VQOFG in Table-type QUAL-PROPS is 1.and is repeated for each quality constituent. (1X,12(1PE10.3))values for SQOLIM at start of each month (qty/ac) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value at start of month for limiting storage of QUALOF (qty/ha) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-SQOLIM @`SQOLIM @FIELD1  ILS to which these data apply. OPNID `QAFIELD3 a(76y 0.000002 A!SQOL1 is the limiting storage of QUALOF at the start of January. SQOL1 AFIELD4 a(76y 0.000002 SQOL2 BFIELD5 b(76y 0.000002 SQOL3 BFIELD6 b(76y 0.000002 SQOL4 CFIELD7 c(76y 0.000002 SQOL5 CFIELD8 c(76y 0.000002 SQOL6 DFIELD9 d(76y 0.000002 SQOL7 DFIELD10d(76y 0.000002 SQOL8 EFIELD11e(76y 0.000002 SQOL9 EFIELD12e(76y 0.000002 SQOL10 FFIELD13f(76y 0.000002 SQOL11 FFIELD14f(76y 0.000002 SQOL12 Monthly values limiting storage of QUALOF at start of each month.This table is only required if VQOFG in Table-type QUAL-PROPS is 1.and is repeated for each quality constituent. (1X,12(1PE10.3))values for SQOLIM at start of each month (qty/ha) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC} $!20000607144843 20000607144843 MUTSINTS OUTPUT 10 POINTMEAN POINT 20 1 -2 1 1 0 0 0 74 ENG any 0 1 0 1 Point-valued output time series MET any 0 1 0 1 MEAN 20 1 -3 1 2 0 0 0 94 ENG any 0 1 0 1 Mean-valued output time series MET any 0 1 0 1 + $!20000309112927 20000309112927 HDSSX   1 1 1 5 This version of HSPF does not support DSS file functionality. However, a reference to DSS data set &I is made in the EXT SOURCES or EXT TARGETS block. This is a fatal error! The user must remove ALL DSS references. C+ $!20000309112927 20000309112927 HDATUT c7  20 1 1 5 The following values were specified for a starting or special action date/time. They are invalid. (Were they placed in the wrong fields?) Year Mon Day Hr Min &I &I &I &I &I@ HSPF has one convention for specifying a starting date/time and another for an ending date/time. Date/times read by the system are checked for validity. See the discussion of this subject in the documentation of the user's control input.  20 1 1 5 The following values were specified for an ending date/time but are invalid. (Were they placed in the wrong fields?) Year Mon Day Hr Min &I &I &I &I &I  1 1 1 5 Subroutine TIMHTW has indicated a time value less than zero. Run must terminate. Year Mon Day Hr Min &I &I &I &I &I CCCCCCCCCCCCCCC  20 11 0 5 Operation : &CCCCC Number : &I Table : &CCCCCCCCCCC Subscrpt: &I Parameter : &I Value : &CCCC Unable to convert value entered into an integer.  20 11 0 5 Operation : &CCCCC Number : &I Table : &CCCCCCCCCCC Subscrpt: &I Parameter : &I Value : &CCCCCCCCC Unable to convert value entered into a real number. 5 $!20040825113027 20040825113027 HSPFITAB |4L]iv} B  20 1 1 5 Operation : &CCCCC Number : &I Table : &CCCCCCCCCCC Subscrpt: &I Parameter : &I Value : &I Allowed Min : &I Max : &I Set to Default : &I  20 1 1 5 Operation : &CCCCC Number : &I Table : &CCCCCCCCCCC Subscrpt: &I Parameter : &I No value was found in UCI and no default is available.  20 1 1 5 Operation : &CCCCC Number : &I Table : &CCCCCCCCCCC Subscrpt: &I Parameter : &I Value : &R Allowed Min : &R Max : &R Set to Default : &R W  INFORMATION NORMALLY CONTAINED IN THIS TABLE HAS NOT BEEN SUPPLIED FOR THIS OPERATION ;  OPERATING IN RESUME MODE, SO EXISTING VALUES WILL BE USED (  WILL USE DEFAULT VALUES WHERE POSSIBLE+  FINISHED PROCESSING ENTRIES IN THIS TABLE   PROCESSING: &  20 1 1 5 The MONTH-DATA table &I was referred to in an operation block of the user's control input but not found in the MONTH-DATA block. Is the number in error, or is it in the wrong columns, in either place? |  20 1 1 5 MONTH-DATA tables cannot contain negative values. However, intable &I value number &I is &R  20 1 1 5 Invalid numeric input in MONTH-DATA table &I . The input string was: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC $!20000309112928 20000309112928 HIMPWAT   10 1 1 5 Impervious land segment: &I Error - Iteration in subroutine IROUTE did not converge in 100+ cycles. SURSE SURO SURSNW FSURO DFSURO DSURO &R &R &R &R &R &R C $!20000309112928 20000309112928 HIOUCI e!      !\! END^  1 1 1 5 Keyword &CCCCCCCCCCC was found before keyword &CCCCCCCCCCC was ENDed. m  1 1 1 5 Keyword &CCCCCCCCCCC has appeared too many times. It may only appear &IIII times. S  1 1 1 5 Keyword &CCCCCCCCCCC was ENDed without ever being started. f  1 1 1 5 Keyword &CCCCCCCCCCC was ENDed without keyword &CCCCCCCCCCC ever being ended. V  1 1 1 5 End of input was found before keyword &CCCCCCCCCCC was ENDed. (  5 1 1 5 Characters were lost at the end of line &I . A line must be only 80 characters long. (In the SPEC-ACTIONS block, this limit applies after any indentation is accounted for.) The lost characters were: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC   USERS CONTROL INPUT IS: 6 $!20000309112928 20000309112928 HIOSTA D&"""#H#p####$G$]$$$$%/%]%%%%&  10 1 1 5 In this configuration of HSPF, input of the STASAV file requires specifications of the variable name and any necessary subscripts. A memory location was input.  10 1 1 5 In this configuration of HSPF, input of the STASAV file requires specifications of a memory location. A variable name was input.  10 1 1 5 The variable name '&CCCCC' in the STASAV file is invalid. It may be mispelled, placed in the wrong field, or it may not be currently available in the "Special Actions Variable Name" library.  10 1 1 5 The number of nonzero subscripts specified for the STASAV file variable '&CCCCC' is not correct. The correct number of dimensions is &I .  10 1 1 5 At least one of the specified subscripts for the STASAV file variable '&CCCCC' exceeds the corresponding dimension of the array.  10 1 1 5 User specified a bad repeat code in the STASAV file. The supplied value of '&C' was interpreted as: &I Valid values are 'MI','HR','DY','MO','YR' or ' ' (defaults to minutes).g  10 1 1 5 Problem reading special action numerical address from string: &CCCCCCCCCCCCCC  10 1 1 5 Unrecognized category tag &C was supplied by user the STASAV file. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  10 1 1 5 Category tag &C was supplied by user in the STASAV file, but no category tags were defined in the CATEGORY block.  10 1 1 5 Problem reading general information from the STASAV header line. The line begins with the string: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCC P  10 1 1 5 Problem reading column dates from the STASAV header line.  10 1 1 5 Problem reading variable status line from the STASAV file. The line begins with the string: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCC }  10 1 1 5 The workspace variable &CCCCC at address &I was not found. It was referred to in the STASAV file.  10 1 1 5 The user-defined variable name (UVNAME) &CCCCC, referred to in the STASAV file, was not defined as a workspace variable in the User's Control Input (UCI) file.  10 1 1 5 The GLOBAL variable name &CCCCC, referred to in the STASAV file, was not defined in the User's Control Input (UCI) file.  10 1 1 5 The GLOBAL variable name &CCCCC was referred to in the STASAV file. However, no workspace variables were defined in the User's Control Input (UCI) file.  10 1 1 5 Operation type '&CCCCC' does not allow STASAV file updates. Valid operation types are 'PERLND','IMPLND','RCHRES','COPY ','PLTGEN', and 'GENER '.  10 1 1 5 An invalid variable type code was specified in the STASAV file for the variable &CCCCC. The code found was &I . Valid codes are: 2: integer 3: real 4: double precision The default is real.  10 1 1 5 Problem reading integer value for variable &CCCCC from the STASAV file. The input string was: '&CCCCCCCCC'   10 1 1 5 Problem reading real value for variable &CCCCC from the STASAV file. The input string was: '&CCCCCCCCC' }  10 11 0 5 The STASAV file contains more than the &I variable lines allowed. The extra lines will be ignored.  10 1 1 5 The STASAV file variable &CCCCC was declared in the STASAV file to be of the type &I . However, this variable was found to be of type &I . Valid codes are: 2: integer 3: real 4: double precisionT,@ $!20011211123144 20011211123144 HIMP )(())D  50 1 1 5IMPLND operation &I has no active sections.  50 1 1 5The printout level (PFLAG) for one or more sections of IMPLNDoperation &I is 2; that is, some printout should occur morefrequently than daily. In this case, the value of pivl (specifiedby the user or by default) must imply a minimum printout intervalof one day or an integer fraction thereof. However, this conditionhas been violated since the value of pdelt is &I minutes.The remedy is to adjust pivl so that pdelt (delt*pivl) meets theabove requirement.  50 1 1 5The binary out level (BFLAG) for one or more sections of IMPLNDoperation &I is 2; that is, some output should occur morefrequently than daily. In this case, the value of bivl (specifiedby the user or by default) must imply a minimum output intervalof one day or an integer fraction thereof. However, this conditionhas been violated since the value of bdelt is &I minutes.The remedy is to adjust bivl so that bdelt (delt*bivl) meets theabove requirement. S  50 1 1 5The binary output interval (BIVL) for one or more IMPLND operationsdoes not equal the print output interval (PIVL), and both thebinary and print output options are on. When using both binaryand print output options, BIVL must equal PIVL. The remedy is tochange one or the other. BIVL = &I , and PIVL = &I . 76 $!20000309112928 20000309112928 HPERNIT P/*+,e-.. /  10 11 0 5&D Pervious land segment: &I Layer: &CCC A negative value is projected for nitrate. To avoid the problem, fluxes will be arbitrarily reduced. Relevant data are: FRAC NO3 TNO3 NITRF IMMNI DENI UTNI &R &R &R &R &R &R &R UTNIA &R Where: FRAC is the factor by which fluxes will be reduced to avoid the negative concentration NO3 is the mass of nitrate before reaction (LB/ACRE or KG/HA) TNO3 is the projected (negative) mass of nitrate after reaction (LB/ACRE or KG/HA) NITRF is the projected nitrification (LB/ACRE or KG/HA) per interval IMMNI is the projected immobilization of nitrate (LB/ACRE OR KG/HA) per interval DENI is the projected denitrification (LB/ACRE or KG/HA) per interval UTNI is the projected below-ground plant uptake of nitrate (LB/ACRE or KG/HA) per interval UTNIA is the projected above-ground plant uptake of nitrate (LB/ACRE or KG/HA) per intervalb  10 11 0 5&D Pervious land segment: &I Layer: &CCC A negative value is projected for particulate labile organic nitrogen. To avoid the problem, fluxes will be arbitrarily reduced. Relevant data are: FRAC ORGN TORGN AMMIF IMMAM IMMNI &R &R &R &R &R &R PRETL RFON &R &R Where: FRAC is the factor by which fluxes will be reduced to avoid the negative concentration ORGN is the mass of organic N before reaction (LB/ACRE or KG/HA) TORGN is the projected (negative) mass of organic N after reaction (LB/ACRE or KG/HA) AMMIF is the projected ammonification (LB/ACRE or KG/HA) per interval IMMAM is the projected immobilization of ammonium (LB/ACRE or KG/HA) per interval IMMNI is the projected immobilization of nitrate (LB/ACRE OR KG/HA) per interval PRETL is the projected return of plant nitrogen (LB/ACRE OR KG/HA) to labile organic nitrogen per interval RFON is the projected conversion to refractory organic nitrogen (LB/ACRE OR KG/HA) per interval   10 11 0 5&D Pervious land segment: &I Layer: &CCC A negative value is projected for adsorbed ammonium. To avoid the problem, fluxes will be arbitrarily reduced. Relevant data are: FRAC AMAD TAMAD ADSAM DESAM &R &R &R &R &R Where: FRAC is the factor by which fluxes will be reduced to avoid the negative concentration AMAD is the mass of adsorbed ammonium before reaction (LB/ACRE or KG/HA) TAMAD is the projected (negative) mass of ads. amm. after reaction (LB/ACRE or KG/HA) ADSAM is the projected adsorption flux (LB/ACRE or KG/HA) per interval DESAM is the projected desorption flux per interval J  10 11 0 5&D Pervious land segment: &I Layer: &CCC A negative value is projected for solution ammonium. To avoid the problem, fluxes will be arbitrarily reduced. Relevant data are: FRAC AMSU TAMSU ADSAM DESAM AMMIF IMMAM &R &R &R &R &R &R &R NITRF UTAM UTAMA AMVO &R &R &R &R Where: FRAC is the factor by which fluxes will be reduced to avoid the negative concentration AMSU is the mass of solution amm. before reaction (LB/ACRE or KG/HA) TAMSU is the projected (negative) mass of solution amm. after reaction (LB/ACRE or KG/HA) ADSAM is the projected adsorption flux (LB/ACRE or KG/HA) per interval DESAM is the projected desorption flux per interval AMMIF is the projected ammonification (LB/ACRE or KG/HA) per interval IMMAM is the projected immobilization of ammonium (LB/ACRE or KG/HA) per interval NITRF is the projected nitrification (LB/ACRE or KG/HA) per interval UTAM is the projected below-ground plant uptake of ammonium (LB/ACRE or KG/HA) per interval UTAMA is the projected above-ground plant uptake of ammonium (LB/ACRE or KG/HA) per interval AMVO is the projected ammonia volatilization (LB/ACRE or KG/HA) per interval  50 2 1 5 Pervious land segment: &I The sum of the twelve monthly fractions in Table-type MON-NUPT-FR1 did not equal one. The values provided summed to &R  50 2 1 5 Pervious land segment: &I In month &I , the sum of the four fractions for the four soil layers in Table-type MON-NUPT-FR2 did not equal one. The values provided summed to &R  50 2 1 5 Pervious land segment: &I The sum of the plant uptake fractions NO3UTF and NH4UTF in Table-type NIT-FSTGEN did not equal one. The values provided summed to &R/5 $!20040809162913 20040809162913 HPERPES 20M12  20 11 0 5&D Pervious land segment: &I A negative value is projected for adsorbed pesticide. To avoid the problem, fluxes will arbitrarily be reduced. Relevant data are: PESTICIDE FRAC PSAD TPSAD ADSPS DESPS LAYER &CCCCCCCCCCCCCCCCCCC&R &R &R &R &R &CCC Where: FRAC is the factor by which fluxes will be reduced, to avoid the negative concentration. PSAD is the mass of adsorbed pesticide before reaction (LB/ACRE or KG/HA) TPSAD is the projected (negative) mass of adsorbed pesticide after reaction (LB/ACRE or KG/HA) ADSPS is the projected adsorption (LB/ACRE or KG/HA) per interval DESPS is the projected desorption (LB/ACRE or KG/HA) per interval   20 11 0 5&D Pervious land segment: &I A negative value is projected for pesticide in solution. To avoid the problem, fluxes will arbitrarily be reduced. Relevant data are: PESTICIDE FRAC PSSU TPSSU ADSPS DESPS LAYER &CCCCCCCCCCCCCCCCCCC&R &R &R &R &R &CCC Where: FRAC is the factor by which fluxes will be reduced, to avoid the negative concentration. PSSU is the mass of pesticide in solution before reaction (LB/ACRE or KG/HA) TPSSU is the projected (negative) mass of pesticide in solution after reaction (LB/ACRE or KG/HA) ADSPS is the projected adsorption (LB/ACRE or KG/HA) per interval DESPS is the projected desorption (LB/ACRE or KG/HA) per interval   20 11 0 5&D Pervious land segment: &I An invalid temperature was computed for one of the soil layers. Either the parameters or input air temperature are invalid. To avoid a problem, the temperature will be adjusted. Relevant data are: LAYER TEMP ADJTMP &CCCCC &R &R Where: LAYER is the layer-specific variable; SLTMP = surface, ULTMP = upper, and LGTMP = lower/groundwater. TEMP is the computed temperature (deg C) ADJTMP is the adjusted temperature (deg C) .67 $!20000309112928 20000309112928 HPERPHO i74K56747  20 11 0 5&D Pervious land segment: &I A negative value is projected for organic phosphorus. To avoid the problem, fluxes will arbitrarily be reduced. Relevant data are: FRAC ORGP TORGP MINZOP IMMP4 LAYER &R &R &R &R &R &CCC Where: FRAC is the factor by which fluxes will be reduced, to avoid the negative concentration. ORGP is the mass of organic P before reaction (LB/ACRE or KG/HA) TORGP is the projected (negative) mass of organic P after reaction (LB/ACRE or KG/HA) MINZOP is the projected mineralization of organic P (LB/ACRE or KG/HA) per interval IMMP4 is the projected immobilization of phosphate (LB/ACRE or KG/HA) per interval   20 11 0 5&D Pervious land segment: &I A negative value is projected for adsorbed phosphorus. To avoid the problem, fluxes will arbitrarily be reduced. Relevant data are: FRAC P4AD TP4AD ADSP4 DESP4 LAYER &R &R &R &R &R &CCC Where: FRAC is the factor by which fluxes will be reduced, to avoid the negative concentration. P4AD is the mass of adsorbed P before reaction (LB/ACRE or KG/HA) TP4AD is the projected (negative) mass of adsorbed P after reaction (LB/ACRE or KG/HA) ADSP4 is the projected adsorption of P (LB/ACRE or KG/HA) per interval DESP4 is the projected desorption of P (LB/ACRE or KG/HA) per interval  20 11 0 5 8&D Pervious land segment: &I A negative value is projected for phosphorus in solution. To avoid the problem, fluxes will be arbitrarily reduced. Relevant data are: FRAC P4SU TP4SU ADSP4 DESP4 MINZOP IMMP4 UTP4 LAYER &R &R &R &R &R &R &R &R &CCC Where: FRAC is the factor by which fluxes will be reduced, to avoid the negative concentration. P4SU is the mass of solution P before reaction (LB/ACRE or KG/HA) TP4SU is the projected (negative) mass of solution P after reaction (LB/ACRE or KG/HA) ADSP4 is the projected adsorption of P (LB/ACRE or KG/HA) per interval DESP4 is the projected desorption of P (LB/ACRE or KG/HA) per interval MINZOP is the projected mineralization of organic P (LB/ACRE or KG/HA) per interval IMMP4 is the projected immobilization of phosphate (LB/ACRE or KG/HA) per interval UTP4 is the projected uptake by plants (LB/ACRE or KG/HA) per interval  20 1 1 5 Pervious land segment: &I The sum of the twelve monthly fractions in Table-type MON-PUPT-FR1 did not equal one. The values provided summed to &R  20 1 1 5 Pervious land segment: &I In month &I , the sum of the four fractions for the four soil layers in Table-type MON-PUPT-FR2 did not equal one. The values provided summed to &R 93 $!20030814161427 20030814161427 HPERQUA 9889>9{9  50 1 1 5 There are too many sediment-associated quality constituents specified in the input to module section pqual or iqual (the limit is &I). The problem arose when processing the constituent '&CCCCCCCCCCC'.  50 1 1 5 There are too many overland-flow-associated quality constituents specified in the input to module section pqual or iqual (the limit is &I). The problem arose when processing the constituent '&CCCCCCCCCCC'.  50 1 1 5 There are too many interflow-associated quality constituents specified in the input to module section pqual or iqual (the limit is &I). The problem arose when processing the constituent '&CCCCCCCCCCC'.  50 1 1 5 There are too many groundwater-flow-associated quality constituents specified in the input to module section pqual or iqual (the limit is &I). The problem arose when processing the constituent '&CCCCCCCCCCC'.   50 1 1 5A constituent must be associated with overland flow in order to receiveatmospheric deposition inputs. However, atmospheric deposition was specifiedin table type PQL-AD-FLAGS for constituent '&CCCCCCCCCCC', which is notoverland-flow-associated. _7. $!20000309112928 20000309112928 HPERSNO M;::";  20 1 1 5&D Pervious land segment: &I The ice content of the pack exceeds the total frozen contents (ice+snow) of the pack. Relevant data are: PACKF PACKI &R &R   20 1 1 5&D Pervious land segment: &I Error in table look-up procedure in function vapor has occurred. Index for array SVP is out of bounds. Relevant data are: INDEX TMP &R &R The minimum allowable value of index is 1, corresponding to a temp of -95DEG F. The maximum allowable value of index is 40, corresponding to a temp of 100 DEGF.  50 1 1 5 The snow section of module PERLND cannot function properly if ice formation is being considered (ICEFG=1) and delt is greater than 6 hours.5y/ $!20040805162441 20040805162441 HPERWAT EC<<h==>@?F@CA{AAB3BTBBBBC  20 1 1 5&D Pervious land segment: &I Error in table look-up procedure used to compute inflow to the upper zone (subroutine uzinf). The non-analytic function linking UZRA to INTGRL is stored in arrays with dimension 10. Intermediate values are found by interpolation. In trying to interpolate, HSPF has attempted to use a value beyond those tabulated. UZR1 UZR2 UZRAA &R &R &R   20 1 1 5&D Pervious land segment: &I Error in table look-up procedure used to compute inflow to the upper zone (subroutine uzinf). The non-analytic function linking UZRA to INTGRL is stored in arrays with dimension 10. Intermediate values are found by interpolation. In trying to interpolate, HSPF has attempted to use a value beyond those tabulated. INTG1 INTG2 INTGB &R &R &R  10 1 1 5 Pervious land segment: &I Error - Iteration in subroutine PROUTE did not converge in 100+ cycles. SURSE SURO SURSNW FSURO DFSURO DSURO &R &R &R &R &R &R   10 1 1 5 Pervious land segment: &I Initial groundwater elevation GWEL is computed to be above the surface elevation SELV (MELEV expressed in inches). To fix the problem, reduce the initial value of AGWS in Table PWAT-STATE1 to its maximum: AGWSMX= ULGWS+ (UELFAC*UZSN- UZS)+ (IFWSC- IFWS)- BGWS where: AGWSMX= maximum allowed active groundwater storage in inches. ULGWS= groundwater storage equivalent to UELV in inches. UELFAC= multiplier for UZSN to give upper zone capacity. UZSN= upper zone nominal storage in inches. UZS= upper zone storage. IFWSC= interflow storage capacity in inches. IFWS= interflow storage. BGWS= groundwater storage equivalent to BELV in inches. GWEL SELV MELEV AGWS AGWSMX ULGWS &R &R &R &R &R &R UELFAC UZSN UZS IFWSC IFWS BGWS &R &R &R &R &R &R f  10 1 1 5 Pervious land segment: &I Lower influence elevation LELV is computed to be below the base elevation BELV. LELV is computed in inches as: LELV= SELV- LELFAC*LZSN/PCW where: SELV= surface elevation (MELEV) in inches. LELFAC= multiplier for LZSN to give lower zone capacity. LZSN= lower zone nominal storage in inches. PCW= soil porosity for cohesion water. This value must be greater than the input value for BELV (converted to inches). BELV LELV SELV LELFAC LZSN PCW &R &R &R &R &R &R   20 1 1 5 Pervious land segment: &I Upper influence elevation UELV is computed to be below the lower influence elevation LELV for month number &I . UELV is computed in inches as: UELV= SELV- (UELFAC*UZSN+ IFWSC)/UPGW where: SELV= surface elevation (MELEV) in inches. UELFAC= multiplier for UZSN to give upper zone capacity. UZSN= upper zone nominal storage in inches IFWSC= interflow storage capacity in inches. UPGW= soil porosity for gravity water in the upper zones. This value must be greater than LELV, which is computed as: LELV= SELV- LELFAC*LZSN/PCW where: SELV= surface elevation (MELEV) in inches. LELFAC= multiplier for LZSN to give lower zone capacity. LZSN= lower zone nominal storage in inches PCW= soil porosity for cohesion water. UELV SELV UELFAC UZSN IFWSC &R &R &R &R &R UPGW LELV LELFAC LZSN PCW &R &R &R &R &R  20 1 1 5 Pervious land segment: &I Upper influence elevation UELV is computed to be below the lower influence elevation LELV. UELV is computed in inches as: UELV= SELV- (UELFAC*UZSN+ IFWSC)/UPGW where: SELV= surface elevation (MELEV) in inches. UELFAC= multiplier for UZSN to give upper zone capacity. UZSN= upper zone nominal storage in inches IFWSC= interflow storage capacity in inches. UPGW= soil porosity for gravity water in the upper zones. This value must be greater than LELV, which is computed as: LELV= SELV- LELFAC*LZSN/PCW where: SELV= surface elevation (MELEV) in inches. LELFAC= multiplier for LZSN to give lower zone capacity. LZSN= lower zone nominal storage in inches PCW= soil porosity for cohesion water. UELV SELV UELFAC UZSN IFWSC &R &R &R &R &R UPGW LELV LELFAC LZSN PCW &R &R &R &R &R  20 1 1 5 The FTABLE &I was referred to in the PERLND block of the user's control input but not found in the FTABLEs block. Is the number in error, or is it in the wrong columns, in either place? *  20 1 1 5 The layout of an FTABLE for PWATER must satisfy all of the following conditions: 1. NSROWS >=1 2. NSCOLS= 2 3. (NSROWS*NSCOLS)<=100 One or more of these conditions is not true for the following FTABLE: STABNO NSROWS NSCOLS &I &I &I  20 1 1 5 If the following FTABLE were to contain the stated no. of rows, it would continue beyond the record where its delimiter (END) was found. STABNO NSROWS KEYND &I &I &I  20 1 1 5 The value in all fields of the first row of an FTABLE for PWATER must be zero. This is not the case for the following FTABLE: FTABNO &I |  20 1 1 5 There are 1 or more negative values in the following FTABLE: STABNO ROW NO. &I &I  20 1 1 5 The depth field of an FTABLE for PWATER may not contain values which decrease as the row no. increases. However, this condition is violated in row &I of FTABLE &I .  20 1 1 5 The outflow fraction field of an FTABLE for PWATER may not contain values greater than unity. However, this condition is violated in row &I of FTABLE &I .  20 1 1 5 The irrigation application fractions IRRTGT must sum to one. The supplied values were: INTERCEP SURFACE UPPER LOWER ACTIVE GW TOTAL &R &R &R &R &R &R r  1 1 1 5 The infiltration redistribution flag IFRDFG must be 0 or 3 - 7. The supplied value was: &I  20 1 1 5&D Pervious land segment: &I Program bug - negative UZS or IFWS in ADJGWE. ContactAQUA TERRA Consultants at www.aquaterra.com UZS IFWS &R &R@U, $!20011211123135 20011211123135 HPER EDDEEE  50 1 1 5 PERLND operation &I has no active sections.   50 1 1 5 The printout level (PFLAG) for one or more sections of PERLND operation &I is 2; that is, some printout should occur more frequently than daily. In this case, the value of pivl (specified by the user or by default) must imply a minimum printout interval of one day or an integer fraction thereof. However, this condition has been violated since the value of pdelt is &I minutes. The remedy is to adjust pivl so that pdelt (delt*pivl) meets the above requirement.  50 1 1 5 The binary out level (BFLAG) for one or more sections of PERLND operation &I is 2; that is, some output should occur more frequently than daily. In this case, the value of bivl (specified by the user or by default) must imply a minimum output interval of one day or an integer fraction thereof. However, this condition has been violated since the value of bdelt is &I minutes. The remedy is to adjust bivl so that bdelt (delt*bivl) meets the above requirement. T  50 1 1 5The binary output interval (BIVL) for one or more PERLND operationsdoes not equal the print output interval (PIVL), and both thebinary and print output options are on. When using both binaryand print output options, BIVL must equal PIVL. The remedy is tochange one or the other. BIVL = &I , and PIVL = &I .LINK block, but no category tags were defined in the CATEGORY block.  20 1 1 5 An error occurred reading the following line in the EXT SOURCES block: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC  20 1 1 5 An error occurred reading the following line in the NETWORK block: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC  20 1 1 5 An error occurred reading the following line in the EXT TARGETS block: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC  20 1 1 5 An error occurred reading the following line in the SCHEMATIC block: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC  20 1 1 5 An error occurred reading the following line in MASS-LINK Table number &I : &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC  20 11 0 5 MASS-LINK Table number &I contains an implicit instruction to pass timeseries from one operation type to another operation type. Using implicit instructions in this way can result in misleading results. $!20050602162854 20050602162854 HSPFEC  where must be a valid table id.  20 1 1 5 The delimiter '&CCCCCCCCCCC, &I ' has been found but was not expected since there is no previous month-data table heading.  20 1 1 5 The delimiter '&CCCCCCCCCCC, &  20 1 1 5 A mass link table heading has been found but a delimiter was expected: Heading Found Delimiter Expected For &CCCCCCCCCCC, &I &CCCCCCCCCCC, &I m  20 1 1 5 The mass link table id '&CCCCCCCCCCC, &I ' has been found, but has occurred before. @ Subroutine MSLKBK expects each mass link table id (and its corresponding delimiter) to occur only once in the range of text it is searching.  20 1 1 5 There are more mass link tables than can fit into the mass link table index. Thus, this mass link table cannot be entered into the index.  20 1 1 5 The delimiter '&CCCCCCCCCCC, &I ' has been found but is not valid. (Has it been misspelled or placed in the wrong columns?) U@ A delimiter has the form END
where
must be a valid table id.  20 1 1 5 The delimiter '&CCCCCCCCCCC, &I ' has been found but was not expected since there is no previous mass link table heading.  20 1 1 5 The delimiter '&CCCCCCCCCCC, &I ' was found but does not match the currently open mass link table id, '&CCCCCCCCCCC, &I '. (Is it misspelled or placed in the wrong columns?)  20 1 1 5 The end of the block of text was reached before a delimiter for the last mass link table, '&CCCCCCCCCCC, &I ', was found. Was the delimiter misspelled or placed in the wrong columns? i@ Subroutine MSLKBK does not expect the block of text which it is searching to end with a partial table.  ==================================================================================================================================== PROCESSING MASS LINK BLOCK  FINISHED PROCESSING MASS LINK BLOCK ==================================================================================================================================== \  20 1 1 5 Category ID &I is out of range. It must be betwe0 1 1 5 Exgrp was explicitly or implicitly specified before the end of the previous ingroup, ingroup no. &I , was found.  20 1 1 5 The run span (duration) is not a multiple of the exgroup time interval. Run Exgroup Span Interval (Min) (Min) &I &I |  20 1 1 5 END INGRP found, but since no corresponding valid ingrp heading preceded it, instruction is ignored.E  20 1 1 5 END EXGRP found before end of current ingroup.   GENERATED END EXGROUP   GENERATED EXGROUP  FTABLE  20 1 1 5 A ftable id has been found but a delimiter was expected: Heading Found Delimiter Expected For &CCCCC , &I &CCCCC , &I `  20 1 1 5 The ftable id '&CCCCC , &I ' has been found, but has occurred before.@ Subroutine TABBLK expects each ftable id (and its corresponding delimiter) to occur only once in the range of text it is searching.  20 1 1 5 There are more ftables than can fit into the ftable index (TABINX). Thus, this ftable cannot be entered into the index.  20 1 1 5 The delimiter '&CCCCC , &I ' has been found but is not valid. (Has it been misspelled or placed in the wrong columns?)  20 1 1 5 The delimiter '&CCCCC , &I ' has been found but was not expected since there is no previous ftable heading.  20 1 1 5 The delimiter '&CCCCC , &I ' was found but does not match the currently open ftable id, '&CCCCC , &I '. (Is it misspelled or placed in the wrong columns?)  20 1 1 5 The end of the block of text was reached before a delimiter for the last ftable, '&CCCCC , &I ', was found. Was the delimiter misspelled or placed in the wrong columns? j@ Subroutine TABBLK does not expect the block of text which it is searching to end with a partial ftable. MASS-LINK  20 1 1 5 The text '&CCCCCCCCCCCCCCCCCCC' is not recognized as a heading, operation-type or delimiter, and thus will be ignored. Is it misspelled or placed in the wrong fields?  20 1 1 5 There is no valid opn sequence block in the user's control input for this run. This is illegal since resume mode is not implemented in this release of HSPF. j  20 1 1 5 The operation-id '&CCCCC, &I ' appears more than once in the opn sequence block. @ Every operation must have a unique id, otherwise the linkages specified in the ext sources, network and ext targets blocks would be ambiguous.  20 1 1 5 There are more operations in the opn sequence block than can fit into table OPNTAB. Thus, this operation will not be entered in the table.  20 1 1 5 There are more ingroups (explicitly or implicitly specified) in the opn sequence block than can fit into table GRPTAB. Thus, this group will not be entered into the table.  20 1 1 5 There are more exgroups (explicitly or implicitly specified) in the opn sequence block than can fit into table EXGTAB. Thus, this exgroup will not be entered into the table. q  20 1 1 5 Ingrp was specified before the end of the previous ingroup, ingroup no. &I , was found.  20 1 1 5 The following time step was read from the user's control input, but is not valid. Hours Mins &I &I @ HSPF supports a specified set of time series intervals, ranging from one minute to 24 hours. See documentation for details.  20 1 1 5 The following exgroup and ingroup time intervals are not compatible: XDELT NDELT (min) (min) &I &I E@ To be compatible, xdelt must be a multiple of ndelt, or vice versa. q  20 1 1 5 Exgrp was specified before the end of the previous exgroup, exgroup no. &I , was found.  2y $!20040624123459 20040624123459 HRINGEN d NCONS. The no. of the conservative substance which is alkalinity, &I , cannot be greater than the total no. of conservatives being simulated, &I . \  20 1 1 5&D RCHRES: &I The no. of iterations in the pH algorithm reached the max allowable (as specified by the user with parameter phcnt) without convergence. The iteration process will be repeated after this message with debug info being printed. At the present time the following values are being used: COEFF1 COEFF2 COEFF3 COEFF4 ALK TIC &R &R &R &R &R &R Where: The coeffs are coefficients in the 4th order polynomial being solved to find hydrogen ion conc ALK is alkalinity TIC is total inorganic carbonY^] $!20000309112928 20000309112928 HRCHPLK jjjj|  20 1 1 5 RCHRES: &I ZOOFG is on, but PHYFG is off. Zooplankton cannot be simulated without phytoplankton.  20 1 1 5 RCHRES: &I NSFG = 1, but NH3FG is off. The nitrogen supply cannot include ammonia if it is not being simulated. q  20 1 1 5 RCHRES: &I PO4FG is off. Phosphate must be simulated if plankton are being simulated. v]Y $!20000309112929 20000309112929 HRCHSED mlllPmm~  20 11 0 5&D RCHRES: &I The bed storage of sediment size fraction &I is empty. (1- sand 2- silt 3- clay)  20 11 0 5&D RCHRES: &I The total bed sediment depth has a value of &R , which is above the "warning level" (bedwrn) specified in your input as &R .   20 11 0 5&D RCHRES: &I Subroutine Colby is set up to simulate sand transport only when the following conditions are met: 0.1osoo @LOOP COL=SRC ROW=TIM TAB=CON@TITLE@CON:** @SRC:**@TIM:** @**:**:**@TSUM:12 @**:**:00 @LOOP COL=SRC ROW=TIM TAB=CON@TITLE@CON:** @SRC:** @SSUM:12@TIM:** @**:**:** @**:00:**@TSUM:12 @**:**:00 @**:00:00 @LOOP COL=TIM ROW=CON TAB=SRC@TITLE@SRC:** @TIM:** @TSUM:12@CON:** @**:**:** @**:**:00  SUM AVER MAX MIN LAST PCT  20 1 1 5 An invalid transformation (aggregation) functional was specified in the user's control input. The valid values are SUM, AVER, MAX, MIN and LAST. The value supplied is '&CCC'. Was it mis-spelled or placed in the wrong columns?  10 1 1 5 REPORT: &I In a field marker, one of the indices on sources, constituents, or time step cannot be read correctly as an integer. Part of the affected line reads: @CCCCCCC  10 1 1 5 REPORT: &I In a field marker, one of the indices on sources, constituents, or time step is out of range. Part of the affected line reads: @CCCCCCC EGORY block.  5 1 1 5 Unknown category &C was specified in field &I in the HYDR-CINIT table. All categories in this table must be present in the CATEGORY block.  5 1 1 5 In table HYDR-CINIT, the specified fractions sum to &R . They must either sum to unity or all be zero.  5 1 1 5 Unknown category &C was specified in field &I in the HYDR-CPREC table. All categories in this table must be present in the CATEGORY block.  5 1 1 5 In table HYDR-CPREC, the specified fractions sum to &R . They must either sum to unity or all be zero.  5 1 1 5 Unknown category &C was specified in field &I in the HYDR-CEVAP table. All categories in this table must be present in the CATEGORY block.  5 1 1 5 In table HYDR-CEVAP, the specified fractions for priority level &I sum to &R . They must either sum to unity or all be zero.  5 1 1 5 Unknown category &C was specified in field &I in the HYDR-CFVOL table. All categories in this table must be present in the CATEGORY block.  5 1 1 5 In table HYDR-CEVAP, the specified fractions for priority level &I sum to &R . They must either sum to unity or all be zero. 5 There are 1 or more negative values in the following WDM ftable: FTBDSN FTABNO ROW NO. &I &I &I  20 1 1 5 The depth and volume fields of an ftable may not contain values which decrease as the row no. increases. However, this condition is violated in the following row of the following WDM ftable: FTBDSN FTABNO ROW NO. &I &I &I  20 1 1 5 The value in the volume field of the first row of an ftable must be zero. This is not the case for the following WDM ftable: FTBDSN FTABNO VZERPT &I &I &I a@ VZERPT is the variable which indicates the highest row no. for which the volume is still zero.  5 1 1 5 A non zero return code was returned from subroutine WDTBSP. FTBDSN FTABNO RETCOD &I &I &I  5 1 1 5 A non zero return code was returned from subroutine WTBGET. FTBDSN FTABNO RETCOD &I &I &I  20 1 1 5 The number of rows and columns for FTABLE &I contains invalid numeric input. The input string was: NROW NCOL &CCCCCCCCC  20 1 1 5 Data row number &I for FTABLE &I contains invalid numeric input. The input string was: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC  20 1 1 5 Exit number &I has been specified as the irrigation exit for withdrawals from PERLND. This exit may not have any other demands, and thus ODFVFG and ODGTFG must both be set to zero for this exit.  5 1 1 5 Unknown category &C was specified as the initial category in the HYDR-INIT table. All categories in this table must be present in the CATEGORY block.  5 1 1 5 Unknown category &C was specified in field &I in the HYDR-CATEGORY table. All categories in this table must be present in the CAT 1. NROWS >=1 2. 3 <= NCOLS <= 8 3. (NROWS*NCOLS) <= 500 One or more of these conditions is not true for the following FTABLE: FTABNO NROWS NCOLS &I &I &I  20 1 1 5 If the following FTABLE were to contain the stated no. of rows, it would continue beyond the record where its delimiter (END) was found. FTABNO NROWS KEYND &I &I &I @ NROWS is the no. of rows, as stated in the UCI KEYND is the record no., in UCIFL, where the delimiter (END) for this ftable is located |  20 1 1 5 There are 1 or more negative values in the following ftable: FTABNO ROW NO. &I &I  20 1 1 5 The depth and volume fields of an ftable may not contain values which decrease as the row no. increases. However, this condition is violated in row &I of ftable &I .  20 1 1 5 The value in the volume field of the first row of an ftable must be zero. This is not the case for the following WDM ftable: FTABNO VZERPT &I &I a@ VZERPT is the variable which indicates the highest row no. for which the volume is still zero.  20 1 1 5 The following WDM ftable was referred to in the rchres block of the user's control input, but no WDM file is available. The ftable cannot be processed. FTBDSN FTABNO &I &I  20 1 1 5 The following WDM ftable was referred to in the RCHRES block of the user's control input but not found in the WDM file. Are the numbers in error or in the wrong columns? FTBDSN FTABNO &I &I7  20 1 1 5 The layout of an ftable must satisfy all of the following conditions: 1. NROWS >=1 2. 3 <= NCOLS <= 8 3. (NROWS*NCOLS)<=100 One or more of these conditions is not true for the following WDM ftable: FTBDSN FTABNO NROWS NCOLS &I &I &I &I  20 1 1 rdingly? If so, this could account for the problem. Relevant data are: VOL CKVOL CCORR &R &R &R Y@ VOL is the volume in the RCHRES CKVOL is the sum of the category volumes in the RCHRES   20 11 0 5 5 -4&D RCHRES: &I The sum of the category volumes CVOL(*) is zero, but the total volume VOL is positive. CVOL for the first category will be set to VOL. Did you specify any "special actions" that alter the sum of CVOL without changing VOL accordingly? If so, this could account for the problem. Relevant data are: VOL CKVOL &R &R @ VOL is the volume in the RCHRES CKVOL is the sum of the category volumes in the RCHRES CCORR is the renormalization factor VOL/CKVOL  20 1 1 5 Inconsistent input in section HYDR of the RCHRES module. If AUX2FG is on (i.e. not 0), then AUX1FG must also be on. Similarly, AUX3FG on requires that AUX2FG be on. These requirements were not met. J  20 1 1 5 The priority for a COTDGT time series specified in HYDR-CDEMAND is not in proper format. The input value is "&CCCCCCCCCCC". The proper format for a priority date is: " YYYY/MM/DD ". The slashes are optional. Also, a real number may be given directly. Blank defaults to lowest priority.  20 1 1 5 Unrecognized category tag &C was supplied by user in RCHRES block. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  20 1 1 5 Category tag &C was supplied by user in RCHRES block, but no category tags were defined in the CATEGORY block.  20 1 1 5 The FTABLE &I was referred to in the RCHRES block of the user's control input but not found in the FTABLEs block. Is the number in error, or is it in the wrong columns, in either place? #  20 1 1 5 The layout of an FTABLE must satisfy all of the following conditions: RDEP1 RDEP2 COUNT &R &R &R &R &R &I @ A,B and C are factors used to calculate RDEP2 (see documentation) RDEP1,RDEP2 are prior and posterior estimates of relative depth for the final iteration, i.e. (DEP-DEP1)/(DEP2-DEP1) COUNT is the number of the final iteration.  20 1 1 5 5 -4&D RCHRES: &I Calculation of relative depth, using Newton's method of successive approximations, converged to an invalid value (not in range 0.0 to 1.0). Probably ftable was extrapolated. If extrapolation was small, no problem. Remedy; extend ftable. Relevant data are: A B C RDEP1 RDEP2 COUNT &R &R &R &R &R &I @ A,B and C are factors used to calculate RDEP2 (see documentation) RDEP1,RDEP2 are prior and posterior estimates of relative depth for the final iteration, i.e. (DEP-DEP1)/(DEP2-DEP1) COUNT is the number of the final iteration   20 11 0 5 5 -4&D RCHRES: &I The volume of water in this reach/mixed reservoir is greater than the value in the "volume" column of the last row of RCHTAB(). To continue the simulation the table has been extrapolated, based on information contained in the last two rows. This will usually result in some loss of accuracy. If depth is being calculated it will also cause an error condition. Relevant data are: NROWS V1 V2 VOL &I &R &R &R @ NROWS is the no. of rows in RCHTAB V1,V2 are the volumes tabulated in the second-last and last rows of RCHTAB VOL is the volume in the RCHRES   20 11 0 5 5 -4&D RCHRES: &I The continuity error between the sum of the category volumes CVOL(*) and the total volume VOL is greater than 1 part in 1000 and is therefore considered high. Did you specify any "special actions" that alter the sum of CVOL without changing VOL acco,5U $!20001117093302 20001117093302 HRCHHYD &Vqz"{{XxyyAvvw\wwww8tttt6uouuu'rorrrs=sqsss p6pZppppq,q  20 1 1 5 5 -4&D RCHRES: &I The determinant DET, used to solve the simultaneous linear equations in subroutine SOLVE, is zero. It will be reset to 0.001 and program will attempt to continue execution, unless the maximum count for this error has been reached. Relevant data are: V1 V2 ROD1 ROD2 &R &R &R &R@ V1,V2 are the "volume" values in RCHTAB corresponding to the segment of equation 8 currently being dealt with (see documentation). ROD1,ROD2 are the corresponding total outflow demands.   20 1 1 5 5 -4&D RCHRES: &I Subroutine SOLVE has become trapped, in searching for the solution to the routing equations. It is yo-yoing back and forth between two adjacent segments of the "total outflow demand vs volume" curve (equation 8). If it occurs once or twice - no problem. If it stops the run you probably have an equation 8 with unusual shape and your ftable probably needs alteration. Relevant data are: MOVE PREMOV &I &I W@ MOVE and PREMOV indicate latest and previous directions of movement along the curve.   20 1 1 5 5 -4&D RCHRES: &I The calculation of relative depth in subroutine AUXIL, using Newton's method of successive approximations, did not converge. Probable reason -- unusual or bad entries in RCHTAB. Relevant data are: A B C v $!20000309112929 20000309112929 HRINGEUT ~||B}}} ~:~~~o  20 1 1 5The heading '&CCCCCCCCCCC' has been found, but the delimiter'&CCCCCCCCCCC' was expected. 5@Subroutine LOCBLK searches for self-contained "blocks" of text,i.e. a group of lines commencing with a valid heading and ending with a corresponding delimiter END . Once avalid heading has been found, the code expects to find the correspondingdelimiter before another heading is found.  20 1 1 5The heading '&CCCCCCCCCCC' has occurred too many times. The maximumnumber of times this heading can occur is &I . @Subroutine LOCBLK expects the no. of occurrences of each heading (and itscorresponding delimiter) not to exceed the "dimension" specified for it.   20 1 1 5The first non-comment line in a run data set, or after a delimiter(eg. END ), must be a valid heading. Instead, '&CCCCCCCCCCC'was found. Possibly it was not recognized because of mis-spelling orincorrect column position.  20 1 1 5The delimiter '&CCCCCCCCCCC' has been found but is not valid.(Has it been misspelled or placed in the wrong columns?)P@A delimiter has the form END where must be avalid heading.y  20 1 1 5The delimiter '&CCCCCCCCCCC' was found but not expected because an openheading did not precede it. @A heading is considered "open" when it is found, and "closed" whenthe corresponding delimiter is found. A delimiter is only expectedif one heading is open.  20 1 1 5The delimiter '&CCCCCCCCCCC' was found but does not match the currentlyopen heading '&CCCCCCCCCCC'. (Is it mis-spelled or placed in the wrongcolumns?)  20 1 1 5The end of the range of text was reached before a delimiter for theheading '&CCCCCCCCCCC' was found. (Was the delimiter mis-spelled orplaced in the wrong columns?)@Subroutine LOCBLK does not expect the range of text which it is searchingto end with a partial block of text (ie. without an END ).  20 1 1 5A value of &I was found for the value of TOPFST. The TOPFST fieldin the ext sources, network or spec-actions blocks must contain apositive value.  20 1 1 5A value of &I was found for the value of TOPLST. The TOPLST field inthe ext sources, network or spec-actions blocks may not contain a valuesmaller than &I, the value of TOPFST (except zero). $!20000309112929 20000309112929 HRINOPUTր  20 1 1 5The OPFST field in Table &CCCCCCCCCCC, &I contains the value &I .This field must contain a positive value.  20 1 1 5The OPLST field in Table &CCCCCCCCCCC, &I contains the value &I ,which is smaller than the value &I in the OPFST field.   20 1 1 5An error occurred reading the OPFST and OPLST fields (first ten characters)in Table &CCCCCCCCCCC, &I . $!20000309112929 20000309112929 HRINSEQ ӂO  20 1 1 5 VOLNO: &I Invalid format class specification, '&CCCCC'. f  20 1 1 5 VOLNO: &I Format not found in the formats block or no formats block was found. Q  20 1 1 5 VOLNO: &I Invalid gap value specified. Zero substituted. \  20 1 1 5 VOLNO: &I Invalid string '&CCC' given in external unit system field.R  20 1 1 5 VOLNO: &I Invalid unit number. Valid range is 14 thru 99. V  20 1 1 5 Invalid numeric input in FORMATS block. Input string was &CCC. $!20000309112929 20000309112929 HRINTS %?T&00ˇ&K|ӈ'Uˉ#\Ċ+׋" TSS SEQ WDM DSS  ADD INST REPL  ENGL METR  ZERO UNDF HYDHR 60 3HYDDAY 1440 3HYDSMN 1440 3HYDMON 1440 3HYDFIV 5 3HYDFIF 15 3 K SAME DIV AVER SUM MAX MIN INTP LAST   1 1 1 1 1 2 1 1 1 3 1 3 2 1 1 7 2 2 1 1 2 2 3 1 3 3 1 1 8 3 2 1 1 1 1 4 3 3 1 1 1 1 3V@CASE STKND STTRAN 1 2 3 4 5 6 7 8 def " (10X,I2,1X,I2,1X,I2,1X,I1,12F5.0)  (7X,2I2,I1,11F6.0)  (7X,I2,I1,12F5.0)  (6X,I2,12F6.0)  (1X,3I2,I1,36F2.0)  (1X,3I2,I1,12F6.0)   30 0 0   30 0 0  PWATER PERO 1 1 0.08333 INFLOW IVOL 1 1PWTGAS POHT 1 1 1.0 INFLOW IHEAT 1 1SEDMNT SOSED 1 1 0.33333 INFLOW ISED 1 1SEDMNT SOSED 1 1 0.33333 INFLOW ISED 2 1SEDMNT SOSED 1 1 0.33333 INFLOW ISED 3 1PWTGAS PODOXM 1 1 1.0 INFLOW OXIF 1 1NITR PONO3 1 1 1.0 INFLOW NUIF1 1 1NITR TSAMS 1 1 1.0 INFLOW NUIF1 2 1NITR TSAMS 5 1 1.0 INFLOW NUIF1 2 1NITR SSAMS 3 1 1.0 INFLOW NUIF1 2 1PHOS TSP4S 1 1 1.0 INFLOW NUIF1 4 1PHOS TSP4S 5 1 1.0 INFLOW NUIF1 4 1PHOS SSP4S 3 1 1.0 INFLOW NUIF1 4 1NITR SEDN 2 1 1.0 INFLOW NUIF2 1 1PHOS SEDP 2 1 1.0 INFLOW NUIF2 2 1NITR SEDN 1 1 1.0 INFLOW PKIF 3 1PHOS SEDP 1 1 1.0 INFLOW PKIF 4 1PWTGAS POCO2M 1 1 1.0 INFLOW PHIF 2 1 @ perlnd to rchres  IWATER SURO 1 1 0.08333 INFLOW IVOL 1 1IWTGAS SOHT 1 1 1.0 INFLOW IHEAT 1 1SOLIDS SOSLD 1 1 0.33333 INFLOW ISED 1 1SOLIDS SOSLD 1 1 0.33333 INFLOW ISED 2 1SOLIDS SOSLD 1 1 0.33333 INFLOW ISED 3 1IWTGAS SODOXM 1 1 1.0 INFLOW OXIF 1 1IWTGAS SOCO2M 1 1 1.0 INFLOW PHIF 2 1 @ implnd to rchres  20 1 1 5 Unrecognized category tag &C was supplied by user in EXT SOURCES block. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  20 1 1 5 Category tag &C was supplied by user in EXT SOURCES block, but no category tags were defined in the CATEGORY block.  20 1 1 5 Unrecognized category tag &C was supplied by user in NETWORK block. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  20 1 1 5 Category tag &C was supplied by user in NETWORK block, but no category tags were defined in the CATEGORY block.  20 1 1 5 Unrecognized category tag &C was supplied by user in SCHEMATIC block. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  20 1 1 5 Category tag &C was supplied by user in SCHEMATIC block, but no category tags were defined in the CATEGORY block.  20 1 1 5 Unrecognized category tag &C was supplied by user in EXT TARGETS block. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  20 1 1 5 Category tag &C was supplied by user in EXT TARGETS block, but no category tags were defined in the CATEGORY block.  20 1 1 5 The timeseries below is input only. User is attempting to output it. Opn-ID Grp-Name Mem-Name &CCCCC &I &CCCCC &CCCCC  20 1 1 5 The timeseries below is output only. User is attempting to input it. Opn-ID Grp-Name Mem-Name &CCCCC &I &CCCCC &CCCCC  20 1 1 5 The time series group-name &CCCCC, for operation ID &CCCCC, &I , encountered in the ext sources, network or ext targets blocks, is invalid. Was it placed in the wrong columns?  20 1 1 5 The following time series member-name, encountered in the ext sources, network or ext targets blocks, is invalid. Was it placed in the wrong columns? Opn-ID Grp-Name Mem-Name &CCCCC &I &CCCCC &CCCCCE  20 1 1 5 A member-name subscript, encountered in the ext sources, network or ext targets blocks, is invalid (out of range). Was it placed in the wrong columns? Opn-ID Grp-Name Mem-Name Subscript Value &CCCCC &I &CCCCC &CCCCC &I  20 1 1 5 The time intervals of the following source and target time series, specified in the ext sources, network or ext targets blocks, are not compatible. Source: &CCCCC, &I Target: &CCCCC, &I   20 1 1 5 The following source/target pair of time series is specified or implied in an entry in the ext sources, network or ext targets blocks. However, this is invalid because the source is mean valued and the target is point-valued. Opn-ID Grp-Name Member-ID Source: &CCCCC, &I &CCCCC &CCCCC &I &I Target: &CCCCC, &I &CCCCC &CCCCC &I &I  20 1 1 5 The source/target transformation function, specified in the following entry which appeared in the ext sources, network or ext targets blocks, is invalid: Transf Stkind Case | Opn-ID Grp-Name Member-ID Function | Source: &CCCCC,&I &CCCCC &CCCCC &I &I &CCC &I &I | Target: &CCCCC,&I &CCCCC &CCCCC &I &I ^  20 1 1 5 For each entry in the network or schematic block, the source opn must be "upstream" of the target operation; that is, the source must appear ahead of the target in the opn sequence block. However, the following entry violates this condition: Source Target Opn-ID Opn-ID &CCCCC &I &CCCCC &I e  20 1 1 5 Program bug. VOLCOD requests EXPAD operation when EXPAD not yet implemented.  20 1 1 5 Program bug. DSS record ID number &I listed in EXT SOURCES or EXT TARGETS blocks does not appear in PATHNAMES block. This should have caused a fatal error in subroutine DSSDS.  20 1 1 5 Aggregation to a WDM dataset requires that the timestep of the dataset be an even multiple of the run timestep. Check TCODE and TSSTEP of the dataset. Also, VBTIME may be incompatible with TCODE, TSSTEP. $!20000309112929 20000309112929 HRINTSS 0QΏ,CX'Ah͑ $:OfD  1 1 1 5 Incompatible tss. Processing must terminate.  VOLNO: &I 20 1 1 5 Year containing initial interval of the run, &I , is outside of the valid range for the dataset. Valid range is from baseyr+1 to baseyr+100.y  20 1 1 5 VOLNO: &I Dataset is write protected. Unable to output data to the specified external target.  20 1 1 5 VOLNO: &I Year containing final interval of the run, &I , is outside of the valid range of the dataset. Valid range is from baseyr+1 to baseyr+100. w  20 1 1 5 VOLNO: &I One or more years of data are missing in the dataset for the time span of the run. K  20 1 1 5 VOLNO: &I Invalid access mode &CCC was specified. Z  20 1 1 5 VOLNO: &I Member name &CCCCC was not found in the dataset label. O  20 1 1 5 VOLNO: &I Specified dataset was not found in the tss.  20 1 1 5 DSN: &I Program bug. Dataset number given in tss directory record does not agree with dataset number used to find the record. b  20 1 1 5 DSN: &I Time series dataset reference made to the tss dircetory dataset. T  20 1 1 5 DSN: &I Dataset number outside of valid range for the tss.L  20 1 1 5 SVOLNO: &I Member subscript &I is out of range.  20 1 1 5 FILE: &I Time gap of one or more years encountered using add or insert for a dataset which requires data to be stored in chronological order. w  20 1 1 5 FILE: &I Attempt to use add access on a dataset in which data is not in chronological order. l  20 1 1 5 FILE: &I Starting year is earlier than first year permitted in the keying system.q  20 1 1 5 FILE: &I Attempt to access dataset with insert for a year which already contains data. R  20 1 1 5 FILE: &I Attempt to use replace for a year without data. ]  20 1 1 5 FILE: &I Program bug or invalid dataset label. Improper branching. K  20 1 1 5 FILE: &I Program bug. Buffer underflow in gword. ]  20 1 1 5 FILE: &I Attempt to obtain data from beyond upper limit of dataset.  20 1 1 5 FILE: &I End of year encountered in fitsb. Either data is missing for part of your run span or your tss is screwed up.  20 1 1 5 FILE: &I End of data encountered in fitsb. Either data is missing for part of your run span or your tss is screwed up.  20 1 1 5 FILE: &I Invalid time series block encountered during setup for replace access. Block must be type uncompressed.Z  20 1 1 5 FILE: &I Program bug. Timing error in aiunc. stime not= tzero. [  20 1 1 5 FILE: &I Program bug. Timing error in aicomp. stime not= tzero. y  20 1 1 5 FILE: &I Program bug. Linear variation bti encountered when such bti's are not yet supported. [  20 1 1 5 FILE: &I Program bug. Linking bcw is not zero when it should be. N  20 1 1 5 FILE: &I Program bug. Invalid buffer state in pval. J  20 1 1 5 FILE: &I Program bug. Buffer underflow in pval. S  20 1 1 5 FILE: &I Program bug. Buffer/extension overflow in pval. u  20 1 1 5 FILE: &I Dataset overflow in pval. Probable cause - too little space in your tss dataset. t $!20000309112929 20000309112929 HRINWDM 0)Dsٕ#Nm`  20 1 1 5 VOLNO: &I WDMSFL: &I Specified dataset was not found in the WDM file.y  20 1 1 5 VOLNO: &I WDMSFL: &I Specified WDM dataset name '&CCC' does not match attribute TSTYP, '&CCC'. d  20 1 1 5 VOLNO: &I WDMSFL: &I Attribute TSTYP not found for specified WDM dataset.  20 1 1 5 VOLNO: &I WDMSFL: &I Specified WDM dataset has an invalid TCODE attribute for HSPF; must be minute, hour, or day for target (month is ok for source).  20 1 1 5 VOLNO: &I WDMSFL: &I Attribute TCODE and/or TSSTEP not found for specified WDM dataset; it is not a timeseries dataset.  20 1 1 5 VOLNO: &I WDMSFL: &I Time span of simulation is not within time span of specified WDM source dataset. g  20 1 1 5 VOLNO: &I WDMSFL: &I Specified WDM target dataset is "read-only" (RWFLAG=1).  20 1 1 5 VOLNO: &I WDMSFL: &I Specified units system is not compatible with units system of WDM dataset. ERRCOD = &I  20 1 1 5 VOLNO: &I WDMSFL: &I Specified access mode is invalid for WDM datasets; must be "add" or "replace".  20 1 1 5 VOLNO: &I WDMSFL: &I Specified gap value is invalid. "UNDEFINED" substituted, or attribute TSFILL from WDM dataset used, if available. s  20 1 1 5 VOLNO: &I WDMSFL: &I Specified WDM data quality code is invalid. Valid values are 0-31.  20 1 1 5 VOLNO: &I WDMSFL: &I Specified access mode for WDM dataset is "add"; however, data are already present in dataset after run start time.  20 1 1 5 VOLNO: &I WDMSFL: &I The specified aggregation keyword is incorrect for WDM dataset; 'AGGR' should be used in columns 69-72.  20 1 1 5 VOLNO: &I WDMSFL: &I Aggregation to a WDM dataset requires that the timestep of the dataset be an even multiple of the run timestep. Check TCODE and TSSTEP of the dataset. Also, VBTIME may be incompatible with TCODE, TSSTEP.  20 1 1 5 VOLNO: &I WDMSFL: &I The specified WDM dataset does not have a valid value for the TSFORM attribute. TSFORM should be 1 or 2 (mean) or 3 (point). t $!20000309112929 20000309112929 HUTDURA Ę  20 1 1 5 The "levels" specified for the duration analysis do not form an ascending sequence. These levels are as follows: &R &R &R &R &R &R &R &R &R t $!20000309112929 20000309112929 HRUNTSGPҚ  20 1 1 5&D Debug error: Volume code, &I , is invalid as passed to tsget in instruction file record &I . Volume code values of 1,2,3, or 4 are allowed. ]  20 1 1 5&D FILE: &I Program bug. Expad selected but not yet implemented. $!20000309112929 20000309112929 HRUNTSGQ 0_՝W  20 1 1 5&D FILE: &I Debug Error: Time interval on inpad, DELT, does not agree with time interval on sequential file, DELTAT, in GETSEQ subroutine. Relevant data: DELT DELTAT File No. &I &I &I Aggregation/Disaggregation not allowed for sequential files, except semi-monthly or monthly data will be disaggregated to daily data on inpad   20 1 1 5&D FILE: &I Debug Error: In subroutine GETSEQ monthly or semi-monthly data is not being disaggregated to daily data on inpad. Relevant data: DELT DELTAT File No. Format Class &I &I &I &I  20 1 1 5&D FILE: &I Debug Error: In subroutine GETSEQ the value for format class is out of bounds. Relevant data: Format Class File &I &I   20 1 1 5&D FILE: &I Trying to read more values than exist on input card in subroutine SEQINP. Relevant data: MAXCNT CRDCNT File No. &I &I &I MAXCNT is number of values on card CRDCNT is number of card values trying to be read  20 1 1 5&D FILE: &I Debug Error: Month read from Hydrocomp daily format card is out of bounds in subroutine DACRD. Relevant data: SEQFL MONTH &I &I s  20 1 1 5&D FILE: &I Invalid date (&I /&I /&I ) found on input card. The card is ignored.  20 1 1 5&D FILE: &I Invalid card number (&I , at &I /&I /&I ) found on input card. The card is ignored.  20 1 1 5&D FILE: &I Error in sequence of input cards in subroutine CHKSEQ. Relevant data: CARDNO/DATE of last card read: &I , &I /&I /&I CARDNO/DATE of last card in proper sequence: &I , &I /&I /&I9  20 1 1 5&D FILE: &I Error reading input card in sequential time series (SEQ) file. The card is: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC The FORTRAN read format is: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC $!20000309112929 20000309112929 HRUNTSGT;  20 1 1 5&D FILE: &I The end of chronological data for this tss dataset has been encountered in bcwupd subroutine. Relevant data: BCW INPEND FRMTIM TENDR DSNO &I &I &I &I &I BCW is the block control word INPEND is the time at the end of the inpad FRMTIM is the frame time of the current value from the tss TENDR is time at end of the run DSNO is dataset number  20 1 1 5&D FILE: &I The year read from the tss in subroutine bcwupd does not agree with the current year. Relevant data: YEAR FROM TSS PRESENT YEAR DSNO &I &I &I r  20 1 1 5&D FILE: &I Debug error: BTI (block type indicator) from the current BCW does not have a valid value in subroutine fillws. Relevant data: BTI DSNO &I &I BTI allows values from 1-4, where 1 is uncompressed data, 2 is zero compressed data, 3 is undefined compressed data, and 4 is linear variation. DSNO is dataset number. f  20 1 1 5&D FILE: &I Debug error: In subroutine gtssrc the desired tss record number is out of the bounds of the current dataset. Relevant data: RECNO FREC LREC DSNO &I &I &I &I RECNO is the desired record number in tss. FREC, LREC are the first and last record number in this dataset. DSNO is the dataset number. $!20000309112929 20000309112929 HRUNTSGWt  20 1 1 5 FILE: &I Data from the WDM file have been set to the 'Missing Data' value, probably because the data 'quality' is less than the specified threshold. Relevant data are listed below. (Subr. GETWDM) INPTIM NVALS QLFG GAPVAL RETCOD &I &I &I &I &I &I &I &I &I &I $!20000309112929 20000309112929 HRUNTSPDFȤ  1 1 1 5 An error has ocurred converting a WDM-style date to a DSS-style character date. Relevant data are listed below. (Subr. PUTDSS) INPTIM RETCOD &I &I &I &I &I &I &I  1 1 1 5&D A fatal error occurred calculating a position in the INPAD. Relevant data are listed below. (Subr. PUTDSS) VOPADR NPTS PLACE SCRSIZ &I &I &I &I   1 1 1 5An error occurred storing &I data points in DSS file number &I . Thestarting date and time were &CCC &CCCCCCCCCCCCCCCCCCC, and the pathname was: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCThe return code was &I . $!20000309112929 20000309112929 HRUNTSPT&J`vħۧ/FYlɨߨH  20 1 1 5&D FILE: &I Program bug. TXVAR not= FRMTIM.~  20 1 1 5&D FILE: &I Program bug. Linear variation BTI encountered when such BTI's are not yet supported.  20 1 1 5&D FILE: &I Program bug. Linear variation compression selected when such compression is not yet supported.O  20 1 1 5&D FILE: &I Program bug. Buffer underflow in RGET. O  20 1 1 5&D FILE: &I Program bug. Dataset overflow in RGET. N  20 1 1 5&D FILE: &I Program bug. Buffer overflow in RGET.  20 1 1 5&D FILE: &I Invalid time series block encountered during replace access. Block must be type uncompressed. O  20 1 1 5&D FILE: &I Program bug. Buffer underflow in RPUT. O  20 1 1 5&D FILE: &I Program bug. Dataset overflow in RPUT. N  20 1 1 5&D FILE: &I Program bug. Buffer overflow in RPUT. k  20 1 1 5&D FILE: &I Program bug. Year not= value of year obtained in dataset in REPLC. a  20 1 1 5&D FILE: &I End of chronological data encountered before end of run. T  20 1 1 5&D FILE: &I Program bug. Invalid buffer state in PTVAL.P  20 1 1 5&D FILE: &I Program bug. Buffer underflow in PTVAL.Y  20 1 1 5&D FILE: &I Program bug. Buffer/extension overflow in PTVAL. |  20 1 1 5&D FILE: &I Dataset overflow in PTVAL. Probable cause is not enough space in your TSS dataset.T  20 1 1 5&D FILE: &I Program bug. Invalid buffer state in BUFINT.C  20 1 1 5&D FILE: &I Dataset underflow in BUFINT B  20 1 1 5&D FILE: &I DATASET overflow in BUFINT O  20 1 1 5&D FILE: &I Program bug. Buffer overflow in BUFINT j  20 1 1 5&D FILE: &I Program bug. Buffer/extension does not contain the TSB in BUFINT. S  20 1 1 5&D FILE: &I Program bug. Invalid buffer state in REPLC B  20 1 1 5&D FILE: &I Dataset overflow in WFBUFF P  20 1 1 5&D FILE: &I Program bug. Buffer underflow in GTWORDb  20 1 1 5&D FILE: &I Attempt to obtain data from beyond upper limit of dataset. $!20000309112929 20000309112929 HRUNTSPWs  20 1 1 5 FILE: &I Attempt to write data to WDM file was unsuccessful, possibly because data existed in the dataset and the access mode was not set to "repl"; Relevant data are listed below. (Subr. PUTWDM) INPTIM DELTAT NVALS DTOVWR RETCOD &I &I &I &I &I &I &I &I &I &I [ $!20000309112929 20000309112929 HRUNTSUTͬ  20 1 1 5&D Debug error: STKIND is not valid in MOVROW subroutine. Relevant data: STKIND(I) DSNO &I &I STKIND is code for kind of data transfer. 1= point to point data; 2= mean to mean data; 3= point to mean. s~r $!20000607144809 20000607144809 HRUNUT Я'B  5 11 0 5 5 -4 The continuity error reported below is greater than 1 part in 1000 and is therefore considered high. Did you specify any "special actions"? If so, they could account for it. Relevant data are:&D &CCCCC :&I RELERR STORS STOR MATIN MATDIF &R &R &R &R &R Where: RELERR is the relative error (ERROR/REFVAL). ERROR is (STOR-STORS) - MATDIF. REFVAL is the reference value (STORS+MATIN). STOR is the storage of material in the processing unit (land-segment or reach/reservior) at the end of the present interval. STORS is the storage of material in the pu at the start of the present printout reporting period. MATIN is the total inflow of material to the pu during the present printout reporting period. MATDIF is the net inflow (inflow-outflow) of material to the pu during the present printout reporting period. &  1 1 1 5 10 5 -4&D &CCCCC :&I The required input timeseries &CCCCC &I &I was omitted for thisoperation. It is always required for this operation type. It mustappear as an input to this operation in the EXT SOURCES, NETWORK, and/orSCHEMATIC/MASS-LINK blocks. A  1 1 1 5 10 5 -4&D &CCCCC :&I The required input timeseries &CCCCC &I &I was omitted for thisoperation. It is required for this operation type whenever section[ $!20000309112929 20000309112929 HRCHOXR c  20 11 0 5&D RCHRES: &I The calculated saturation dissolved oxygen concentration (SATDO) is negative. This occurs when the water temperature above 66 C (150 F). In most cases, this indicates an error in the time series input (GATMP if HTRCH is on, TW if HTRCH is off). Relevant values are : SATDO TW &R &R X $!20040624123429 20040624123429 PERLNDTSܳ/3YǴWu:e<gBmøDoŹJu˺!Lwͻ'R}Ӽ)Tս0[ܾ2]޿ 8c:e@kBmHsJu%P{'R}-X/Z 5` 7b=h?jEpGr"Mx$Oz*U,W2] 4_:e<gBmDoJu!Lw'R})T0[2] 8c:e@k EXTNL 20ATEMP 70SNOW 80PWATER 110SEDMNT 150PSTEMP 160PWTGAS 170PQUAL 200MSTLAY 220PEST 230NITR 260PHOS 310TRACER 340 2 GATMPPRECDTMPGWINMOVSOLRADCLOUDSURLIUZLIIFWLILZLIAGWLIPETINPIRRINPSLSEDSLITMPILITMPALITMPSLIDOXILIDOXALIDOXSLICO2ILICO2ALICO2SLIQOSLIQSPILIQCALIQCPQADFXPQADCNLIPSSLISDPSPEADFXPEADCNLIAMSLINO3LISLNLISRNLISEDNNIADFXNIADCNLIP4SLISEDPPHADFXPHADCNLITRSTRADFXTRADCN  AIRTMP PACKPACKFPACKWPACKIPDEPTHCOVINXNEGHTSXLNMLTRDENPFSKYCLRSNOCOVDULLALBEDOPAKTMPDEWTMPSNOTMPSNOWFPRAINSNOWEWYIELDMELTRAINF PERSCEPSSURSUZSIFWSLZSAGWSTGWSGWELGWVSINFFACPETADJRPARMRZWSSUPYSUROIFWOAGWOPEROIGWIPETCEPESURETUZETLZETAGWETBASETTAETIFWIUZIINFILPERCLZIAGWISURIIRRDEMIRSHRTIRDRAWIRRAPP + DETSSTCAPCOVERWSSDSCRSDSOSEDDETNVSI  AIRTCSLTMPULTMPLGTMP SOTMPIOTMPAOTMPSODOXSOCO2IODOXIOCO2AODOXAOCO2SOHTIOHTAOHTPOHTSODOXMSOCO2MIODOXMIOCO2MAODOXMAOCO2MPODOXMPOCO2M q SQOSOQSPIOQCAOQCWASHQSSCRQSSOQSSOQOSOQOCSOQUALSOQCIOQUALAOQUALPOQUALPOQCPQADDRPQADWTPQADEPISQO MSTFRAC SPSUPSIPSLPSAPSTPSTPSTTOTPSTSDPSTSPSSSSPSSSDEGPSUDEGPSLDEGPSADEGPSTDEGPSSOSDPSSOPESTPOPSTTOPSTPEADDRPEADWTPEADEP  NITIFAGPLTNLITTRNSNUNINLNANTNTNITTOTNITNDFCTNUPTGSEDNTSAMSSSAMSTSNO3SSNO3DENIFTDENIFAMNITAMIMBORNMNNIADDRNIADWTNIADEPNFIXFXTSSLNSSSLNTSSRNSSSRNNIIMBAMVOLREFRONNIUPAAMUPANIUPBAMUPBRETAGNRTLLNRTRLNRTLBNRTRBNSOSEDNPONO3PONH4POORNPONITRp PHOIFSPUPIPLPAPTPTPHOTOTPHOPDFCTPUPTGSEDPTSP4SSSP4SP4IMBORPMNSOSEDPPOPHOSPHADDRPHADWTPHADEPJ STRSUUTRSUITRSULTRSUATRSUTRSUTSTRSSSTRSPOTRSTRADDRTRADWTTRADEP GATMP 1 1 1 1 2 0 2 0 115 ENG Deg F 0 117.8 1.8 Measured air temp over PLS MET Deg C 0 117.8 1.8 PREC 1 1 1 1 2 0 2 0 116 ENG in/iv 0 1 0 .0394 Measured precipitation on PLS MET mm/iv 0 1 0 .0394 DTMPG 1 1 1 1 2 0 2 0 153 ENG Deg F 0 117.8 1.8 Measured dewpoint temp over PLS MET Deg C 0 117.8 1.8 WINMOV 1 1 1 1 2 0 2 0 154 ENG mi/iv 0 1 0 .621 Measured wind movement over PLS MET km/iv 0 1 0 .621 SOLRAD 1 1 1 1 2 0 2 0 155 ENG Ly/iv 0 1 0 1 Measured solar radiation over PLS MET Ly/iv 0 1 0 1 CLOUD 1 1 1 1 2 0 2 0 156 ENG tenths 0 1 0 1 Cloud cover (range 0 thru 10) MET tenths 0 1 0 1 SURLI 1 1 1 1 2 0 2 0 346 ENG in/iv 0 1 0 .0394 Surface lateral inflow to PLS MET mm/iv 0 1 0 .0394 UZLI 1 1 1 1 2 0 2 0 347 ENG in/iv 0 1 0 .0394 Upper zone lateral inflow to PLS MET mm/iv 0 1 0 .0394 IFWLI 1 1 1 1 2 0 2 0 348 ENG in/iv 0 1 0 .0394 Interflow lateral inflow to PLS MET mm/iv 0 1 0 .0394 LZLI 1 1 1 1 2 0 2 0 349 ENG in/iv 0 1 0 .0394 Lower zone lateral inflow to PLS MET mm/iv 0 1 0 .0394 AGWLI 1 1 1 1 2 0 2 0 350 ENG in/iv 0 1 0 .0394 Active groundwater lateral inflow to PLS MET mm/iv 0 1 0 .0394 PETINP 1 1 1 1 2 0 2 0 351 ENG in/iv 0 1 0 .0394 Input potential E-T from PLS MET mm/iv 0 1 0 .0394 IRRINP 1 1 1 1 2 0 2 0 357 ENG in/iv 0 1 0 .0394 Input irrigation demand MET mm/iv 0 1 0 .0394 SLSED 1 1 1 1 2 0 2 0 1110 ENG tn/aciv 0 1 0 .4462 Lateral input of sediment to PLS MET tne/haiv 0 1 0 .4462 SLITMP 1 1 1 1 2 0 2 0 1279 ENG Deg F -32 .555 0 1 Temp of surface lateral inflow MET Deg C -32 .555 0 1 ILITMP 1 1 1 1 2 0 2 0 1280 ENG Deg F -32 .555 0 1 Temp of interflow lateral inflow MET Deg C -32 .555 0 1 ALITMP 1 1 1 1 2 0 2 0 1281 ENG Deg F -32 .555 0 1 Temp of groundwater lateral inflow MET Deg C -32 .555 0 1 SLIDOX 1 1 1 1 2 0 2 0 1282 ENG mg/l 0 1 0 1 Conc of DO in surface lateral inflow MET mg/l 0 1 0 1 ILIDOX 1 1 1 1 2 0 2 0 1283 ENG mg/l 0 1 0 1 Conc of DO in interflow lateral inflow MET mg/l 0 1 0 1 ALIDOX 1 1 1 1 2 0 2 0 1284 ENG mg/l 0 1 0 1 Conc of DO in groundwater lateral inflow MET mg/l 0 1 0 1 SLICO2 1 1 1 1 2 0 2 0 1285 ENG mg/l 0 1 0 1 Conc of CO2 in surface lateral inflow MET mg/l 0 1 0 1 ILICO2 1 1 1 1 2 0 2 0 1286 ENG mg/l 0 1 0 1 Conc of CO2 in interflow lateral inflow MET mg/l 0 1 0 1 ALICO2 1 1 1 1 2 0 2 0 1287 ENG mg/l 0 1 0 1 Conc of CO2 in groundwater lateral inflow MET mg/l 0 1 0 1 SLIQO 10 1 -1569 1 2 0 2 0 1507 ENG qty/aciv 0 1 0 .4047 Lateral input of QUALOF to PLS MET qty/haiv 0 1 0 .4047 SLIQSP 10 1 -1568 1 2 0 2 0 1517 ENG qty/ton 0 1 0 .9072 Pot fac of QUALSD on lat sediment inflow MET qty/tonn 0 1 0 .9072 ILIQC 10 1 -1570 1 2 0 2 0 1527 ENG qty/ft3 0 3630. 0 102833. Conc of QUALIF in lateral interflow inflow MET qty/l 0 3630. 0 102833. ALIQC 7 1 -1571 1 2 0 2 0 1537 ENG qty/ft3 0 3630. 0 102833. Conc of QUALGW in lat groundwater inflow MET qty/l 0 3630. 0 102833. PQADFX 10 1 -1567 1 2 0 2 0 1547 ENG qty/aciv 0 1 0 .4047 Atmospheric deposition of QUAL to PLS MET qty/haiv 0 1 0 .4047 PQADCN 10 1 -1567 1 2 0 2 0 1557 ENG qty/ft3 0 3630. 0 102833. Concentration of QUAL in precip over PLS MET qty/l 0 3630. 0 102833. LIPSS 5 3 5 -3626 2 0 2 0 3587 ENG lb/aciv 0 1 0 .892 Lateral input of soln pest. to each layer MET kg/haiv 0 1.12 0 1 LISDPS 2 3 2 -3626 2 0 2 0 3602 ENG lb/aciv 0 1 0 .892 Lateral input of sediment-associated pest. MET kg/haiv 0 1.12 0 1 PEADFX 3 3 -3626 3 2 0 2 0 3608 ENG lb/aciv 0 1 0 .892 Atmospheric deposition of pesticide form MET kg/haiv 0 1.12 0 1 PEADCN 3 3 -3626 3 2 0 2 0 3617 ENG mg/l 0 .226635 0 .01 Concentration of pesticide form in precip MET mg/l 0 .226635 0 .01 LIAMS 5 1 5 1 2 0 2 0 4734 ENG lb/aciv 0 1 0 .892 Lateral inflow of soln ammon to each layer MET kg/haiv 0 1.12 0 1 LINO3 5 1 5 1 2 0 2 0 4739 ENG lb/aciv 0 1 0 .892 Lateral inflow of nitrate to each layer MET kg/haiv 0 1.12 0 1 LISLN 5 1 5 1 2 0 2 0 4744 ENG lb/aciv 0 1 0 .892 Lat inflow of soln lab ORGN to each layer MET kg/haiv 0 1.12 0 1 LISRN 5 1 5 1 2 0 2 0 4749 ENG lb/aciv 0 1 0 .892 Lat inflow of soln ref ORGN to each layer MET kg/haiv 0 1.12 0 1 LISEDN 3 1 3 1 2 0 2 0 4754 ENG lb/aciv 0 1 0 .892 Lat inflow of sediment-associated N MET kg/haiv 0 1.12 0 1 NIADFX 3 2 3 2 2 0 2 0 4757 ENG lb/aciv 0 1 0 .892 Atmospheric deposition of N to soil layer MET kg/haiv 0 1.12 0 1 NIADCN 3 2 3 2 2 0 2 0 4763 ENG mg/l 0 .226635 0 .01 Concentration of N to soil layer in precip MET mg/l 0 .226635 0 .01 LIP4S 5 1 5 1 2 0 2 0 6622 ENG lb/aciv 0 1 0 .892 Lateral inflow of soln PO4 to each layer MET kg/haiv 0 1.12 0 1 LISEDP 2 1 2 1 2 0 2 0 6627 ENG lb/aciv 0 1 0 .892 Lateral inflow of sediment-associated P MET kg/haiv 0 1.12 0 1 PHADFX 2 2 2 2 2 0 2 0 6629 ENG lb/aciv 0 1 0 .892 Atmospheric deposition of P to soil layer MET kg/haiv 0 1.12 0 1 PHADCN 2 2 2 2 2 0 2 0 6633 ENG mg/l 0 .226635 0 .01 Concentration of P to soil layer in precip MET mg/l 0 .226635 0 .01 LITRS 5 1 5 1 2 0 2 0 7214 ENG lb/aciv 0 1 0 .892 Lateral inflow of tracer to each layer MET kg/haiv 0 1.12 0 1 TRADFX 2 1 2 1 2 0 2 0 7219 ENG lb/aciv 0 1 0 .892 Atmospheric deposition of tracer to layer MET kg/haiv 0 1.12 0 1 TRADCN 2 1 2 1 2 0 2 0 7221 ENG mg/l 0 .226635 0 .01 Concentration of tracer to layer in precip MET mg/l 0 .226635 0 .01 AIRTMP 1 1 1 1 2 1 1 0 144 ENG Deg F 0 117.8 1.8 Estimated surf air temp over PLS MET Deg C 0 117.8 1.8 PACK 1 1 1 1 1 2 0 262 ENG in 0 1 0 .0394 Total contents of pack(water equiv) MET mm 0 1 0 .0394 PACKF 1 1 1 1 1 2 1 0 263 ENG in 0 1 0 .0394 Frozen contents of pack (water equiv) MET mm 0 1 0 .0394 PACKW 1 1 1 1 1 2 0 264 ENG in 0 1 0 .0394 Liquid water in pack MET mm 0 1 0 .0394 PACKI 1 1 1 1 1 2 1 0 265 ENG in 0 1 0 .0394 Ice in pack (water equiv) MET mm 0 1 0 .0394 PDEPTH 1 1 1 1 1 2 0 266 ENG in 0 1 0 .0394 Pack depth MET mm 0 1 0 .0394 COVINX 1 1 1 1 1 2 0 267 ENG in 0 1 0 .0394 Snowfall cover index for complete cover MET mm 0 1 0 .0394 NEGHTS 1 1 1 1 1 2 0 268 ENG in 0 1 0 .0394 Negative heat storage of pack (water eq) MET mm 0 1 0 .0394 XLNMLT 1 1 1 1 1 2 0 269 ENG in 0 1 0 .0394 Curr max increment to ice in pack MET mm 0 1 0 .0394 RDENPF 1 1 1 1 1 2 0 270 ENG none 0 1 0 1 Rel density of frozen contents of pack MET none 0 1 0 1 SKYCLR 1 1 1 1 1 2 0 271 ENG none 0 1 0 1 Fraction of sky assumed clear MET none 0 1 0 1 SNOCOV 1 1 1 1 1 2 1 0 272 ENG none 0 1 0 1 Fraction of PLS covered by pack MET none 0 1 0 1 DULL 1 1 1 1 1 2 0 273 ENG none 0 1 0 1 Dullness index of the pack MET none 0 1 0 1 ALBEDO 1 1 1 1 1 2 0 274 ENG none 0 1 0 1 Albedo of the pack MET none 0 1 0 1 PAKTMP 1 1 1 1 1 2 0 275 ENG Deg F 0 117.8 1.8 Mean temp of the pack MET Deg C 0 117.8 1.8 DEWTMP 1 1 1 1 1 2 0 276 ENG Deg F 0 117.8 1.8 Effective dewpoint temp MET Deg C 0 117.8 1.8 SNOTMP 1 1 1 1 1 2 0 277 ENG Deg F 0 117.8 1.8 Curren max temp for precip as snowfall MET Deg C 0 117.8 1.8 SNOWF 1 1 1 1 2 2 0 314 ENG in/iv 0 1 0 .0394 Snowfall, water equivalent MET mm/iv 0 1 0 .0394 PRAIN 1 1 1 1 2 2 0 315 ENG in/iv 0 1 0 .0394 Rainfall on pack MET mm/iv 0 1 0 .0394 SNOWE 1 1 1 1 2 2 0 316 ENG in/iv 0 1 0 .0394 Evap from PACKF (sublimation) MET mm/iv 0 1 0 .0394 WYIELD 1 1 1 1 2 2 1 0 317 ENG in/iv 0 1 0 .0394 Water yielded by pack (to land-surface) MET mm/iv 0 1 0 .0394 MELT 1 1 1 1 2 2 0 318 ENG in/iv 0 1 0 .0394 Quantity of melt from PACKF(water equiv) MET mm/iv 0 1 0 .0394 RAINF 1 1 1 1 2 2 1 0 319 ENG in/iv 0 1 0 .0394 Rainfall MET mm/iv 0 1 0 .0394 PERS 1 1 1 1 1 3 0 892 ENG in 0 1 0 .0394 Total water stored in the PLS MET mm 0 1 0 .0394 CEPS 1 1 1 1 1 3 0 893 ENG in 0 1 0 .0394 Interception storage MET mm 0 1 0 .0394 SURS 1 1 1 1 1 3 1 0 894 ENG in 0 1 0 .0394 Surface (overland flow) storage MET mm 0 1 0 .0394 UZS 1 1 1 1 1 3 1 0 895 ENG in 0 1 0 .0394 Upper zone storage MET mm 0 1 0 .0394 IFWS 1 1 1 1 1 3 1 0 896 ENG in 0 1 0 .0394 Interflow storage MET mm 0 1 0 .0394 LZS 1 1 1 1 1 3 1 0 897 ENG in 0 1 0 .0394 Lower zone storage MET mm 0 1 0 .0394 AGWS 1 1 1 1 1 3 1 0 898 ENG in 0 1 0 .0394 Active groundwater storage above base elevMET mm 0 1 0 .0394 TGWS 1 1 1 1 1 3 1 0 899 ENG in 0 1 0 .0394 Total groundwater storage above datum MET mm 0 1 0 .0394 GWEL 1 1 1 1 1 3 1 0 900 ENG ft 0 12.0 0 39.4 Groundwater elevation MET m 0 12.0 0 39.4 GWVS 1 1 1 1 1 3 1 0 901 ENG in 0 1 0 .0394 Groundwater slope index MET mm 0 1 0 .0394 INFFAC 1 1 1 1 1 3 1 0 902 ENG none 0 1 0 1 Infiltration adjustment factor MET none 0 1 0 1 PETADJ 1 1 1 1 1 3 1 0 903 ENG none 0 1 0 1 Potential ET adjustment factor MET none 0 1 0 1 RPARM 1 1 1 1 2 3 0 904 ENG in/iv 0 1 0 .0394 Value of max lower zone E-T opportunity MET mm/iv 0 1 0 .0394 RZWS 1 1 1 1 1 3 0 905 ENG in 0 1 0 .0394 Root zone water storage MET mm 0 1 0 .0394 SUPY 1 1 1 1 2 3 1 0 1073 ENG in/iv 0 1 0 .0394 Moisture supply MET mm/iv 0 1 0 .0394 SURO 1 1 1 1 2 3 1 0 1074 ENG in/iv 0 1 0 .0394 Surface outflow MET mm/iv 0 1 0 .0394 IFWO 1 1 1 1 2 3 1 0 1075 ENG in/iv 0 1 0 .0394 Interflow outflow MET mm/iv 0 1 0 .0394 AGWO 1 1 1 1 2 3 1 0 1076 ENG in/iv 0 1 0 .0394 Active groundwater outflow MET mm/iv 0 1 0 .0394 PERO 1 1 1 1 2 3 1 0 1077 ENG in/iv 0 1 0 .0394 Total outflow from PLS MET mm/iv 0 1 0 .0394 IGWI 1 1 1 1 2 3 1 0 1078 ENG in/iv 0 1 0 .0394 Inflow to inactive (deep) groundwater MET mm/iv 0 1 0 .0394 PET 1 1 1 1 2 3 0 1079 ENG in/iv 0 1 0 .0394 Potential E-T MET mm/iv 0 1 0 .0394 CEPE 1 1 1 1 2 3 0 1080 ENG in/iv 0 1 0 .0394 Evap from interception storage MET mm/iv 0 1 0 .0394 SURET 1 1 1 1 2 3 0 1081 ENG in/iv 0 1 0 .0394 E-T from surface storage MET mm/iv 0 1 0 .0394 UZET 1 1 1 1 2 3 0 1082 ENG in/iv 0 1 0 .0394 E-T from upper zone MET mm/iv 0 1 0 .0394 LZET 1 1 1 1 2 3 0 1083 ENG in/iv 0 1 0 .0394 E-T from lower zone MET mm/iv 0 1 0 .0394 AGWET 1 1 1 1 2 3 0 1084 ENG in/iv 0 1 0 .0394 E-T from active groundwater storage MET mm/iv 0 1 0 .0394 BASET 1 1 1 1 2 3 0 1085 ENG in/iv 0 1 0 .0394 E-T from active groundwater outflow MET mm/iv 0 1 0 .0394 TAET 1 1 1 1 2 3 0 1086 ENG in/iv 0 1 0 .0394 Total simulated E-T MET mm/iv 0 1 0 .0394 IFWI 1 1 1 1 2 3 1 0 1087 ENG in/iv 0 1 0 .0394 Interflow inflow(excluding lateral flow) MET mm/iv 0 1 0 .0394 UZI 1 1 1 1 2 3 1 0 1088 ENG in/iv 0 1 0 .0394 Upper zone inflow MET mm/iv 0 1 0 .0394 INFIL 1 1 1 1 2 3 1 0 1089 ENG in/iv 0 1 0 .0394 Infiltration to the soil MET mm/iv 0 1 0 .0394 PERC 1 1 1 1 2 3 1 0 1090 ENG in/iv 0 1 0 .0394 Percolation from upper to lower zone MET mm/iv 0 1 0 .0394 LZI 1 1 1 1 2 3 0 1091 ENG in/iv 0 1 0 .0394 Lower zone inflow MET mm/iv 0 1 0 .0394 AGWI 1 1 1 1 2 3 1 0 1092 ENG in/iv 0 1 0 .0394 Act. groundwater inflow(no lateral flow) MET mm/iv 0 1 0 .0394 SURI 1 1 1 1 2 3 1 0 1093 ENG in/iv 0 1 0 .0394 Surface inflow(including lateral inflow) MET mm/iv 0 1 0 .0394 IRRDEM 1 1 1 1 2 3 0 1094 ENG in/iv 0 1 0 .0394 Calculated irrigation demand MET mm/iv 0 1 0 .0394 IRSHRT 1 1 1 1 2 3 0 1095 ENG in/iv 0 1 0 .0394 Irrigation shortfall MET mm/iv 0 1 0 .0394 IRDRAW 3 1 3 1 2 3 0 1096 ENG in/iv 0 1 0 .0394 Irrigation withdrawal by source MET mm/iv 0 1 0 .0394 IRRAPP 6 1 6 1 2 3 0 1099 ENG in/iv 0 1 0 .0394 Irrigation application MET mm/iv 0 1 0 .0394 DETS 1 1 1 1 1 4 0 1150 ENG tn/ac 0 1 0 .4462 Storage of detached sediment MET tne/ha 0 1 0 .4462 STCAP 1 1 1 1 1 4 0 1151 ENG tn/aciv 0 1 0 .4462 Sed. transport capacity by surf. runoff MET tne/haiv 0 1 0 .4462 COVER 1 1 1 1 1 4 0 1152 ENG none 0 1 0 1 Cover fraction for PLS MET none 0 1 0 1 WSSD 1 1 1 1 2 4 1 0 1174 ENG tn/aciv 0 1 0 .4462 Washoff of detached sediment MET tne/haiv 0 1 0 .4462 SCRSD 1 1 1 1 2 4 1 0 1175 ENG tn/aciv 0 1 0 .4462 Scour of matrix (attached) soil MET tne/haiv 0 1 0 .4462 SOSED 1 1 1 1 2 4 1 0 1176 ENG tn/aciv 0 1 0 .4462 Total removal of soil and sediment MET tne/haiv 0 1 0 .4462 DET 1 1 1 1 2 4 0 1177 ENG tn/aciv 0 1 0 .4462 Sediment detached by rainfall impact MET tne/haiv 0 1 0 .4462 NVSI 1 1 1 1 2 4 0 1178 ENG tn/aciv 0 1 0 .4462 Net vertical sediment input MET tne/haiv 0 1 0 .4462 AIRTC 1 1 1 1 2 5 0 1266 ENG Deg F -32 .555 0 1 Air temp on the PLS MET Deg C -32 .555 0 1 SLTMP 1 1 1 1 2 5 1 0 1267 ENG Deg F -32 .555 0 1 Surface layer soil temp MET Deg C -32 .555 0 1 ULTMP 1 1 1 1 2 5 1 0 1268 ENG Deg F -32 .555 0 1 Upper layer soil temp MET Deg C -32 .555 0 1 LGTMP 1 1 1 1 2 5 1 0 1269 ENG Deg F -32 .555 0 1 Lower and groundwater layer MET Deg C -32 .555 0 1 SOTMP 1 1 1 1 1 6 0 1358 ENG Deg F -32 .555 0 1 Temp of surface outflow MET Deg C -32 .555 0 1 IOTMP 1 1 1 1 1 6 0 1359 ENG Deg F -32 .555 0 1 Temp of interflow outflow MET Deg C -32 .555 0 1 AOTMP 1 1 1 1 1 6 0 1360 ENG Deg F -32 .555 0 1 Temp of active groundwater outflow MET Deg C -32 .555 0 1 SODOX 1 1 1 1 1 6 0 1361 ENG mg/l 0 1 0 1 DO conc in surface outflow MET mg/l 0 1 0 1 SOCO2 1 1 1 1 1 6 0 1362 ENG mg/l 0 1 0 1 CO2 conc in surface outflow MET mg/l 0 1 0 1 IODOX 1 1 1 1 1 6 0 1363 ENG mg/l 0 1 0 1 DO conc in interflow outflow MET mg/l 0 1 0 1 IOCO2 1 1 1 1 1 6 0 1364 ENG mg/l 0 1 0 1 CO2 conc in interflow outflow MET mg/l 0 1 0 1 AODOX 1 1 1 1 1 6 0 1365 ENG mg/l 0 1 0 1 DO conc in active groundwater outflow MET mg/l 0 1 0 1 AOCO2 1 1 1 1 1 6 0 1366 ENG mg/l 0 1 0 1 CO2 conc in active groundwater outflow MET mg/l 0 1 0 1 SOHT 1 1 1 1 2 6 0 1415 ENG BTU/aciv 0.02.455E-6 0.03.942E-6 Heat energy in surface outflow MET kcl/haiv 0.02.455E-6 0.03.942E-6 IOHT 1 1 1 1 2 6 0 1416 ENG BTU/aciv 0.02.455E-6 0.03.942E-6 Heat energy in interflow outflow MET kcl/haiv 0.02.455E-6 0.03.942E-6 AOHT 1 1 1 1 2 6 0 1417 ENG BTU/aciv 0.02.455E-6 0.03.942E-6 Heat energy in act. groundwater outflow MET kcl/haiv 0.02.455E-6 0.03.942E-6 POHT 1 1 1 1 2 6 0 1418 ENG BTU/aciv 0.02.455E-6 0.03.942E-6 Heat energy in total outflow from PLS MET kcl/haiv 0.02.455E-6 0.03.942E-6 SODOXM 1 1 1 1 2 6 0 1419 ENG lb/aciv 0 4.411 0 3.937 Flux of DO in surface outflow MET kg/haiv 0 4.411 0 3.937 SOCO2M 1 1 1 1 2 6 0 1420 ENG lb/aciv 0 4.411 0 3.937 Flux of CO2 in surface outflow MET kg/haiv 0 4.411 0 3.937 IODOXM 1 1 1 1 2 6 0 1421 ENG lb/aciv 0 4.411 0 3.937 Flux of DO in interflow outflow MET kg/haiv 0 4.411 0 3.937 IOCO2M 1 1 1 1 2 6 0 1422 ENG lb/aciv 0 4.411 0 3.937 Flux of CO2 in interflow outflow MET kg/haiv 0 4.411 0 3.937 AODOXM 1 1 1 1 2 6 0 1423 ENG lb/aciv 0 4.411 0 3.937 Flux of DO in active groundwater outflow MET kg/haiv 0 4.411 0 3.937 AOCO2M 1 1 1 1 2 6 0 1424 ENG lb/aciv 0 4.411 0 3.937 Flux of CO2 in act. groundwater outflow MET kg/haiv 0 4.411 0 3.937 PODOXM 1 1 1 1 2 6 0 1425 ENG lb/aciv 0 4.411 0 3.937 DO in total outflow from PLS MET kg/haiv 0 4.411 0 3.937 POCO2M 1 1 1 1 2 6 0 1426 ENG lb/aciv 0 4.411 0 3.937 CO2 in total outflow from PLS MET kg/haiv 0 4.411 0 3.937 SQO 7 1 -1569 1 1 7 0 2832 ENG qty/ac 0 1 0 .4047 Storage of QUALOF on the surface MET qty/ha 0 1 0 .4047 SOQSP 7 1 -1568 1 1 7 0 2842 ENG qty/ton 0 1 0 .9072 Pot factor of QUALSD on sediment outflow MET qty/tonn 0 1 0 .9072 IOQC 7 1 -1570 1 1 7 0 2852 ENG qty/ft3 0 3630. 0 102833. Conc of QUALIF in interflow outflow MET qty/l 0 3630. 0 102833. AOQC 7 1 -1571 1 1 7 0 2862 ENG qty/ft3 0 3630. 0 102833. Conc of QUALGW in interflow outflow MET qty/l 0 3630. 0 102833. WASHQS 7 1 -1568 1 2 7 0 3302 ENG qty/aciv 0 1 0 .4047 Removal of QUALSD with det. sed washoff MET qty/haiv 0 1 0 .4047 SCRQS 7 1 -1568 1 2 7 0 3312 ENG qty/aciv 0 1 0 .4047 Removal of QUALSD with matrix soil scour MET qty/haiv 0 1 0 .4047 SOQS 7 1 -1568 1 2 7 0 3322 ENG qty/aciv 0 1 0 .4047 Total outflow of QUALSD from surface MET qty/aciv 0 1 0 .4047 SOQO 7 1 -1569 1 2 7 0 3332 ENG qty/aciv 0 1 0 .4047 Washoff of QUALOF from surface MET qty/haiv 0 1 0 .4047 SOQOC 7 1 -1569 1 2 7 0 3342 ENG qty/ft3 0 3630. 0 102833. Conc of QUALOF in surface outflow MET qty/l 0 3630. 0 102833. SOQUAL 10 1 -1567 1 2 7 0 3352 ENG qty/aciv 0 1 0 .4047 Total outflow of QUAL from the surface MET qty/haiv 0 1 0 .4047 SOQC 10 1 -1567 1 2 7 0 3362 ENG qty/ft3 0 3630. 0 102833. Conc of QUAL in surface outflow MET qty/l 0 3630. 0 102833. IOQUAL 7 1 -1570 1 2 7 0 3372 ENG qty/aciv 0 1 0 .4047 Outflow of QUALIF in interflow MET qty/haiv 0 1 0 .4047 AOQUAL 7 1 -1571 1 2 7 0 3382 ENG qty/aciv 0 1 0 .4047 Outflow of QUALGW in baseflow MET qty/haiv 0 1 0 .4047 POQUAL 10 1 -1567 1 2 7 0 3392 ENG qty/aciv 0 1 0 .4047 Total flux of QUAL from the PLS MET qty/haiv 0 1 0 .4047 POQC 10 1 -1567 1 2 7 0 3402 ENG qty/ft3 0 3630. 0 102833. Conc of QUAL in total outflow from PLS MET qty/l 0 3630. 0 102833. PQADDR 10 1 -1567 1 2 7 0 3412 ENG qty/aciv 0 1 0 .4047 Dry atmospheric deposition flux to PLS MET qty/haiv 0 1 0 .4047 PQADWT 10 1 -1567 1 2 7 0 3422 ENG qty/aciv 0 1 0 .4047 Wet atmospheric deposition flux to PLS MET qty/haiv 0 1 0 .4047 PQADEP 10 1 -1567 1 2 7 0 3432 ENG qty/aciv 0 1 0 .4047 Total atmospheric deposition flux to PLS MET qty/haiv 0 1 0 .4047 ISQO 10 1 -1567 1 2 7 0 3442 ENG qty/aciv 0 1 0 .4047 Total input flux if QUALOF to PLS MET qty/haiv 0 1 0 .4047 MST 5 1 5 1 1 8 1 0 3469 ENG lb/ac 0 1 0 .892 Water storages by zone MET kg/ha 0 1.12 0 1 FRAC 8 1 8 1 1 8 0 3474 ENG /ivl 0 1 0 1 Fractional fluxes thru soil MET /ivl 0 1 0 1 SPS 3 3 3 -3626 1 9 0 4109 ENG lb/ac 0 1 0 .892 Amt. of pestic. in surface storage MET kg/ha 0 1.12 0 1 UPS 3 3 3 -3626 1 9 0 4118 ENG lb/ac 0 1 0 .892 Amt. of pestic. in upper princ. storage MET kg/ha 0 1.12 0 1 IPS 3 1 -3626 1 1 9 0 4127 ENG lb/ac 0 1 0 .892 Amt. of pestic. in upper auxil storage MET kg/ha 0 1.12 0 1 LPS 3 3 3 -3626 1 9 0 4130 ENG lb/ac 0 1 0 .892 Amt. of pestic. in lower layer storage MET kg/ha 0 1.12 0 1 APS 3 3 3 -3626 1 9 0 4139 ENG lb/ac 0 1 0 .892 Amt of pest. in act. groundwater storage MET kg/ha 0 1.12 0 1 TPS 3 3 3 -3626 1 9 0 4148 ENG lb/ac 0 1 0 .892 Total amount of pesticide in the soil MET kg/ha 0 1.12 0 1 TPST 5 3 5 -3626 1 9 0 4157 ENG lb/ac 0 1 0 .892 Total amount of pesticide in each layer MET kg/ha 0 1.12 0 1 TOTPST 3 1 -3626 1 1 9 0 4172 ENG lb/ac 0 1 0 .892 Total amount of pesticide in the soil MET kg/ha 0 1.12 0 1 SDPS 2 3 2 -3626 2 9 0 4511 ENG lb/aciv 0 1 0 .892 Outflow of sediment-associated pesticide MET kg/haiv 0 1.12 0 1 TSPSS 5 3 5 -3626 2 9 0 4517 ENG lb/aciv 0 1 0 .892 Fluxes of soln pest. for topsoil layers MET kg/haiv 0 1.12 0 1 SSPSS 3 3 3 -3626 2 9 0 4532 ENG lb/aciv 0 1 0 .892 Fluxes of soln pest. for subsoil layers MET kg/haiv 0 1.12 0 1 SDEGPS 3 1 -3626 1 2 9 0 4541 ENG lb/aciv 0 1 0 .892 Amount of degradation in surf. layer MET kg/haiv 0 1.12 0 1 UDEGPS 3 1 -3626 1 2 9 0 4544 ENG lb/aciv 0 1 0 .892 Amount of degradation in upper layer MET kg/haiv 0 1.12 0 1 LDEGPS 3 1 -3626 1 2 9 0 4547 ENG lb/aciv 0 1 0 .892 Amount of degradation in lower layer MET kg/haiv 0 1.12 0 1 ADEGPS 3 1 -3626 1 2 9 0 4550 ENG lb/aciv 0 1 0 .892 Amount of degr. in groundw. layer MET kg/haiv 0 1.12 0 1 TDEGPS 3 1 -3626 1 2 9 0 4553 ENG lb/aciv 0 1 0 .892 Total amount of degradation in soil MET kg/haiv 0 1.12 0 1 SOSDPS 3 1 -3626 1 2 9 0 4556 ENG lb/aciv 0 1 0 .892 Total outflow of sed-assoc. pesticide MET kg/haiv 0 1.12 0 1 SOPEST 3 1 -3626 1 2 9 0 4559 ENG lb/aciv 0 1 0 .892 Total surface outflow of pesticide MET kg/haiv 0 1.12 0 1 POPST 3 1 -3626 1 2 9 0 4562 ENG lb/aciv 0 1 0 .892 Total outflow of sol. pestic. from PLS MET kg/haiv 0 1.12 0 1 TOPST 3 1 -3626 1 2 9 0 4565 ENG lb/aciv 0 1 0 .892 Total outflow of pest. from PLS MET kg/haiv 0 1.12 0 1 PEADDR 3 3 -3626 3 2 9 0 4568 ENG lb/aciv 0 1 0 .892 Dry atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 PEADWT 3 3 -3626 3 2 9 0 4577 ENG lb/aciv 0 1 0 .892 Wet atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 PEADEP 3 3 -3626 3 2 9 0 4586 ENG lb/aciv 0 1 0 .892 Total atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 NITIF 4 1 4 1 2 10 0 4615 ENG lb/ac 0 1 0 .892 Special Action inflow of nitrogen species MET kg/ha 0 1.12 0 1 AGPLTN 1 1 1 1 1 10 0 5636 ENG lb/ac 0 1 0 .892 N in above-ground plant storage MET kg/ha 0 1.12 0 1 LITTRN 1 1 1 1 1 10 0 5637 ENG lb/ac 0 1 0 .892 N in litter storage MET kg/ha 0 1.12 0 1 SN 8 1 8 1 1 10 0 5638 ENG lb/ac 0 1 0 .892 N in surface layer storage MET kg/ha 0 1.12 0 1 UN 8 1 8 1 1 10 0 5646 ENG lb/ac 0 1 0 .892 N in upper layer princ storage MET kg/ha 0 1.12 0 1 IN 4 1 4 1 1 10 0 5654 ENG lb/ac 0 1 0 .892 N in upper auxil layer storage MET kg/ha 0 1.12 0 1 LN 8 1 8 1 1 10 0 5658 ENG lb/ac 0 1 0 .892 N in lower layer storage MET kg/ha 0 1.12 0 1 AN 8 1 8 1 1 10 0 5666 ENG lb/ac 0 1 0 .892 N in groundwater layer storage MET kg/ha 0 1.12 0 1 TN 8 1 8 1 1 10 0 5674 ENG lb/ac 0 1 0 .892 Total N in soil, by species MET kg/ha 0 1.12 0 1 TNIT 5 1 5 1 1 10 0 5682 ENG lb/ac 0 1 0 .892 Total N stored in each layer (all species)MET kg/ha 0 1.12 0 1 TOTNIT 1 1 1 1 1 10 0 5687 ENG lb/ac 0 1 0 .892 Total N stored in the PLS (all species) MET kg/ha 0 1.12 0 1 NDFCT 5 1 5 1 1 10 0 5688 ENG lb/ac 0 1 0 .892 Plant uptake deficit by layer, and total MET kg/ha 0 1.12 0 1 NUPTG 4 1 4 1 2 10 0 5726 ENG lb/aciv 0 1 0 .892 Plant uptake target by layer MET kg/haiv 0 1.12 0 1 SEDN 3 1 3 1 2 10 0 6433 ENG lb/aciv 0 1 0 .892 Outflows of sediment-associated N MET kg/haiv 0 1.12 0 1 TSAMS 5 1 5 1 2 10 0 6436 ENG lb/aciv 0 1 0 .892 Fluxes of soln ammon in the topsoil MET kg/haiv 0 1.12 0 1 SSAMS 3 1 3 1 2 10 0 6441 ENG lb/aciv 0 1 0 .892 Fluxes of soln ammon in the subsoil MET kg/haiv 0 1.12 0 1 TSNO3 5 1 5 1 2 10 0 6444 ENG lb/aciv 0 1 0 .892 Fluxes of nitrate in the topsoil MET kg/haiv 0 1.12 0 1 SSNO3 3 1 3 1 2 10 0 6449 ENG lb/aciv 0 1 0 .892 Fluxes of nitrate in the subsoil MET kg/haiv 0 1.12 0 1 DENIF 5 1 5 1 2 10 0 6452 ENG lb/aciv 0 1 0 .892 Denitrification by layer & total MET kg/haiv 0 1.12 0 1 TDENIF 1 1 1 1 2 10 0 6457 ENG lb/aciv 0 1 0 .892 Total denitrification in the PLS MET kg/haiv 0 1.12 0 1 AMNIT 5 1 5 1 2 10 0 6458 ENG lb/aciv 0 1 0 .892 Ammonia nitrification by layer & total MET kg/haiv 0 1.12 0 1 AMIMB 5 1 5 1 2 10 0 6463 ENG lb/aciv 0 1 0 .892 Ammonia immobilization by layer & total MET kg/haiv 0 1.12 0 1 ORNMN 5 1 5 1 2 10 0 6468 ENG lb/aciv 0 1 0 .892 Organic N mineralization by layer & total MET kg/haiv 0 1.12 0 1 NIADDR 3 2 3 2 2 10 0 6473 ENG lb/aciv 0 1 0 .892 Dry atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 NIADWT 3 2 3 2 2 10 0 6479 ENG lb/aciv 0 1 0 .892 Wet atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 NIADEP 3 2 3 2 2 10 0 6485 ENG lb/aciv 0 1 0 .892 Total atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 NFIXFX 5 1 5 1 2 10 0 6491 ENG lb/aciv 0 1 0 .892 Nitrogen fixation (4 layers and total) MET kg/haiv 0 1.12 0 1 TSSLN 5 1 5 1 2 10 0 6496 ENG lb/aciv 0 1 0 .892 Fluxes of soln labile ORGN in the topsoil MET kg/haiv 0 1.12 0 1 SSSLN 3 1 3 1 2 10 0 6501 ENG lb/aciv 0 1 0 .892 Fluxes of soln labile ORGN in the subsoil MET kg/haiv 0 1.12 0 1 TSSRN 5 1 5 1 2 10 0 6504 ENG lb/aciv 0 1 0 .892 Fluxes of soln refrac ORGN in the topsoil MET kg/haiv 0 1.12 0 1 SSSRN 3 1 3 1 2 10 0 6509 ENG lb/aciv 0 1 0 .892 Fluxes of soln refrac ORGN in the subsoil MET kg/haiv 0 1.12 0 1 NIIMB 5 1 5 1 2 10 0 6512 ENG lb/aciv 0 1 0 .892 Nitrate immobilization by layer & total MET kg/haiv 0 1.12 0 1 AMVOL 5 1 5 1 2 10 0 6517 ENG lb/aciv 0 1 0 .892 Ammonia volatilization by layer & total MET kg/haiv 0 1.12 0 1 REFRON 5 1 5 1 2 10 0 6522 ENG lb/aciv 0 1 0 .892 Refractory N conversion by layer & total MET kg/haiv 0 1.12 0 1 NIUPA 5 1 5 1 2 10 0 6527 ENG lb/aciv 0 1 0 .892 Above-ground NO3 uptake by layer & total MET kg/haiv 0 1.12 0 1 AMUPA 5 1 5 1 2 10 0 6532 ENG lb/aciv 0 1 0 .892 Above-ground NH3 uptake by layer & total MET kg/haiv 0 1.12 0 1 NIUPB 5 1 5 1 2 10 0 6537 ENG lb/aciv 0 1 0 .892 Below-ground NO3 uptake by layer & total MET kg/haiv 0 1.12 0 1 AMUPB 5 1 5 1 2 10 0 6542 ENG lb/aciv 0 1 0 .892 Below-ground NH3 uptake by layer & total MET kg/haiv 0 1.12 0 1 RETAGN 1 1 1 1 2 10 0 6547 ENG lb/aciv 0 1 0 .892 Above-ground plant N return to litter MET kg/haiv 0 1.12 0 1 RTLLN 3 1 3 1 2 10 0 6548 ENG lb/aciv 0 1 0 .892 Litter return to labile by layer & total MET kg/haiv 0 1.12 0 1 RTRLN 3 1 3 1 2 10 0 6551 ENG lb/aciv 0 1 0 .892 Litter return to refrac by layer & total MET kg/haiv 0 1.12 0 1 RTLBN 5 1 5 1 2 10 0 6554 ENG lb/aciv 0 1 0 .892 Plant N return to labile by layer & total MET kg/haiv 0 1.12 0 1 RTRBN 5 1 5 1 2 10 0 6559 ENG lb/aciv 0 1 0 .892 Plant N return to refrac by layer & total MET kg/haiv 0 1.12 0 1 SOSEDN 1 1 1 1 2 10 0 6564 ENG lb/aciv 0 1 0 .892 Outflow of sed-assoc N (orgN + ads NH3) MET kg/haiv 0 1.12 0 1 PONO3 1 1 1 1 2 10 0 6565 ENG lb/aciv 0 1 0 .892 Total outflow of NO3 from the PLS MET kg/haiv 0 1.12 0 1 PONH4 1 1 1 1 2 10 0 6566 ENG lb/aciv 0 1 0 .892 Total outflow of NH4 from the PLS MET kg/haiv 0 1.12 0 1 POORN 1 1 1 1 2 10 0 6567 ENG lb/aciv 0 1 0 .892 Total outflow of ORG N from the PLS MET kg/haiv 0 1.12 0 1 PONITR 1 1 1 1 2 10 0 6568 ENG lb/aciv 0 1 0 .892 Tot outflow of N (NO3+NH4+ORGN) from PLS MET kg/haiv 0 1.12 0 1 PHOIF 3 1 3 1 2 11 0 6584 ENG lb/ac 0 1 0 .892 Special Action inflow of phosphorus spec. MET kg/ha 0 1.12 0 1 SP 4 1 4 1 1 11 0 6941 ENG lb/ac 0 1 0 .892 P in surface layer storage MET kg/ha 0 1.12 0 1 UP 4 1 4 1 1 11 0 6945 ENG lb/ac 0 1 0 .892 P in upper layer princ storage MET kg/ha 0 1.12 0 1 IP 1 1 1 1 1 11 0 6949 ENG lb/ac 0 1 0 .892 P in upper layer auxil storage MET kg/ha 0 1.12 0 1 LP 4 1 4 1 1 11 0 6950 ENG lb/ac 0 1 0 .892 P in lower layer storage MET kg/ha 0 1.12 0 1 AP 4 1 4 1 1 11 0 6954 ENG lb/ac 0 1 0 .892 P in groundwater layer storage MET kg/ha 0 1.12 0 1 TP 4 1 4 1 1 11 0 6958 ENG lb/ac 0 1 0 .892 Total P in soil, by species MET kg/ha 0 1.12 0 1 TPHO 5 1 5 1 1 11 0 6962 ENG lb/ac 0 1 0 .892 Total P stored in each layer (all species)MET kg/ha 0 1.12 0 1 TOTPHO 1 1 1 1 1 11 0 6967 ENG lb/ac 0 1 0 .892 Total P stored in the PLS (all species) MET kg/ha 0 1.12 0 1 PDFCT 5 1 5 1 1 11 0 6968 ENG lb/ac 0 1 0 .892 Plant uptake deficit by layer, and total MET kg/ha 0 1.12 0 1 PUPTG 4 1 4 1 2 11 0 6981 ENG lb/aciv 0 1 0 .892 Plant uptake target by layer MET kg/haiv 0 1.12 0 1 SEDP 2 1 2 1 2 11 0 7155 ENG lb/aciv 0 1 0 .892 Outflows of sediment-associated P MET kg/haiv 0 1.12 0 1 TSP4S 5 1 5 1 2 11 0 7157 ENG lb/aciv 0 1 0 .892 Fluxes of soln phosphate in the topsoil MET kg/haiv 0 1.12 0 1 SSP4S 3 1 3 1 2 11 0 7162 ENG lb/aciv 0 1 0 .892 Fluxes of soln phosphate in the subsoil MET kg/haiv 0 1.12 0 1 P4IMB 5 1 5 1 2 11 0 7165 ENG lb/aciv 0 1 0 .892 PO4 immobilization flux (each layer & tot)MET kg/haiv 0 1.12 0 1 ORPMN 5 1 5 1 2 11 0 7170 ENG lb/aciv 0 1 0 .892 ORP mineralization flux (each layer & tot)MET kg/haiv 0 1.12 0 1 SOSEDP 1 1 1 1 2 11 0 7175 ENG lb/aciv 0 1 0 .892 Outflow of sed-assoc P (orgP + ads PO4) MET kg/haiv 0 1.12 0 1 POPHOS 1 1 1 1 2 11 0 7176 ENG lb/aciv 0 1 0 .892 Total outflow of P from the PLS. MET kg/haiv 0 1.12 0 1 PHADDR 2 2 2 2 2 11 0 7177 ENG lb/aciv 0 1 0 .892 Dry atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 PHADWT 2 2 2 2 2 11 0 7181 ENG lb/aciv 0 1 0 .892 Wet atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 PHADEP 2 2 2 2 2 11 0 7185 ENG lb/aciv 0 1 0 .892 Total atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 STRSU 1 1 1 1 1 12 0 7291 ENG lb/ac 0 1 0 .892 Tracer in surface layer storage MET kg/ha 0 1.12 0 1 UTRSU 1 1 1 1 1 12 0 7292 ENG lb/ac 0 1 0 .892 Tracer in upper layer princ storage MET kg/ha 0 1.12 0 1 ITRSU 1 1 1 1 1 12 0 7293 ENG lb/ac 0 1 0 .892 Tracer in upper layer auxil storage MET kg/ha 0 1.12 0 1 LTRSU 1 1 1 1 1 12 0 7294 ENG lb/ac 0 1 0 .892 Tracer in lower layer storage MET kg/ha 0 1.12 0 1 ATRSU 1 1 1 1 1 12 0 7295 ENG lb/ac 0 1 0 .892 Tracer in groundwater layer storage MET kg/ha 0 1.12 0 1 TRSU 1 1 1 1 1 12 0 7296 ENG lb/ac 0 1 0 .892 Total tracer stored in the PLS MET kg/ha 0 1.12 0 1 TSTRS 5 1 5 1 2 12 0 7360 ENG lb/aciv 0 1 0 .892 Fluxes of tracer in topsoil MET kg/haiv 0 1.12 0 1 SSTRS 3 1 3 1 2 12 0 7365 ENG lb/aciv 0 1 0 .892 Fluxes of tracer in subsoil MET kg/haiv 0 1.12 0 1 POTRS 1 1 1 1 2 12 0 7368 ENG lb/aciv 0 1 0 .892 Total outflow of tracer from the PLS MET kg/haiv 0 1.12 0 1 TRADDR 2 1 2 1 2 12 0 7369 ENG lb/aciv 0 1 0 .892 Dry atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 TRADWT 2 1 2 1 2 12 0 7371 ENG lb/aciv 0 1 0 .892 Wet atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 TRADEP 2 1 2 1 2 12 0 7373 ENG lb/aciv 0 1 0 .892 Total atmospheric deposition to PLS MET kg/haiv 0 1.12 0 1 of FILES block   FILES block not found   End of FILES block not found t-  INTERPRETATION OF RUN DATA SET COMPLETE T  EXECUTION WILL NOT BE ATTEMPTED BECAUSE ONE OR MORE ERRORS HAVE BEEN DETECTED. R  EXECUTION WILL NOT BE ATTEMPTED BECAUSE RUN=0 WAS SPECIFIED IN GLOBAL BLOCK.  RUN 1 1  GLOBAL 1 2OPN SEQUENCE 1 3FTABLES 1 4EXT SOURCES 1 5FORMATS 1 6NETWORK 1 7EXT TARGETS 1 8SPEC-ACTIONS 1 9SCHEMATIC 1 10MASS-LINK 1 11PERLND 1 100IMPLND 1 100RCHRES 1 100COPY 1 100PLTGEN 1 100DISPLY 1 100DURANL 1 100GENER 1 100MUTSIN 1 100BMPRAC 1 100REPORT 1 100FILES 1 12CATEGORY 1 13MONTH-DATA 1 14PATHNAMES 1 15 M  1 2 3 4 5 6 10 12 15 20 30 60 120 180 240 360 480 7201440  ==================================================================================================================================== PROCESSING & BLOCK  FINISHED PROCESSING & BLOCK ====================================================================================================================================  20 1 1 5 The OPN-SEQUENCE block refers to operation &CCCCCCC &I , but no input block was provided for this operation type. This input block must be present. J  Beginning HSPF simulation. Looking for FILES block in file: & $  Reading user's control input file.  HSPF simulation completed.6  Processing RUN data set complete - RUNFG=0 in GLOBAL 4  Processing RUN data set complete - ERRORS in input*  No RUN data set found - review UCI file. &  Error in FILES block - Return code & (  Error opening UCI file - Return code &3  Processing a RUN data set from user's input file. 2  Operations supervisor calling operating modules. ?  Found end of FILES block but never found start [ $!20000309112930 20000309112930 HTSSUT   20 1 1 5&D FILE: &I Debug error: STTRAN is not valid in xvinit subroutine. Relevant data: STTRAN COMP# DSNO &I &I &I @ STTRAN is code for source to target transformation DSNO is dataset number COMP# is number of current component to transfer $!20000309112930 20000309112930 HTSINSI   5 1 1 5 The entries in the EXT SOURCES, NETWORK, EXT TARGETS & SCHEMATIC blocks imply an INPAD with more rows than can be handled in this release of HSPF. Thus, operations should be grouped into smaller ingroups. The max no. of rows that can be handled is &I . }  20 1 1 5 A sequential source file can go to only one target. Unit # &I &I r  20 1 1 5 A tss dataset target may only have one source. Dataset &I &I Time Series File produced by PLTGEN (TYPEFG = 2) may contain only mean-valued timeseries. The user has specified &I point-valued timeseries.  20 1 1 5 A Point Time Series File produced by PLTGEN (TYPEFG = 3) may contain only point-valued timeseries. The user has specified &I mean-valued timeseries.  20 1 1 5 A Point Time Series File produced by PLTGEN (TYPEFG = 3) may contain only one point-valued timeseries. The user has specified &I . s $!20000607144819 20000607144819 HUTOPINP  [+Z! SUM AVER MAX MIN LAST 0  20 1 1 5 An invalid transformation (aggregation) functional was specified in the user's control input. The valid values are SUM, AVER, MAX, MIN and LAST. The value supplied is '&CCC'. Was it mis-spelled or placed in the wrong columns?   (' ',I6,F12.bbbb,6X, 12F8.bbbb,/, (' ',24X, 12F8.bbbb))(' ',I5,':',F12.bbbb,6X, 12F8.bbbb,/, (' ',24X, 12F8.bbbb)) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC(' ',I6,3X ,F8.bbbb,A8 )(/,2X,A4,4XHOUR DAY MONTH  20 1 1 5 The interval of the data in a short-span display (pdelt= delt*pivl mins) must divide exactly into a day (1440 mins). For disply operation &I , this is not the case since the value of pdelt is &I .  20 1 1 5 The total number of timeseries to be input is incorrect. The value is &I , but it must be between 0 and 20.  20 1 1 5 The maximum total number of curves (point plus mean) that may be output to a flat-format PLTGEN file (TYPEFG = 1) is 20. The user has asked for &I . SUM AVER MAX MIN LAST  20 1 1 5 An invalid transformation (aggregation) functional was specified in the user's control input. The valid values are SUM, AVER, MAX, MIN and LAST. The value supplied was '&CCC'. Was it mis-spelled or placed in the wrong columns?  20 1 1 5 A Diffuse y0.0!CTRBQ1 CTRBQ1 AFIELD4 aPyy1.0!CTRBQ2 CTRBQ2 BFIELD5 bPy0.0"CKTRB1 CKTRB1 BFIELD6 bPyy1.0"CKTRB2 CKTRB2 AOptional benthic algae light extinction parameters for SDLTFG=2. X (1X,4(1PE10.3)) CTRBQ1 CTRBQ2 CKTRB1 CKTRB2 (NTU/cfs) (/ft)\ RCHRES CTRBQ1 CTRBQ2 CKTRB1 CKTRB2 x - x NTU/cms /m BENAL-LIGHT@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0.0!CTRBQ1 CTRBQ1 AFIELD4 aPyy1.0!CTRBQ2 CTRBQ2 BFIELD5 bPy0.0"CKTRB1 CKTRB1 BFIELD6 bPyy1.0"CKTRB2 CKTRB2 AOptional benthic algae light extinction parameters for SDLTFG=2. X (1X,4(1PE10.3)) CTRBQ1 CTRBQ2 CKTRB1 CKTRB2 (NTU/cms) (/m)z RCHRES FRRIF CMMV RIFCQ1 RIFCQ2 RIFCQ3 x - x ft/s cfs cfs cfs BENAL-RIFF1@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP #<?1.0]!FRRIF is the fraction of the reach that is composed of riffleswhere benthic algae can grow. FRRIF AFIELD4 aP75y1.0q!CMMV is the Michaelis-Menton half-saturation constant forriffle velocity in the nutrient availability equation. CMMV BFIELD5 bPy0. O"RIFCQ1 is the first critical flow level for rifflevelocity and average depth. RIFCQ1 BFIELD6 bPy0. P"RIFCQ2 is the second critical flow level for rifflevelocity and average depth.RIFCQ2 CFIELD7 cPy0. O#RIFCQ3 is the third critical flow level for rifflevelocity and average depth. RIFCQ3 4First group of riffle parameters for benthic algae. BALFG=2. BALR20 AFIELD4 aP?@1.07 l!TCBALR is the temperature correction coefficient forrespiration for each benthic algae species if BALFG=2.TCBALR BFIELD5 bP75y0.10 i"CSLOF1 is the coefficient in the benthic algae scour equationfor each benthic algae species if BALFG=2. CSLOF1 BFIELD6 bP75@1.0"CSLOF2 is the coefficient for velocity in the exponent in thebenthic algae scour equation for each benthic algae speciesif BALFG=2. CSLOF2 CFIELD7 cP?0.075 #GRORES is the fraction of photorespiration required to supportgrowth and photosynthesis for each benthic algae species if BALFG=2.GRORES ASpecies-specific benthic algae respiration and scour parameters. b (1X,5(1PE10.3)) BALR20 TCBALR CSLOF1 CSLOF2 GRORES (/hr) (/hr) \ RCHRES CREMVL CMMBI BINV TCGRAZ x - x mgA/mgI/yr mgA/m2 mgI/m2 BENAL-GRAZE@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP75y0.05 <!CREMVL is the coefficient for grazing rate by invertebratesCREMVL AFIELD4 aP75y0.05 T!CMMBI is the Michaelis-Menton half-saturation constant forgrazing by invertebratesCMMBI BFIELD5 bPy0.0Y"BINV is the constant value of biomass of grazing invertebratesin the reach if BINVFG=2. BINV BFIELD6 bP?@1.0F"TCGRAZ is the temperature correction factor for invertebrategrazing. TCGRAZ +Optional benthic algae grazing parameters. Y (1X,4(1PE10.3)) CREMVL CMMBI BINV TCGRAZ(mgA/mgI/yr) (mgA/m2) (mgI/m2) \ RCHRES CTRBQ1 CTRBQ2 CKTRB1 CKTRB2 x - x NTU/cfs /ft BENAL-LIGHT@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPaturation constant fordensity-limited growth for each species if BALFG=2. CMMD2 DFIELD9 dP75y250. A$CSLIT is the saturation light level for each species if BALFG=2. CSLIT 2Species-specific benthic algae growth parameters. (1X,7(1PE10.3)) MBALGR TCBALG CMMNB CMMPB CMMD1 CMMD2 CSLIT (/hr) (mg/l) (mg/l) (mg/m2) (ly/min) f RCHRES BALR20 TCBALR CSLOF1 CSLOF2 GRORES x - x /hr /hr BENAL-RESSCR @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP75y0.004 R!BALR20 is the benthic algae respiration rate at 20 C foreach species if BALFG=2. BALR20 AFIELD4 aP?@1.07 l!TCBALR is the temperature correction coefficient forrespiration for each benthic algae species if BALFG=2.TCBALR BFIELD5 bP75y0.0007 i"CSLOF1 is the coefficient in the benthic algae scour equationfor each benthic algae species if BALFG=2. CSLOF1 BFIELD6 bP75 A0.0007 "CSLOF2 is the coefficient for velocity in the exponent in thebenthic algae scour equation for each benthic algae speciesif BALFG=2. CSLOF2 CFIELD7 cP?0.075 #GRORES is the fraction of photorespiration required to supportgrowth and photosynthesis for each benthic algae species if BALFG=2.GRORES ASpecies-specific benthic algae respiration and scour parameters. b (1X,5(1PE10.3)) BALR20 TCBALR CSLOF1 CSLOF2 GRORES (/hr) (/hr) e RCHRES BALR20 TCBALR CSLOF1 CSLOF2 GRORES x - x /hr /hr BENAL-RESSCR @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP75y0.004 R!BALR20 is the benthic algae respiration rate at 20 C foreach species ifgae species fixes nitrogen, so that growth is notnitrogen limited BFIXFG1BFIELD5 b(0 |"BFIXFG2: Value of 1 specifies that the second benthicalgae species fixes nitrogen, so that growth is notnitrogen limitedBFIXFG2CFIELD6 c(0 {#BFIXFG3: Value of 1 specifies that the third benthicalgae species fixes nitrogen, so that growth is notnitrogen limited BFIXFG3CFIELD7 c(0 |#BFIXFG4: Value of 1 specifies that the fourth benthicalgae species fixes nitrogen, so that growth is notnitrogen limitedBFIXFG4;Benthic algae flags - used only when BALFG=2 in PLNK-FLAGS H (1X,6I10) NUMBAL BINVFG BFIXFG1 BFIXFG2 BFIXFG3 BFIXFG4 RCHRES MBALGR TCBALG CMMNB CMMPB CMMD1 CMMD2 CSLIT x - x /hr mg/l mg/l mg/m2 ly/min BENAL-GROW @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP75y0.3R!MBALGR is the maximum benthic algae base growth rate foreach species if BALFG=2. MBALGR AFIELD4 aP?@1.07 g!TCBALG is the temperature correction coefficient forgrowth for each benthic algae species if BALFG=2. TCBALG BFIELD5 bPy0.045 "CMMNB is the Michaelis-Menton half-saturation constant fornitrogen-limited growth for each species if BALFG=2. Ifthe value is zero, then growth is not limited (i.e. thisspecies fixes nitrogen). CMMNB BFIELD6 bP75y0.015 r"CMMPB is the Michaelis-Menton half-saturation constant forphosphorus-limited growth for each species if BALFG=2. CMMPB CFIELD7 cP75y0.1|#CMMD1 is the coefficient for total benthic algae densityin the density-limited growth equation for each speciesif BALFG=2CMMD1 CFIELD8 cP75y100.0 o#CMMD2 is the Michaelis-Menton half-sARM6 ACPARM7 X RCHRES ACCONC1 ACCONC2 ACCONC3 ACCONC4 ACCONC5 ACCONC6 ACCONC7 x - x ACID-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aPy0.000 L!ACCONC(*) are the initial concentrations for the acid minedrainage module. ACCONC(1) AFIELD4 aPy0.000 L!ACCONC(*) are the initial concentrations for the acid minedrainage module. ACCONC(2) BFIELD5 bPy0.000 L"ACCONC(*) are the initial concentrations for the acid minedrainage module. ACCONC(3) BFIELD6 bPy0.000 L"ACCONC(*) are the initial concentrations for the acid minedrainage module. ACCONC(4) CFIELD7 cPy0.000 L#ACCONC(*) are the initial concentrations for the acid minedrainage module. ACCONC(5) CFIELD8 cPy0.000 L#ACCONC(*) are the initial concentrations for the acid minedrainage module. ACCONC(6) DFIELD9 dPy0.000 L$ACCONC(*) are the initial concentrations for the acid minedrainage module. ACCONC(7) Acid mine initial values (1X,7(1PE10.3)) ACCONC1 ACCONC2 ACCONC3 ACCONC4 ACCONC5 ACCONC6 ACCONC7 (mole/l) (mole/l) (mole/l) (mole/l) (mole/l) (mole/l) (mole/l) H RCHRES Benthic algae flags x - x NUMB BINV NFX1 NFX2 NFX3 NFX4 BENAL-FLAGS@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(0 S!NUMBAL is the number of benthic algae species simulatedwhen BALFG=2 in PLNK-FLAGS NUMBAL AFIELD4 a(1 !BINVFG indicates the source of benthal invertebrate data; 1means a time series (either input or computed), 2 means aconstant value, and 3 means twelve monthly values. BINVFG BFIELD4 b(0 {"BFIXFG1: Value of 1 specifies that the first benthicalule. ACFLAG(10) FFIELD13f(d0 5&ACFLAG(*) are option flags for the acid mine module. ACFLAG(11) FFIELD14f(d0 5&ACFLAG(*) are option flags for the acid mine module. ACFLAG(12) GFIELD15g(d0 5'ACFLAG(*) are option flags for the acid mine module. ACFLAG(13) GFIELD16g(d0 5'ACFLAG(*) are option flags for the acid mine module. ACFLAG(14) Acid mine flagsQ (1X,14I5) AC01 AC02 AC03 AC04 AC05 AC06 AC07 AC08 AC09 AC10 AC11 AC12 AC13 AC14 X RCHRES ACPARM1 ACPARM2 ACPARM3 ACPARM4 ACPARM5 ACPARM6 ACPARM7 x - x ACID-PARMS @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP8 A1.0!ACPARM(1) is the ratio of actual CO2 concentration in the RCHRES to thevalue that would occur in equilibrium with the atmosphere. ACPARM(1) AFIELD4 aP.T6.5E-32b!ACPARM(2) is the user specified Gibbsite solubility product;this value is used if ACFLAG(2) = 5. ACPARM(2) BFIELD5 bPTC-1.0 `"ACPARM(3) is a constant value of water temperature to beused by the acid mine drainage module. ACPARM(3) BFIELD6 bP??0.95 p"ACPARM(4) is the coefficient to predict the removal efficiency forprecipitated metals; used when ACFLAG(2)= 4. ACPARM(4) CFIELD7 cP?@@2.50 #ACPARM(5) is the coefficient that adjusts the remaining metal concentrationthat resists precipitation; used when ACFLAG(2)= 4. ACPARM(5) CFIELD8 cPy0.000 <#ACPARM(*) are parameters for the acid mine drainage module. ACPARM(6) DFIELD9 dPy0.000 <$ACPARM(*) are parameters for the acid mine drainage module. ACPARM(7) Acid mine parameters W (1X,7(1PE10.3)) ACPARM1 ACPARM2 ACPARM3 ACPARM4 ACPARM5 ACP2) (mg/m2.hr)(mg/m2.hr) H RCHRES TIC CO2 PH x - x mg/l mg/l PH-INIT@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. ,!TIC is the initial total inorganic carbon.TICAFIELD4 aPy0. 0!CO2 is the initial carbon dioxide (as carbon).CO2BFIELD5 bP?pA7. "PH is the initial pH. PH &Initial conditions for pH simulation. D (1X,3(1PE10.3)) TIC CO2 PH (mg/l) (mg/l)X RCHRES AC01 AC02 AC03 AC04 AC05 AC06 AC07 AC08 AC09 AC10 AC11 AC12 AC13 AC14 x - x ACID-FLAGS @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 a(3 E!ACFLAG(1) determines the units of printout for the acid mine module. ACFLAG(1) AFIELD4 a(4 f!ACFLAG(2) selects one four optional methods for the chemical simulation used by the acid mine module. ACFLAG(2) BFIELD5 b(1 `"ACFLAG(3) selects the Gibbsite solubility product used if chemical simulation method 1 is used. ACFLAG(3) BFIELD6 b(d0 5"ACFLAG(*) are option flags for the acid mine module. ACFLAG(4) CFIELD7 c(d0 5#ACFLAG(*) are option flags for the acid mine module. ACFLAG(5) CFIELD8 c(d0 5#ACFLAG(*) are option flags for the acid mine module. ACFLAG(6) DFIELD9 d(d0 5$ACFLAG(*) are option flags for the acid mine module. ACFLAG(7) DFIELD10d(d0 5$ACFLAG(*) are option flags for the acid mine module. ACFLAG(8) EFIELD11e(d0 5%ACFLAG(*) are option flags for the acid mine module. ACFLAG(9) EFIELD12e(d0 5%ACFLAG(*) are option flags for the acid mine mod. PHYTO AFIELD4 aP75y0.03 *!ZOO is the initial value of zooplankton. ZOOBFIELD5 bP.y1.0E-8 "BENAL is the initial value of benthic algae, as biomass,if only one species is simulated (i.e. BALFG=1 or if BALFG=2and NUMBAL= 1). BENAL BFIELD6 bPy0. ?"ORN is the initial value of dead refractory organicnitrogen. ORNCFIELD7 cPy0. A#ORP is the initial value of dead refractory organicphosphorus. ORPCFIELD8 cPy0. =#ORC is the initial value of dead refractory organic carbon. ORCInitial plankton conditions. (1X,6(1PE10.3)) PHYTO ZOO BENAL ORN ORP ORC (mg/l) (org/l) (mg/m2) (mg/l) (mg/l) (mg/l) 8 RCHRES Flags for pH simulation x - x PHCN ALKC PH-PARM1 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(d25 ;!PHCNT is the maximum number of iterations to pH solution. PHCNT AFIELD4 a( 1 I!ALKCON is the number of the conservative substance which isalkalinity. ALKCON Flags for pH simulation.  (1X,2I10) PHCNT ALKCON R RCHRES CFCINV BRCO2(1) BRCO2(2) x - x mg/m2.hr mg/m2.hr PH-PARM2 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPn:?0.913 U!CFCINV is the ratio of carbon dioxide invasion rate tooxygen reaeration rate. CFCINV AFIELD4 aP #<y62.Q!BRCO2(1) is the benthal release of CO2 (as carbon) foraerobic conditions. BRCO21 BFIELD5 bP #<y62.S"BRCO2(2) is the benthal release of CO2 (as carbon) foranaerobic conditions. BRCO22 Parameters for pH simulation. N (1X,3(1PE10.3)) CFCINV BRCO2(1) BRCO2(ZRES ZEXDEL ZOMASS (mg/org)  RCHRES MBAL CFBALR CFBALG MINBAL CAMPR FRAVL NMAXFX x - x mg/m2 mg/m2 mg/l mg/l BENAL-PARM @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP #<y600. D!MBAL is the maximum benthic algae density (as biomass) ifBALFG=1.MBAL AFIELD4 aP #<?1. U!CFBALR is the ratio of benthic algal to phytoplanktonrespiration if BALFG=1. CFBALR BFIELD5 bP #<?1. U"CFBALG is the ratio of benthic algal to phytoplanktongrowth rate if BALFG=1. CFBALG BFIELD6 bP75y0.0001 N"MINBAL is the minimum combined benthic algae density (as biomass)if BALFG=2. MINBAL CFIELD7 cP75y0.001 #CAMPR is the Michaelis-Menton half-saturation constant for ammonia inthe nitrogen preference equation for benthic algae if BALFG=2. CAMPR CFIELD8 cP?0. #FRAVL is the fraction of benthic algae death and scour that isimmediately available as inorganic nutrients, plus refractoryorganics. FRAVL DFIELD9 dPy10.$NMAXFX is the level of dissolved inorganic nitrogen concentration(NO3 plus TAM if simulated) above which nitrogen fixation will not occur.NMAXFX "General benthic algae parameters. (1X,7(1PE10.3)) MBAL CFBALR CFBALG MINBAL CAMPR FRAVL NMAXFX (mg/m2) (mg/m2) (mg/l) (mg/l)  RCHRES PHYTO ZOO BENAL ORN ORP ORC x - x mg/l org/l mg/m2 mg/l mg/l mg/l PLNK-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP.y.96E-6 :!PHYTO is the initial value of phytoplankton, as biomassnkton parameters. (1X,6(1PE10.3)) SEED MXSTAY OREF CLALDH PHYSET REFSET (mg/l) (mg/l) (m3/s) (ug/l) (m/hr) (m/hr) z RCHRES MZOEAT ZFIL20 ZRES20 ZD OXZD x - x mg/l.hr l/mgzoo.hr /hr /hr /hr ZOO-PARM1 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPn:y0.055 8!MZOEAT is the maximum zooplankton unit ingestion rate.MZOEAT AFIELD4 aPn:y-999. ;!ZFIL20 is the zooplankton filtering rate at 20 degrees C. ZFIL20 BFIELD5 bP75y0.0015 C"ZRES20 is the zooplankton unit respiration rate at 20degrees C. ZRES20 BFIELD6 bP75y0.0001 0"ZD is the natural zooplankton unit death rate.ZD CFIELD7 cP75y0.03 S#OXZD is the increment to unit zooplankton death rate due toanaerobic conditions. OXZD 'First group of zooplankton parameters. v (1X,5(1PE10.3)) MZOEAT ZFIL20 ZRES20 ZD OXZD(mg/mg.hr) (l/mg.hr) (/hr) (/hr) (/hr) f RCHRES TCZFIL TCZRES ZEXDEL ZOMASS x - x mg/org ZOO-PARM2 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP?@1.17 A!TCZFIL is the temperature correction coefficient forfiltering. TCZFIL AFIELD4 aP?@1.07 C!TCZRES is the temperature correction coefficient forrespiration. TCZRES BFIELD5 bPn:?0.7}"ZEXDEL is the fraction of nonrefractory zooplanktonexcretion which is immediately decomposed when ingestionrate > MZOEAT. ZEXDEL BFIELD6 bP75?0.0003 9"ZOMASS is the average weight of a zooplankton organism. ZOMASS (Second group of zooplankton parameters.b (1X,4(1PE10.3)) TCZFIL TCon not subjectto advection (i.e. at high flow). SEED AFIELD4 aPy0. T!MXSTAY is the concentration of plankton not subject toadvection at very low flow.MXSTAY BFIELD5 bP8y0.0001 t"OREF is the outflow at which concentration of plankton notsubject to advection is midway between SEED and MXSTAY.O REF BFIELD6 bP #<y50.W"CLALDH is the chlorophyll "A" concentration above whichhigh algal death rate occurs. CLALDH CFIELD7 cPy0. /#PHYSET is the rate of phytoplankton settling. PHYSET CFIELD8 cPy0. >#REFSET is the rate of settling for dead refractoryorganics. REFSET Phytoplankton parameters. (1X,6(1PE10.3)) SEED MXSTAY OREF CLALDH PHYSET REFSET (mg/l) (mg/l) (ft3/s) (ug/l) (ft/hr) (ft/hr)  RCHRES SEED MXSTAY OREF CLALDH PHYSET REFSET x - x mg/l mg/l m3/s ug/l m/hr m/hr PHYTO-PARM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. ]!SEED is the minimum concentration of plankton not subjectto advection (i.e. at high flow). SEED AFIELD4 aPy0. T!MXSTAY is the concentration of plankton not subject toadvection at very low flow.MXSTAY BFIELD5 bP8y0.0001 t"OREF is the outflow at which concentration of plankton notsubject to advection is midway between SEED and MXSTAY.O REF BFIELD6 bP #<y50._"CLALDH is the chlorophyll "A" concentration above whichhigh phytoplankton death rate occurs. CLALDH CFIELD7 cPy0. /#PHYSET is the rate of phytoplankton settling. PHYSET CFIELD8 cPy0. >#REFSET is the rate of settling for dead refractoryorganics. REFSET Phytoplais the temperature below which phytoplankton growth ceases.TALGRL DFIELD9 dPB25.I$TALGRM is the temperature below which phytoplankton growth isretarded. TALGRM &General plankton parameters, group 2. (1X,7(1PE10.3)) CMMLT CMMN CMMNP CMMP TALGRH TALGRL TALGRM (ly/min) (mg/l) (mg/l) (mg/l) (deg C) (deg C) (deg C)  RCHRES ALR20 ALDH ALDL OXALD NALDH PALDH x - x /hr /hr /hr /hr mg/l mg/l PLNK-PARM3 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP75y0.004 C!ALR20 is the phytoplankton unit respiration rate at 20 degrees C. ALR20 AFIELD4 aP75y0.01 1!ALDH is the high phytoplankton unit death rate. ALDH BFIELD5 bP75y0.001 0"ALDL is the low phytoplankton unit death rate.ALDL BFIELD6 bP75y0.03 V"OXALD is the increment to phytoplankton unit death rate dueto anaerobic conditions. OXALD CFIELD7 cPy0. q#NALDH is the inorganic nitrogen concentration below whichhigh phytoplankton death rate occurs (as nitrogen). NALDH CFIELD8 cPy0. s#PALDH is the inorganic phosphorus concentration below whichhigh phytoplankton death rate occurs (as phosphorus). PALDH &General plankton parameters, group 3. (1X,6(1PE10.3)) ALR20 ALDH ALDL OXALD NALDH PALDH (/hr) (/hr) (/hr) (/hr) (mg/l) (mg/l)  RCHRES SEED MXSTAY OREF CLALDH PHYSET REFSET x - x mg/l mg/l ft3/s ug/l ft/hr ft/hr PHYTO-PARM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. ]!SEED is the minimum concentration of planktoplankton. CMMN BFIELD5 bP75y0.0284 j"CMMNP is the nitrate Michaelis-Menten constant forphosphorus limited growth for phytoplankton. CMMNP BFIELD6 bP75y0.015 j"CMMP is the phosphate Michaelis-Menten constant forphosphorus limited growth for phytoplankton. CMMP CFIELD7 cPHBTC95.D#TALGRH is the temperature above which phytoplankton growth ceases.TALGRH CFIELD8 cPTC43.D#TALGRL is the temperature below which phytoplankton growth ceases.TALGRL DFIELD9 dPBTC77.I$TALGRM is the temperature below which phytoplankton growth isretarded. TALGRM &General plankton parameters, group 2. (1X,7(1PE10.3)) CMMLT CMMN CMMNP CMMP TALGRH TALGRL TALGRM (ly/min) (mg/l) (mg/l) (mg/l) (deg F) (deg F) (deg F)  RCHRES CMMLT CMMN CMMNP CMMP TALGRH TALGRL TALGRM x - x ly/min mg/l mg/l mg/l deg C deg C deg C PLNK-PARM2 @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP75y0.033 W!CMMLT is the Michaelis-Menten constant for light limitedgrowth for phytoplankton. CMMLT AFIELD4 aP75y0.045 _!CMMN is the nitrate Michaelis-Menten constant for nitrogenlimited growth for phytoplankton. CMMN BFIELD5 bP75y0.0284 j"CMMNP is the nitrate Michaelis-Menten constant forphosphorus limited growth for phytoplankton. CMMNP BFIELD6 bP75y0.015 j"CMMP is the phosphate Michaelis-Menten constant forphosphorus limited growth for phytoplankton. CMMP CFIELD7 cP AB35.D#TALGRH is the temperature above which phytoplankton growth ceases.TALGRH CFIELD8 cPB6.1D#TALGRL  ALNPR EXTB MALGR PARADF x - x l/mg.ft /m /hr PLNK-PARM1 @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP #<y0.6T!RATCLP is the ratio of chlorophyll "A" content of biomassto phosphorus content.RATCLP AFIELD4 aP #<?0.5R!NONREF is the nonrefractory fraction of algae andzooplankton biomass. NONREF BFIELD5 bPy0. "LITSED is the multiplication factor to total sedimentconcentration to determine sediment contribution to lightextinction if SDLTFG=1. LITSED BFIELD6 bP #<?1. "ALNPR is the fraction of nitrogen requirements forphytoplankton growth satisfied by nitrate. It is also usedfor benthic algae if BALFG > 0 and BNPRFG= 1. ALNPR CFIELD7 cPn:y-999. 4#EXTB is the base extinction coefficient for light.EXTB CFIELD8 cPn:y0.3@#MALGR is the maximal unit algal growth rate for phytoplankton.MALGR DFIELD9 dP?1.0V$PARADF is the fraction of incoming solar radiation that isphotosynthetically active. PARADF &General plankton parameters, group 1. (1X,7(1PE10.3)) RATCLP NONREF LITSED ALNPR EXTB MALGR PARADF (/m) (/hr) RCHRES CMMLT CMMN CMMNP CMMP TALGRH TALGRL TALGRM x - x ly/min mg/l mg/l mg/l deg F deg F deg F PLNK-PARM2 @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP75y0.033 W!CMMLT is the Michaelis-Menten constant for light limitedgrowth for phytoplankton. CMMLT AFIELD4 aP75y0.045 _!CMMN is the nitrate Michaelis-Menten constant for nitrogenlimited growth for phytradiation data x - x CFSAEX SURF-EXPOSED @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPn:?1. !CFSAEX is a factor used to adjust the input solar radiationto make it applicable to the RCHRES; for example, to accountfor shading of the surface by trees or buildings.CFSAEX ,Correction factor for solar radiation data. (1X,1(1PE10.3)) CFSAEX  RCHRES RATCLP NONREF LITSED ALNPR EXTB MALGR PARADF x - x l/mg.ft /ft /hr PLNK-PARM1 @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP #<y0.6T!RATCLP is the ratio of chlorophyll "A" content of biomassto phosphorus content.RATCLP AFIELD4 aP #<?0.5R!NONREF is the nonrefractory fraction of algae andzooplankton biomass. NONREF BFIELD5 bPy0. "LITSED is the multiplication factor to total sedimentconcentration to determine sediment contribution to lightextinction if SDLTFG=1. LITSED BFIELD6 bP #<?1. "ALNPR is the fraction of nitrogen requirements forphytoplankton growth satisfied by nitrate. It is also usedfor benthic algae if BALFG > 0 and BNPRFG= 1. ALNPR CFIELD7 cPn:y-999. 4#EXTB is the base extinction coefficient for light.EXTB CFIELD8 cPn:y0.3@#MALGR is the maximal unit algal growth rate for phytoplankton.MALGR DFIELD9 dP?1.0V$PARADF is the fraction of incoming solar radiation that isphotosynthetically active. PARADF &General plankton parameters, group 1. (1X,7(1PE10.3)) RATCLP NONREF LITSED ALNPR EXTB MALGR PARADF (/ft) (/hr) RCHRES RATCLP NONREF LITSED anic N iseither absent or is supplied as a direct time series as PLADFX. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. PLADFG(1) AAFIELD4 a0 !Value of 0 indicates that concentration of organic N in precipitationis either absent or is supplied as a direct time series as PLADCN. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. PLADFG(2) ABFIELD5 b0 "Value of 0 indicates that atmospheric deposition flux of organic P iseither absent or is supplied as a direct time series as PLADFX. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. PLADFG(3) BBFIELD6 b0 "Value of 0 indicates that concentration of organic P in precipitationis either absent or is supplied as a direct time series as PLADCN. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. PLADFG(4) BCFIELD7 c0 #Value of 0 indicates that atmospheric deposition flux of organic C iseither absent or is supplied as a direct time series as PLADFX. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. PLADFG(5) CCFIELD8 c0 #Value of 0 indicates that concentration of organic C in precipitationis either absent or is supplied as a direct time series as PLADCN. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. PLADFG(6) Cb (1X,3(1X,2I4))Atmospheric Deposition Flags ORN ORP ORC FLX CON FLX CON FLX CON L RCHRES Correction factor for solar G: value of 1 means zooplankton are simulated.ZOOFG BFIELD5 b(0 "BALFG: Value of 1 means a single species of benthic algaeis simulated, with growth and respiration rates proportionalto phytoplankton - PHYFG must be on. Value of 2 means one tofour species of benthic algae are simulated using new kinetics. BALFG BFIELD6 b(0 "SDLTFG: Value of 1 means influence of sediment washload onlight extinction is simulated based on computed or inputsediment concentation. Value of 2 means it is based onlinear regression on flow (requires input of BENAL-LIGHT).Value of 0 means no influence is considered. SDLTFG BCFIELD7 c(0 X#AMRFG: value of 1 means ammonia retardation of nitrogenlimited growth is enabled.AMRFG CFIELD8 c(0 `#DECFG: value of 1 means linkage between carbon dioxide andphytoplankton growth is decoupled.DECFG DFIELD9 d(0 $NSFG: value of 1 means ammonia is included as part ofavailable nitrogen supply in nitrogen limited growthcalculations.NSFG DFIELD10d(2 +$ZFOOD is the quality of zooplankton food. ZFOOD EFIELD11e(0 %BNPFG: Value of 0 means benthic algae use ALNPR in PLNK-PARM1to determine preference between ammonia and nitrate. Value of1 means it is a function of the current ammonia concentration,based on CAMPR in BENAL-PARM. BNPFG Plankton flags (RCHRES). e (1X,9I10) PHYFG ZOOFG BALFG SDLTFG AMRFG DECFG NSFG ZFOOD BNPFG g Atmospheric Deposition Flags RCHRES ORN ORP ORC x - x  PLNK-AD-FLAGS @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a0 !Value of 0 indicates that atmospheric deposition flux of org 0.0J"SPO4(1) is the initial concentration of PO4-P adsorbedto suspended sand. SPO4(1)CFIELD7 cPy0.0J#SPO4(2) is the initial concentration of PO4-P adsorbedto suspended silt. SPO4(2)CFIELD8 cPy0.0J#SPO4(3) is the initial concentration of PO4-P adsorbedto suspended clay. SPO4(3)Initial Adsorbed concs. (1X,6(1PE10.3)) Initial suspended NH4 and PO4 concentrations (mg/kg) SNH4(1) SNH4(2) SNH4(3) SPO4(1) SPO4(2) SPO4(3) (mg/kg) (mg/kg) (mg/kg) (mg/kg) (mg/kg) (mg/kg) h RCHRES Monthly values of pH x - x PH1 PH2 PH3 PH4 PH5 PH6 PH7 PH8 PH9 PH10 PH11 PH12 MON-PHVAL @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(?`A7. %!PHVA1 is the value of pH in January. PHVA1 AFIELD4 a(?`A7. PHVA2 BFIELD5 b(?`A7. PHVA3 BFIELD6 b(?`A7. PHVA4 CFIELD7 c(?`A7. PHVA5 CFIELD8 c(?`A7. PHVA6 DFIELD9 d(?`A7. PHVA7 DFIELD10d(?`A7. PHVA8 EFIELD11e(?`A7. PHVA9 EFIELD12e(?`A7. PHVA10 FFIELD13f(?`A7. PHVA11 FFIELD14f(?`A7. PHVA12 IMonthly values of pH; input only if PHFLAG=3 in Table-typeGQ-GENDATA. y (1X,12(1PE10.3)) Monthly values of pH JAN FEB MAR APR MAY JUN JUL AUG R RCHRES Plankton flags x - x PHYF ZOOF BALF SDLT AMRF DECF NSFG ZFOO BNP PLNK-FLAGS @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(0 5!PHYFG: value of 1 means phytoplankton is simulated. PHYFG AFIELD4 a(0 4!ZOOF   silt. ADPOPM(2) CFIELD8 cP.y1.0E-10C#ADPOPM(3) is the partition coefficient for PO4-P adsorbedto clay. ADPOPM(3) /Partition coefficients for NH4 AND PO4 (ml/g) (1X,6(1PE10.3)) Partition coefficients for NH4 AND PO4 (ml/g) ADNHPM(1) ADNHPM(2) ADNHPM(3) ADPOPM(1) ADPOPM(2) ADPOPM(3) (ml/g) (ml/g) (ml/g) (ml/g) (ml/g) (ml/g)f RCHRES NO3 TAM NO2 PO4 x - x mg/l mg/l mg/l mg/l NUT-DINIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0.0<!NO3 is the initial concentration of nitrate (as nitrogen).NO3AFIELD4 aPy0.0;!TAM is the initial concentration of total ammonia (as N). TAMBFIELD5 bPy0.0<"NO2 is the initial concentration of nitrite (as nitrogen).NO2BFIELD6 bPy0.0J"PO4 is the initial concentration of ortho-phosphorus (asphosphorus). PO4CFIELD7 cP`A7. 7#PHVAL is the constant (annual) or initial value of pH. PHVAL Initial dissolved concs. v (1X,5(1PE10.3)) NO3 TAM NO2 PO4 PHVAL (mg/l) (mg/l) (mg/l) (mg/l) (ph)  RCHRES Initial suspended NH4 and PO4 concentrations (mg/kg) x - x NH4-sand NH4-silt NH4-clay PO4-sand PO4-silt PO4-clay NUT-ADSINIT@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0.0J!SNH4(1) is the initial concentration of NH4-N adsorbedto suspended sand. SNH4(1)AFIELD4 aPy0.0J!SNH4(2) is the initial concentration of NH4-N adsorbedto suspended silt. SNH4(2)BFIELD5 bPy0.0J"SNH4(3) is the initial concentration of NH4-N adsorbedto suspended clay. SNH4(3)BFIELD6 bPy  d NH4-silt NH4-clay PO4-sand PO4-silt PO4-clay NUT-BEDCONC@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0.0E!BNH4(1) is the constant bed concentration of NH4-Nadsorbed to sand. BNH4(1)AFIELD4 aPy0.0E!BNH4(2) is the constant bed concentration of NH4-Nadsorbed to silt. BNH4(2)BFIELD5 bPy0.0E"BNH4(3) is the constant bed concentration of NH4-Nadsorbed to clay. BNH4(3)BFIELD6 bPy0.0E"BPO4(1) is the constant bed concentration of PO4-Padsorbed to sand. BPO4(1)CFIELD7 cPy0.0E#BPO4(2) is the constant bed concentration of PO4-Padsorbed to silt. BPO4(2)CFIELD8 cPy0.0E#BPO4(3) is the constant bed concentration of PO4-Padsorbed to clay. BPO4(3)(Bed concentrations of NH4 & PO4 (mg/kg) (1X,6(1PE10.3)) Bed concentrations of NH4 & PO4 (mg/kg) BNH4(1) BNH4(2) BNH4(3) BPO4(1) BPO4(2) BPO4(3) (mg/kg) (mg/kg) (mg/kg) (mg/kg) (mg/kg) (mg/kg)  RCHRES Partition coefficients for NH4 AND PO4 (ml/g) x - x NH4-sand NH4-silt NH4-clay PO4-sand PO4-silt PO4-clay NUT-ADSPARM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP.y1.0E-10C!ADNHPM(1) is the partition coefficient for NH4-N adsorbedto sand. ADNHPM(1) AFIELD4 aP.y1.0E-10C!ADNHPM(2) is the partition coefficient for NH4-N adsorbedto silt. ADNHPM(2) BFIELD5 bP.y1.0E-10C"ADNHPM(3) is the partition coefficient for NH4-N adsorbedto clay. ADNHPM(3) BFIELD6 bP.y1.0E-10C"ADPOPM(1) is the partition coefficient for PO4-P adsorbedto sand. ADPOPM(1) CFIELD7 cP.y1.0E-10C#ADPOPM(2) is the partition coefficient for PO4-P adsorbedto  rameters (NUTRX section). v (1X,5(1PE10.3)) BRTAM(1) BRTAM(2) BRPO4(1) BRPO4(2) ANAER(mg/m2.hr)(mg/m2.hr)(mg/m2.hr)(mg/m2.hr) (mg/l)  RCHRES KTAM20 KNO220 TCNIT KNO320 TCDEN DENOXT x - x /hr /hr /hr mg/l NUT-NITDENIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPn:y-999. =!KTAM20 is the unit oxidation rate of total ammonia at 20 C. KTAM20 AFIELD4 aPn:y-999. =!KNO220 is the unit oxidation rate of nitrite at 20 deg. C. KNO220 BFIELD5 bP?@1.07 V"TCNIT is the temperature correction coefficient for thenitrogen oxidation rates. TCNIT BFIELD6 bPn:y-999. ="KNO320 is the unit denitrification rate of nitrate at 20 C. KNO320 CFIELD7 cP?@1.07 R#TCDEN is the temperature correction coefficient for thedenitrification rate. TCDEN CFIELD8 cPy2.0\#DENOXT is the dissolved oxygen concentration threshholdabove which denitrification ceases.DENOXT Nitrif/denitrif parms. (1X,6(1PE10.3)) KTAM20 KNO220 TCNIT KNO320 TCDEN DENOXT (/hr) (/hr) (/hr) (mg/l) * RCHRES EXPNVG EXPNVL x - x NUT-NH3VOLAT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP=@0.5c!EXPNVG is the exponent in the gas layer mass transfercoefficient equation for NH3 volatilization. EXPNVG AFIELD4 aP=@0.6667 f!EXPNVL is the exponent in the liquid layer mass transfercoefficient equation for NH3 volatilization. EXPNVL NH3 volatilization parms. % (1X,2(1PE10.3)) EXPNVG EXPNVL  RCHRES Bed concentrations of NH4 & PO4 (mg/kg) x - x NH4-san ) Cb (1X,3(1X,2I4))Atmospheric Deposition Flags NO3 NH3 PO4 FLX CON FLX CON FLX CON \ RCHRES CVBO CVBPC CVBPN BPCNTC x - x mg/mg mols/mol mols/mol CONV-VAL1 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP?@1.98 P!CVBO is the conversion from milligrams biomass tomilligrams oxygen.CVBO AFIELD4 aPHBHC106. _!CVBPC is the conversion from biomass expressed asphosphorus to carbon equivalency. CVBPC BFIELD5 bP AHB16.a"CVBPN is the conversion from biomass expressed asphosphorus to nitrogen equivalency. CVBPN BFIELD6 bP AB49.E"BPCNTC is the percentage, by weight, of biomass which iscarbon. BPCNTC $Conversion factors (NUTRX section).b (1X,4(1PE10.3)) CVBO CVBPC CVBPN BPCNTC (mg/mg)(mols/mol)(mols/mol) (percent) z RCHRES BRNIT(1) BRNIT(2) BRPO4(1) BRPO4(2) ANAER x - x mg/m2.hr mg/m2.hr mg/m2.hr mg/m2.hr mg/l NUT-BENPARM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. W!BRNIT(1) is the benthal release rate of inorganic nitrogenunder aerobic conditions. BRNIT1 AFIELD4 aPy0. Y!BRNIT(2) is the benthal release rate of inorganic nitrogenunder anaerobic conditions. BRNIT2 BFIELD5 bPy0. W"BRPO4(1) is the benthal release rate of ortho-phosphateunder aerobic conditions. BRPO41 BFIELD6 bPy0. Y"BRPO4(2) is the benthal release rate of ortho-phosphateunder anaerobic conditions. BRPO42 CFIELD7 cP8?0.005 Y#ANAER is the concentration of dissolved oxygen below whichanaerobic conditions exist. ANAER .Nutrient benthic pa  NUT-AD-FLAGS @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a0 !Value of 0 indicates that atmospheric deposition flux of NO3 is eitherabsent or is supplied as a direct time series as NUADFX. A valuegreater than 0 indicates the index number of the MONTH-DATA block to beused to supply atmospheric deposition data. NUADFG(1) AAFIELD4 a0 !Value of 0 indicates that concentration of NO3 in precipitation iseither absent or is supplied as a direct time series as NUADCN. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. NUADFG(2) ABFIELD5 b0 "Value of 0 indicates that atmospheric deposition flux of NH3 is eitherabsent or is supplied as a direct time series as NUADFX. A valuegreater than 0 indicates the index number of the MONTH-DATA block to beused to supply atmospheric deposition data. NUADFG(3) BBFIELD6 b0 "Value of 0 indicates that concentration of NH3 in precipitation iseither absent or is supplied as a direct time series as NUADCN. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. NUADFG(4) BCFIELD7 c0 #Value of 0 indicates that atmospheric deposition flux of PO4 is eitherabsent or is supplied as a direct time series as NUADFX. A valuegreater than 0 indicates the index number of the MONTH-DATA block to beused to supply atmospheric deposition data. NUADFG(5) CCFIELD8 c0 #Value of 0 indicates that concentration of PO4 in precipitation iseither absent or is supplied as a direct time series as NUADCN. Avalue greater than 0 indicates the index number of the MONTH-DATA blockto be used to supply atmospheric deposition data. NUADFG(6REAK EXPRED EXPREV (/hr) R RCHRES DOX BOD SATDO x - x mg/l mg/l mg/l  OX-INIT@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPA0. 4!DOX is the initial dissolved oxygen concentration.DOXAFIELD4 aPy0. /!BOD is the initial biochemical oxygen demand. BODBFIELD5 bP=A10.L"SATDO is the initial dissolved oxygen saturationconcentration.SATDO )Initial concentrations for section OXRX. N (1X,3(1PE10.3)) DOX BOD SATDO (mg/l) (mg/l) (mg/l) N RCHRES Nutrient flags x - x NH3 NO2 PO4 AMV DEN ADNH ADPO PHFL NUT-FLAGS @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(0 /!NH3FG: value of 1 means ammonia is simulated. NH3FG AFIELD4 a(0 /!NO2FG: value of 1 means nitrite is simulated. NO2FG BFIELD5 b(0 8"PO4FG: value of 1 means ortho-phosphorus is simulated.PO4FG BFIELD6 b(0 <"AMVFG: value of 1 means ammonia vaporization is simulated.AMVFG CFIELD7 c(0 7#DENFG: value of 1 means denitrification is simulated. DENFG CFIELD8 c(0 9#ADNHFG: value of 1 means NH4 adsorption is simulated ADNHFG DFIELD9 d(0 9$ADPOFG: value of 1 means PO4 adsorption is simulated ADPOFG DFIELD10d(2 =$PHFLAG: value of 1=time series, 2=annual, 3=monthly values PHFLAG Nutrient flags (RCHRES). [ (1X,8I10) TAMFG NO2FG PO4FG AMVFG DENFG ADNHFG ADPOFG PHFLAG f Atmospheric Deposition Flags RCHRES NO3 NH3 PO4 x - x  is the length of the RCHRES. LENAFIELD4 aP'7y-999. ;!DELTH is the (energy) drop over the length of the RCHRES. DELTH #Length of reach and fall (RCHRES). : (1X,2(1PE10.3)) LEN DELTH (miles) (ft) > RCHRES LEN DELTH x - x km (m) OX-LEN-DELTH @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP #<y-999. "!LEN is the length of the RCHRES. LENAFIELD4 aP'7y-999. ;!DELTH is the (energy) drop over the length of the RCHRES. DELTH #Length of reach and fall (RCHRES). : (1X,2(1PE10.3)) LEN DELTH (km) (m) = RCHRES Temperature correction coef x - x TCGINV OX-TCGINV @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP?@1.047 S!TCGINV is the temperature correction coefficient forsurface gas invasion. TCGINV &Owen/Churchill/O'Connor-Dobbins data.  (1X,1(1PE10.3)) TCGINV R RCHRES TCGINV REAK EXPRED EXPREV x - x /hr OX-REAPARM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP?@1.047 S!TCGINV is the temperature correction coefficient forsurface gas invasion. TCGINV AFIELD4 aP`B y-999. c!REAK is the empirical constant for equation used tocalculate the reaeration coefficient. REAK BFIELD5 bPy0. U"EXPRED is the exponent to depth used in calculation of thereaeration coefficient. EXPRED BFIELD6 bPy0. Y"EXPREV is the exponent to velocity used in calculation ofthe reaeration coefficient. EXPREV 1Parameters for user-supplied reaeration formula. N (1X,4(1PE10.3)) TCGINV thaloxygen demand.TCBEN BFIELD5 bP=y1.22 f"EXPOD is the exponential factor in the dissolved oxygen termof the benthal oxygen demand equation. EXPOD BFIELD6 bP8y72.L"BRBOD(1) is the benthal release of BOD at high oxygenconcentration.BRBOD1 CFIELD7 cP8y100. S#BRBOD(2) is the increment to benthal release of BOD underanaerobic conditions. BRBOD2 CFIELD8 cP=y2.82 d#EXPREL is the exponential factor in the dissolved oxygen termof the benthal BOD release equation.EXPREL Oxygen benthic parameters. (1X,6(1PE10.3)) BENOD TCBEN EXPOD BRBOD(1) BRBOD(2) EXPREL(mg/m2.hr) (mg/m2.hr)(mg/m2.hr)C RCHRES Reaeration correction coefficient x - x CFOREA OX-CFOREA @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPn: A1. !CFOREA is a correction factor in the lake reaerationequation, to account for good or poor circulationcharacteristics. CFOREA (Lake reaeration correction coefficient. (1X,1(1PE10.3)) CFOREA 4 RCHRES REAKT TCGINV x - x /ft OX-TSIVOGLOU @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPn:?0.08 ^!REAKT is the empirical constant in Tsivoglou's equation forreaeration (escape coefficient). REAKT AFIELD4 aP?@1.047 S!TCGINV is the temperature correction coefficient forsurface gas invasion. TCGINV &Parameters for Tsivoglou calculation. 0 (1X,2(1PE10.3)) REAKT TCGINV (/ft)> RCHRES LEN DELTH x - x miles (ft) OX-LEN-DELTH @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP #<y-999. "!LEN  KBOD20 TCBOD KODSET SUPSAT x - x /hr m/hr OX-GENPARM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP`B y-999. 4!KBOD20 is the unit BOD decay rate at 20 degrees C.KBOD20 AFIELD4 aP?@1.075 D!TCBOD is the temperature correction coefficient for BODdecay.TCBOD BFIELD5 bPy0. %"KODSET is the rate of BOD settling. KODSET BFIELD6 bP?@1.15 w"SUPSAT is the allowable dissolved oxygen supersaturation(expressed as a multiple of DO saturation concentration). SUPSAT $General oxygen parameters (RCHRES).X (1X,4(1PE10.3)) KBOD20 TCBOD KODSET SUPSAT (/hr) (m/hr)* RCHRES ELEV x - x (ft)  ELEV @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP`F0. (!ELEV is the elevation above sea level.ELEV "RCHRES elevation above sea level. & (1X,1(1PE10.3)) ELEV (ft) * RCHRES ELEV x - x (m)  ELEV @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP@F0. (!ELEV is the elevation above sea level.ELEV "RCHRES elevation above sea level. & (1X,1(1PE10.3)) ELEV (m)  RCHRES BENOD TCBEN EXPOD BRBOD(1) BRBOD(2) EXPREL x - x mg/m2.hr mg/m2.hr mg/m2.hr OX-BENPARM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. !BENOD is the benthal oxygen demand at 20 degrees C (withunlimited DO concentration) (demand is, thus, proportionalto the water temperature). BENOD AFIELD4 aP?@1.074 L!TCBEN is the temperature correction coefficient for bensec SCOUR-PARMS@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP #<y3.05 c!SCRVEL is the velocity above which effects of scouring onbenthal release rates are considered. SCRVEL AFIELD4 aP?y2. N!SCRMUL is the multiplier to increase benthal releasesduring scouring. SCRMUL Benthal scour parameters. 0 (1X,2(1PE10.3)) SCRVEL SCRMUL (m/sec)( RCHRES Oxygen flags x - x REAM OX-FLAGS @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(2 !REAMFG indicates the method used to calculate reaerationcoefficient for free-flowing streams; 1 means Tsivogloumethod is used, 2 means Owens, Churchill, or O'Connor-Dobbins method is used depending on velocity and depth ofwater, and 3 means coefficient is calculated as a powerfunction of velocity and/or depth; user inputs exponents forvelocity and depth and an empirical constant (REAK) REAMFG Oxygen flags (RCHRES).  (1X,1I10) REAMFG \ RCHRES KBOD20 TCBOD KODSET SUPSAT x - x /hr ft/hr OX-GENPARM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP`B y-999. 4!KBOD20 is the unit BOD decay rate at 20 degrees C.KBOD20 AFIELD4 aP?@1.075 D!TCBOD is the temperature correction coefficient for BODdecay.TCBOD BFIELD5 bPy0. %"KODSET is the rate of BOD settling. KODSET BFIELD6 bP?@1.15 w"SUPSAT is the allowable dissolved oxygen supersaturation(expressed as a multiple of DO saturation concentration). SUPSAT $General oxygen parameters (RCHRES).X (1X,4(1PE10.3)) KBOD20 TCBOD KODSET SUPSAT ( /hr) (ft/hr)[ RCHRES esses. C2F1 BFIELD5 bPy0. "See help for C2F1. C3F1 BFIELD6 bPy0. "See help for C2F1. C4F1 CFIELD7 cPy0. #See help for C2F1. C5F1 CFIELD8 cPy0. #See help for C2F1. C6F1 DFIELD9 dPy0. $See help for C2F1. C7F1 HThis table-type specifies the relationship between parent anddaughter compounds. The table must be repeated in sequencefor each decay process that produces "daughter" quals fromdecay of "parent" quals. The proper sequence is :1-hydrolysis, 2-oxidation by free radical oxygen, 3-photolysis,4-volatilization, 5-biodegradation, 6-general first order decay.If some processes are not active, then dummy tables are used topreserve this order. In this table data has to be specifiedusing one row per qual. Extra rows will be ignored. Missingrows will be filled in with zeroes.b (1X,7(' ',7(1PE10.3),/,)) ->1 ->2 ->3 ->4 ->5 ->6 ->7 1 RCHRES Benthic release flag x - x BENF BENTH-FLAG @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(0 =!BENRFG: value of 1 means benthal influences are considered. BENRFG Benthic release flag (RQUAL).  (1X,1I10) BENF 4 RCHRES SCRVEL SCRMUL x - x ft/sec SCOUR-PARMS@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP #<y10.c!SCRVEL is the velocity above which effects of scouring onbenthal release rates are considered. SCRVEL AFIELD4 aP?y2. N!SCRMUL is the multiplier to increase benthal releasesduring scouring. SCRMUL Benthal scour parameters. 0 (1X,2(1PE10.3)) SCRVEL SCRMUL (ft/sec)4 RCHRES SCRVEL SCRMUL x - x m/" RCHRES to which these data apply. OPNID `QAFIELD3 a(y0. L!PHYM(1) through PHYM(12) are monthly values of phytoplanktonconcentration.PHYM1 AFIELD4 a(y0. PHYM2 BFIELD5 b(y0. PHYM3 BFIELD6 b(y0. PHYM4 CFIELD7 c(y0. PHYM5 CFIELD8 c(y0. PHYM6 DFIELD9 d(y0. PHYM7 DFIELD10d(y0. PHYM8 EFIELD11e(y0. PHYM9 EFIELD12e(y0. PHYM10 FFIELD13f(y0. PHYM11 FFIELD14f(y0. PHYM12 cMonthly values of phytoplankton concentration; input onlyif PHYTFG=3 in Table-type GQ-GENDATA. (1X,12(1PE10.3))Values of phytoplankton conc (mg biomass/l) at the start of each month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC i Relationship between parent and daughter compounds. ZERO 2F1 3F1 4F1 5F1 6F1 7F1 ZERO ZERO 3F2 4F2 5F2 6F2 7F2 ZERO ZERO ZERO 4F3 5F3 6F3 7F3 ZERO ZERO ZERO ZERO 5F4 6F4 7F4 ZERO ZERO ZERO ZERO ZERO 6F5 7F5 RCHRES ZERO ZERO ZERO ZERO ZERO ZERO 7F6 x - x ZERO ZERO ZERO ZERO ZERO ZERO ZER0 GQ-DAUGHTER@@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aPy0. ZERO AFIELD4 aPy0. !Variable C2F1 indicates the amount of qual no. 2 which is produced bydecay of qual no. 1 through one of the six decay proc A0. CLDM7 DFIELD10d( A0. CLDM8 EFIELD11e( A0. CLDM9 EFIELD12e( A0. CLDM10 FFIELD13f( A0. CLDM11 FFIELD14f( A0. CLDM12 _Monthly values of average cloud cover; input only ifCLDFG=3 in Table-type GQ-GENDATA. (1X,12(1PE10.3))Values of cloud cover (tenths) at start of each month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC | RCHRES Values of sediment concentrations (mg/l) x - x SC1 SC2 SC3 SC4 SC5 SC6 SC7 SC8 SC9 SC10 SC11 SC12 MON-SEDCONC@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(y0. V!SDCN(1) through SDCN(12) are monthly average suspendedsediment concentration values. SDCN1 AFIELD4 a(y0. SDCN2 BFIELD5 b(y0. SDCN3 BFIELD6 b(y0. SDCN4 CFIELD7 c(y0. SDCN5 CFIELD8 c(y0. SDCN6 DFIELD9 d(y0. SDCN7 DFIELD10d(y0. SDCN8 EFIELD11e(y0. SDCN9 EFIELD12e(y0. SDCN10 FFIELD13f(y0. SDCN11 FFIELD14f(y0. SDCN12 lMonthly average suspended sediment concentration values;input only if SDFG=3 in Table-type GQ-GENDATA. (1X,12(1PE10.3))Values of total sed conc (mg/l) at the start of each month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  RCHRES Values of phytoplankton concentration (mg/l) x - x P1 P2 P3 P4 P5 P6 P7 P8 P9 P10 P11 P12 MON-PHYTO @@FIELD1  F1 F2 F3 F4 F5 F6 F7 RCHRES F8 F9 F10 F11 F12 F13 F14 x - x F15 F16 F17 F18 GQ-CLDFACT @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP?0. !KCLD(1) through KCLD(18) are values of light extinctionefficiency of cloud cover for each of 18 wavelengths; inputonly when a qual undergoes photolysis; i.e., when anyQALFG(3)=1 in Table-type GQ-QALFG. KCLD1 AFIELD4 aP?0. KCLD2 BFIELD5 bP?0. KCLD3 BFIELD6 bP?0. KCLD4 CFIELD7 cP?0. KCLD5 CFIELD8 cP?0. KCLD6 DFIELD9 dP?0. KCLD7 vValues of light extinction efficiency of cloud cover, for eachof the 18 light wavelengths: When an entry has to be continuedonto more than 1 line: 1) no blank or "comment" lines may beput between any of the lines for a continued entry. Put allcomments ahead of the entry, 2) The specfication mustbe repeated for each line onto which the entry is continued. | (1X,9(1PE10.3),/,1X,9(1PE10.3))Values of light extinction efficiency of cloud cover, for each of the 18 light wavelengths:s RCHRES Values of cloud cover (tenths) x - x C1 C2 C3 C4 C5 C6 C7 C8 C9 C10 C11 C12 MON-CLOUD @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a( A0. A!CLDM(1) through CLDM(12) are monthly values of average cloud cov CLDM1 AFIELD4 a( A0. CLDM2 BFIELD5 b( A0. CLDM3 BFIELD6 b( A0. CLDM4 CFIELD7 c( A0. CLDM5 CFIELD8 c( A0. CLDM6 DFIELD9 d(7 GValues of sediment absorbance coeff (l/mg.cm).When an entry has to be continued onto more than 1 line:1) no blank or "comment" lines may be put between anyof the lines for a continued entry. Put all comments ahead ofthe entry, 2) The specfication must be repeated foreach line onto which the entry is continued. z (1X,9(1PE10.3),/,1X,9(1PE10.3))Values of sediment absorbance coefficient (l/mg.cm) for each of the 18 light wavelengths:  Values of phytoplankton absorbance coefficient (l/mg.cm) K1 K2 K3 K4 K5 K6 K7 RCHRES K8 K9 K10 K11 K12 K13 K14 x - x K15 K16 K17 K18 GQ-DELTA @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aPy0. !DEL(1) through DEL(18) are increments to the baseabsorption coefficient (Table-type GQ-ALPHA) for lightpassing through plankton-laden water; input only when a qualundergoes photolysis; i.e., when any QALFG(3)=1 in Table-type GQ-QALFG. DEL1 AFIELD4 aPy0. DEL2 BFIELD5 bPy0. DEL3 BFIELD6 bPy0. DEL4 CFIELD7 cPy0. DEL5 CFIELD8 cPy0. DEL6 DFIELD9 dPy0. DEL7 RValues of phytoplankton absorbance coefficient (l/mg.cm).When an entry has to be continued onto more than 1 line:1) no blank or "comment" lines may be put between anyof the lines for a continued entry. Put all comments ahead ofthe entry, 2) The specfication must be repeated foreach line onto which the entry is continued. (1X,9(1PE10.3),/,1X,9(1PE10.3))Values of the phytoplankton absorbance coefficient (l/mg.cm), for each of the 18 light wavelengths: Values of light extinction efficiency of cloud coverh ALPH(18) are base absorption coefficientsfor 18 wavelengths of light passing through clear water;input only when a qual undergoes photolysis; i.e., when anyQALFG(3)=1 in Table-type GQ-QALFG. ALPH1 AFIELD4 aP'7y-999. ALPH2 BFIELD5 bP'7y-999. ALPH3 BFIELD6 bP'7y-999. ALPH4 CFIELD7 cP'7y-999. ALPH5 CFIELD8 cP'7y-999. ALPH6 DFIELD9 dP'7y-999. ALPH7 eValues of base absorbance coeff (/cm) for each of the 18 lightwavelengths. When an entry has to be continued onto more than1 line: 1) no blank or "comment" lines may be put between anyof the lines for a continued entry. Put all comments ahead ofthe entry, 2) The specfication must be repeated foreach line onto which the entry is continued. l (1X,9(1PE10.3),/,1X,9(1PE10.3))Values of base absorbance coeff (/cm) for each of the 18 light wavelengths:  Values sediment absorbance coefficient (l/mg.cm) K1 K2 K3 K4 K5 K6 K7 RCHRES K8 K9 K10 K11 K12 K13 K14 x - x K15 K16 K17 K18 GQ-GAMMA @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aPy0. !GAMM(1) through GAMM(18) are increments to the base absorbancycoefficient (Table-type GQ-ALPHA) for light passing throughsediment-laden water. This table is necessary only when a qualundergoes photolysis; i.e., when any QALFG(3)=1 in Table-typeGQ-QALFG. GAMM1 AFIELD4 aPy0. GAMM2 BFIELD5 bPy0. GAMM3 BFIELD6 bPy0. GAMM4 CFIELD7 cPy0. GAMM5 CFIELD8 cPy0. GAMM6 DFIELD9 dPy0. GAMMTEMP11 FFIELD14f(=B15.5 TEMP12 VMonthly values of water temperature; input only if TEMPFG=3in Table-type GQ-GENDATA. (1X,12(1PE10.3))Values of water temperature (DegC) at start of each month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC RCHRES Monthly values of free radical oxygen (mole/l) x - x OX1 OX2 OX3 OX4 OX5 OX6 OX7 OX8 OX9 OX10 OX11 OX12 MON-ROXYGEN@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(y0. D!ROCM1 is the value of free radical oxygen concentration in January.ROCM1 AFIELD4 a(y0. ROCM2 BFIELD5 b(y0. ROCM3 BFIELD6 b(y0. ROCM4 CFIELD7 c(y0. ROCM5 CFIELD8 c(y0. ROCM6 DFIELD9 d(y0. ROCM7 DFIELD10d(y0. ROCM8 EFIELD11e(y0. ROCM9 EFIELD12e(y0. ROCM10 FFIELD13f(y0. ROCM11 FFIELD14f(y0. ROCM12 gMonthly values of free radical oxygen concentration; inputonly if ROXFG=3 in Table-type GQ-GENDATA. (1X,12(1PE10.3))Values of free radical oxygen at start of each month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Values of base absorbance coefficient (/cm) K1 K2 K3 K4 K5 K6 K7 RCHRES K8 K9 K10 K11 K12 K13 K14 x - x K15 K16 K17 K18 GQ-ALPHA @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP'7y-999. !ALPH(1) throug(deg F) x - x T1 T2 T3 T4 T5 T6 T7 T8 T9 T10 T11 T12 MON-WATEMP @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(BTC60.+!TEMP1 is the water temperature in January. TEMP1 AFIELD4 a(BTC60.TEMP2 BFIELD5 b(BTC60.TEMP3 BFIELD6 b(BTC60.TEMP4 CFIELD7 c(BTC60.TEMP5 CFIELD8 c(BTC60.TEMP6 DFIELD9 d(BTC60.TEMP7 DFIELD10d(BTC60.TEMP8 EFIELD11e(BTC60.TEMP9 EFIELD12e(BTC60.TEMP10 FFIELD13f(BTC60.TEMP11 FFIELD14f(BTC60.TEMP12 VMonthly values of water temperature; input only if TEMPFG=3in Table-type GQ-GENDATA. (1X,12(1PE10.3))Values of water temperature (DegF) at start of each month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC RCHRES Monthly values of water temperature (deg C) x - x T1 T2 T3 T4 T5 T6 T7 T8 T9 T10 T11 T12 MON-WATEMP @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(=B15.5 +!TEMP1 is the water temperature in January. TEMP1 AFIELD4 a(=B15.5 TEMP2 BFIELD5 b(=B15.5 TEMP3 BFIELD6 b(=B15.5 TEMP4 CFIELD7 c(=B15.5 TEMP5 CFIELD8 c(=B15.5 TEMP6 DFIELD9 d(=B15.5 TEMP7 DFIELD10d(=B15.5 TEMP8 EFIELD11e(=B15.5 TEMP9 EFIELD12e(=B15.5 TEMP10 FFIELD13f(=B15.5  value of total sedimentconcentration; input only if SDFG = 2 in Table-type GQ-GENDATA. SDCNC CFIELD8 cPy0. #PHY is the constant annual value of phytoplanktonconcentration; input only if PHYTFG = 2 in Table-type GQ-GENDATA. PHY6Initial values for inputs which are constant (GQUAL). (1X,6(1PE10.3)) TWAT PHVAL ROC CLD SDCNC PHY (deg F) (mole/l) (tenths) (mg/l) (mg/l)  RCHRES TWAT PHVAL ROC CLD SDCNC PHY x - x deg C mole/l tenths mg/l mg/l GQ-VALUES @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP=B15.5 p!TWAT is the constant annual value of water temperature;input only if TEMPFG = 2 in Table-type GQ-GENDATA.TWAT AFIELD4 aP?`A7. b!PHVAL is the constant annual value of pH; input only ifPHFLAG = 2 in Table-type GQ-GENDATA. PHVAL BFIELD5 bPy0. o"ROC is the constant annual value of free radical oxygen;input only if ROXFG = 2 in Table-type GQ-GENDATA. ROCBFIELD6 bP A0. d"CLD is the constant annual value of cloud cover; input onlyif CLDFG = 2 in Table-type GQ-GENDATA.CLDCFIELD7 cPy0. #SDCNC is the constant annual value of total sedimentconcentration; input only if SDFG = 2 in Table-type GQ-GENDATA. SDCNC CFIELD8 cPy0. #PHY is the constant annual value of phytoplanktonconcentration; input only if PHYTFG = 2 in Table-type GQ-GENDATA. PHY6Initial values for inputs which are constant (GQUAL). (1X,6(1PE10.3)) TWAT PHVAL ROC CLD SDCNC PHY (deg C) (mole/l) (tenths) (mg/l) (mg/l)  RCHRES Monthly values of water temperature QAL4 SQAL5 SQAL6 GQ-SEDCONC @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. ?!SQAL1 is the initial concentrations of qual on suspended sand. SQAL1 AFIELD4 aPy0. ?!SQAL2 is the initial concentrations of qual on suspended silt. SQAL2 BFIELD5 bPy0. ?"SQAL3 is the initial concentrations of qual on suspended clay. SQAL3 BFIELD6 bPy0. 9"SQAL4 is the initial concentrations of qual on bed sand. SQAL4 CFIELD7 cPy0. 9#SQAL5 is the initial concentrations of qual on bed silt. SQAL5 CFIELD8 cPy0. 9#SQAL6 is the initial concentrations of qual on bed clay. SQAL6 $Initial concentrations on sediment. (1X,6(1PE10.3))Initial concentrations on sediment (concu/mg):<---------Suspended-----------><-------------Bed-----------> Sand Silt Clay Sand Silt Clay  RCHRES TWAT PHVAL ROC CLD SDCNC PHY x - x deg F mole/l tenths mg/l mg/l GQ-VALUES @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPBTC60.p!TWAT is the constant annual value of water temperature;input only if TEMPFG = 2 in Table-type GQ-GENDATA.TWAT AFIELD4 aP?`A7. b!PHVAL is the constant annual value of pH; input only ifPHFLAG = 2 in Table-type GQ-GENDATA. PHVAL BFIELD5 bPy0. o"ROC is the constant annual value of free radical oxygen;input only if ROXFG = 2 in Table-type GQ-GENDATA. ROCBFIELD6 bP A0. d"CLD is the constant annual value of cloud cover; input onlyif CLDFG = 2 in Table-type GQ-GENDATA.CLDCFIELD7 cPy0. #SDCNC is the constant annualr rates between adsorbed and desorbedstates for qual with bed silt. ADPM52 CFIELD8 cP'7y-999. ^#ADPM(6,2) is the transfer rates between adsorbed and desorbedstates for qual with bed clay. ADPM62 (Adsorption /desorption rate parameters. (1X,6(1PE10.3))Adsorption/desorption rate parameters (/day) for:<--------Suspended-----------><------------Bed------------> Sand Silt Clay Sand Silt Clay  RCHRES Adsorption/desorption temp. correction parameters x - x ADPM(1,3) ADPM(2,3) ADPM(3,3) ADPM(4,3) ADPM(5,3) ADPM(6,3) GQ-ADTHETA @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP?@1.07 a!ADPM(1,3) is the temperature correction coefficient foradsorption/desorption on suspended sand. ADPM13 AFIELD4 aP?@1.07 a!ADPM(2,3) is the temperature correction coefficient foradsorption/desorption on suspended silt. ADPM23 BFIELD5 bP?@1.07 a"ADPM(3,3) is the temperature correction coefficient foradsorption/desorption on suspended clay. ADPM33 BFIELD6 bP?@1.07 ["ADPM(4,3) is the temperature correction coefficient foradsorption/desorption on bed sand. ADPM43 CFIELD7 cP?@1.07 [#ADPM(5,3) is the temperature correction coefficient foradsorption/desorption on bed silt. ADPM53 CFIELD8 cP?@1.07 [#ADPM(6,3) is the temperature correction coefficient foradsorption/desorption on bed clay. ADPM63 9Adsorption/desorption temperature correction parameters. (1X,6(1PE10.3))Adsorption/desorption temp correction parameters for:<--------Suspended-----------><------------Bed------------> Sand Silt Clay Sand Silt Clay  RCHRES Initial concentrations on sediment (concu/mg) x - x SQAL1 SQAL2 SQAL3 S DPM(6,1)  GQ-KD @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP.y-999. A!ADPM(1,1) is the distribution coefficient for qual with suspende ADPM11 AFIELD4 aP.y-999. A!ADPM(2,1) is the distribution coefficient for qual with suspende ADPM21 BFIELD5 bP.y-999. A"ADPM(3,1) is the distribution coefficient for qual with suspende ADPM31 BFIELD6 bP.y-999. A"ADPM(4,1) is the distribution coefficient for qual with bed sand ADPM41 CFIELD7 cP.y-999. A#ADPM(5,1) is the distribution coefficient for qual with bed silt ADPM51 CFIELD8 cP.y-999. A#ADPM(6,1) is the distribution coefficient for qual with bed clay ADPM61 Partition coefficients. (1X,6(1PE10.3))Partition coefficients (l/mg) for:<--------Suspended-----------><-------------Bed------------> Sand Silt Clay Sand Silt Clay  RCHRES Adsorption/desorption rate parameters (/day) x - x ADPM(1,2) ADPM(2,2) ADPM(3,2) ADPM(4,2) ADPM(5,2) ADPM(6,2) GQ-ADRATE @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP'7y-999. d!ADPM(1,2) is the transfer rates between adsorbed and desorbedstates for qual with suspended sand.ADPM12 AFIELD4 aP'7y-999. d!ADPM(2,2) is the transfer rates between adsorbed and desorbedstates for qual with suspended silt.ADPM22 BFIELD5 bP'7y-999. d"ADPM(3,2) is the transfer rates between adsorbed and desorbedstates for qual with suspended clay.ADPM32 BFIELD6 bP'7y-999. ^"ADPM(4,2) is the transfer rates between adsorbed and desorbedstates for qual with bed sand. ADPM42 CFIELD7 cP'7y-999. ^#ADPM(5,2) is the transfe!-999. BIOM11 FFIELD14f('7y-999. BIOM12 Monthly values of biomass. This table must be included inthe UCI only if GQPM2(7) is assigned a value of 3 in Table-type GQ-FLG2. (1X,12(1PE10.3))Values of biomass (mg/l) for start of each calendar month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC 4 RCHRES FSTDEC THFST x - x (/day) GQ-GENDECAY@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP'7y-999. 0!FSTDEC is the first order decay rate for qual.FSTDEC AFIELD4 aP?@1.07 R!THFST is the temperature correction coefficient for firstorder decay of qual. THFST Parameters for "general" decay.0 (1X,2(1PE10.3)) FSTDEC THFST (/day)\ RCHRES KSUSP THSUSP KBED THBED x - x /day /day GQ-SEDDECAY@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. F!KSUSP is the decay rate for qual adsorbed to suspendedsediment. ADDCP1 AFIELD4 aP?@1.07 \!THSUSP is the temperature correction coefficient for decayof qual on suspended sediment.ADDCP2 BFIELD5 bPy0. ="KBED is the decay rate for qual adsorbed to bed sediment. ADDCP3 BFIELD6 bP?@1.07 V"THBED is the temperature correction coefficient for decayof qual on bed sediment. ADDCP4 :Parameters for decay of contaminant adsorbed to sediment. (1X,4(1PE10.3))Decay rate (/day) & temp correction coeff. for qual on sediment:<----Suspended-----><-----Bed----------> Rate Theta Rate Theta  RCHRES Partition coefficients (l/mg) x - x ADPM(1,1) ADPM(2,1) ADPM(3,1) ADPM(4,1) ADPM(5,1) A"   RCHRES CFGAS x - x GQ-CFGAS @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP`B y-999. N!CFGAS is the ratio of volatilization rate of qual to oxygenreaeration rate. CFGAS .Ratio of volatilization to oxygen reaeration.  (1X,1(1PE10.3)) CFGAS R RCHRES BIOCON THBIO BIO x - x 1/mg/day mg/l GQ-BIOPM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP`B y-999. k!BIOCON is the second order rate constant for biomassconcentration causing biodegradation of qual. BIOCON AFIELD4 aP?@1.07 U!THBIO is the temperature correction coefficient forbiodegradation of qual. THBIO BFIELD5 bP'7y-999. F"BIO is the concentration of biomass causing biodegradationof qual. BIOBiodegradation parameters. N (1X,3(1PE10.3)) BIOCON THBIO BIO(1/mg/day) (mg/l) s RCHRES Monthly values of biomas (mg/l) x - x BM1 BM2 BM3 BM4 BM5 BM6 BM7 BM8 BM9 BM10 BM11 BM12  MON-BIO@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a('7y-999. e!BIOM(1) through BIOM(12) are monthly concentrations ofbiomass causing biodegradation of qual. BIOM1 AFIELD4 a('7y-999. BIOM2 BFIELD5 b('7y-999. BIOM3 BFIELD6 b('7y-999. BIOM4 CFIELD7 c('7y-999. BIOM5 CFIELD8 c('7y-999. BIOM6 DFIELD9 d('7y-999. BIOM7 DFIELD10d('7y-999. BIOM8 EFIELD11e('7y-999. BIOM9 EFIELD12e('7y-999. BIOM10 FFIELD13f('7y#! KB KN THHYD (/M-sec) (/M-sec) (/sec)4 RCHRES KOX THOX x - x /M.sec GQ-ROXPM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP`B y-999. U!KOX is the second order rate constant for oxidation of qualby free radical oxygen. KOXAFIELD4 aP?@1. g!THOX is the temperature correction coefficient foroxidation of qual by free radical oxygen. THOX 'Parameters for free radical oxidation. 0 (1X,2(1PE10.3)) KOX THOX (/M.sec) K1 K2 K3 K4 K5 K6 K7 RCHRES K8 K9 K10 K11 K12 K13 K14 x - x K15 K16 K17 K18 PHI THETA GQ-PHOTPM @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 a Py0. !PHOTPM(1) through PHOTPM(18) are molar absorptioncoefficients for qual for 18 wavelength ranges of light (seefunctional description for subroutine DDECAY in Part E). PHOTP1 AFIELD4 aPy0. PHOTP2 BFIELD5 bPy0. PHOTP3 BFIELD6 b'Py0. PHOTP4 CFIELD7 c1Py0. PHOTP5 CFIELD8 c;Py0. PHOTP6 DFIELD9 dEPy0. PHOTP7 Parameters for photolysis.**NOTE**1. No blank or "comment" lines may be put between any of thelines for a continued entry. Put all comments ahead of theentry. 2. The specification must be repeated for eachline onto which the entry is continued. (1X,9(1PE10.3),/,1X,9(1PE10.3),/,1X,2(1PE10.3))Items 1 thru 18 below are molar absorption coefficients, for each of the 18 wavelengths (l/mole.cm).Item 19 is the quantum yield (mole/Einstein).Item 20 is the temperature correction parameter (theta).$"Q!GQPM2(1): value of 1 indicates qual is a "daughter" productthrough hydrolysis. GQPM21 AFIELD4 a(0 P!GQPM2(2): value of 1 indicates qual is a "daughter" productthrough oxidation.GQPM22 BFIELD5 b(0 Q"GQPM2(3): value of 1 indicates qual is a "daughter" productthrough photolysis. GQPM23 BFIELD6 b(0 U"GQPM2(4): value of 1 indicates qual is a "daughter" productthrough volatilization. GQPM24 CFIELD7 c(0 U#GQPM2(5): value of 1 indicates qual is a "daughter" productthrough biodegradation. GQPM25 CFIELD8 c(0 `#GQPM2(6): value of 1 indicates qual is a "daughter" productthrough general first-order decay.GQPM26 DFIELD9 d(2 $GQPM2(7) indicates the source of biomass data for qual; 1means a time series, 2 means an annual value, and 3 means 12monthly values. Input only if QALFG(5)=1.GQPM27 Second set of flags for a qual. (1X,6I10,I15) <-Flags indicating whether qual is a daughter through--> Source of Hydrol Oxid Photol Volatil Biodeg General biomass data \ RCHRES KA KB KN THHYD x - x /M-sec /M-sec /sec GQ-HYDPM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP`B y-999. C!KA is the second order acid rate constant for hydrolysis ofqual. KA AFIELD4 aP`B y-999. C!KB is the second order base rate constant for hydrolysis ofqual. KB BFIELD5 bP`B y-999. P"KN is the second order rate constant for neutral reactionof qual with waterKN BFIELD6 bP?@1. Q"THHYD is the temperature correction coefficient forhydrolysis of qual. THHYD Hydrolysis parameters. X (1X,4(1PE10.3)) KA %# characters may be supplied as the"qty" unit for the qual. QTYID specifies the units in whichthe total flow of qual into, or out of the RCHRES will beexpressed. QTYID c@3Data for a generalized quality constituent (qual). (1X,5A4,1(1PE10.3),6X,A4,1PE10.3,2X,2A4) Substance id Concentration Conv Qty- Init-val Units(/l) fact id 9 RCHRES HDRL OXID PHOT VOLT BIOD GEN SDAS x - x GQ-QALFG @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(0 M!QALFG(1): value of 1 indicates hydrolysis is considered fordissolved qual. QALFG1 AFIELD4 a(0 f!QALFG(2): value of 1 indicates oxidation by free radicaloxygen is considered for dissolved qual. QALFG2 BFIELD5 b(0 M"QALFG(3): value of 1 indicates photolysis is considered fordissolved qual. QALFG3 BFIELD6 b(0 Q"QALFG(4): value of 1 indicates volatilization is consideredfor dissolved qual. QALFG4 CFIELD7 c(0 Q#QALFG(5): value of 1 indicates biodegradation is consideredfor dissolved qual. QALFG5 CFIELD8 c(0 \#QALFG(6): value of 1 indicates general first order decay isconsidered for dissolved qual.QALFG6 DFIELD9 d(0 $QALFG(7): value of 1 indicates qual is associated withsediment. If so, adsorption/desorption of qual isconsidered. QALFG7 First set of flags for a qual. (1X,7I10) <-----------Degradation process flags -----------------> Sediment Hydrol Oxid Photol Volatil Biodeg General assoc9 RCHRES HDRL OXID PHOT VOLT BIOD GEN SBMS x - x  GQ-FLG2@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(0 &$tyconstituent #6 in precipitation is either absent or is supplied as adirect time series as GQADCN. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. GQADFG(12) FGFIELD15g0 'Value of 0 indicates that atmospheric deposition flux of generalizedquality constituent #7 is either absent or is supplied as a direct timeseries as GQADFX. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. GQADFG(13) GGFIELD16g0 'Value of 0 indicates that concentration of generalized qualityconstituent #7 in precipitation is either absent or is supplied as adirect time series as GQADCN. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. GQADFG(14) G (1X,7(1X,2I4))Atmospheric Deposition Flags GQUAL1 GQUAL2 GQUAL3 GQUAL4 GQUAL5 GQUAL6 GQUAL7 FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CONp RCHRES GQID DQAL CONCID CONV QTYID x - x concid GQ-QALDATA @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 e!Any string of up to 20 characters may be supplied as thename of the quality constituent (qual). GQID aAFIELD4 aPy0. 0!DQAL is the initial concentration of the qual.DQAL BFIELD5 "Any string of up to 8 characters may be supplied as theconcentration units (implied that it is "per liter"), eg."mg"(/l).CONCID b BFIELD6 bP`B y-999. "CONV is the factor to convert from Qty/Vol to concentrationunits: Conc= CONV* Qty/Vol (in English system, Vol is inft3) (in Metric system, Vol is in m3). CONV CFIELD7 #Any string of up to 8'%s GQADCN. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. GQADFG(6) CDFIELD9 d0 $Value of 0 indicates that atmospheric deposition flux of generalizedquality constituent #4 is either absent or is supplied as a direct timeseries as GQADFX. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. GQADFG(7) DDFIELD10d0 $Value of 0 indicates that concentration of generalized qualityconstituent #4 in precipitation is either absent or is supplied as adirect time series as GQADCN. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. GQADFG(8) DEFIELD11e0 %Value of 0 indicates that atmospheric deposition flux of generalizedquality constituent #5 is either absent or is supplied as a direct timeseries as GQADFX. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. GQADFG(9) EEFIELD12e0 %Value of 0 indicates that concentration of generalized qualityconstituent #5 in precipitation is either absent or is supplied as adirect time series as GQADCN. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. GQADFG(10) EFFIELD13f0 &Value of 0 indicates that atmospheric deposition flux of generalizedquality constituent #6 is either absent or is supplied as a direct timeseries as GQADFX. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. GQADFG(11) FFFIELD14f0 &Value of 0 indicates that concentration of generalized quali(&FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a0 !Value of 0 indicates that atmospheric deposition flux of generalizedquality constituent #1 is either absent or is supplied as a direct timeseries as GQADFX. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. GQADFG(1) AAFIELD4 a0 !Value of 0 indicates that concentration of generalized qualityconstituent #1 in precipitation is either absent or is supplied as adirect time series as GQADCN. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. GQADFG(2) ABFIELD5 b0 "Value of 0 indicates that atmospheric deposition flux of generalizedquality constituent #2 is either absent or is supplied as a direct timeseries as GQADFX. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. GQADFG(3) BBFIELD6 b0 "Value of 0 indicates that concentration of generalized qualityconstituent #2 in precipitation is either absent or is supplied as adirect time series as GQADCN. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. GQADFG(4) BCFIELD7 c0 #Value of 0 indicates that atmospheric deposition flux of generalizedquality constituent #3 is either absent or is supplied as a direct timeseries as GQADFX. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. GQADFG(5) CCFIELD8 c0 #Value of 0 indicates that concentration of generalized qualityconstituent #3 in precipitation is either absent or is supplied as adirect time series a)'2 !TEMPFG indicates the source of water temperature data; 1means a time series (either input or computed), 2 means anannual value, and 3 means 12 monthly values. TEMPFG BFIELD5 b(2 "PHFLAG indicates the source of pH data; 1 means a timeseries (either input or computed), 2 means an annual value,and 3 means 12 monthly values. Input only if any QALFG(1)=1. PHFLAG BFIELD6 b(2 ǀ"ROXFG indicates the source of free radical oxygen data; 1means a time series (either input or computed), 2 means anannual value, and 3 means 12 monthly values. Input only ifany QALFG(2)=1. ROXFG CFIELD7 c(2 #CLDFG indicates the source of cloud cover data; 1 means atime series (either input or computed), 2 means an annualvalue, and 3 means 12 monthly values. Input only if anyQALFG(3)=1. CLDFG CFIELD8 c(2 π#SDFG indicates the source of total sediment concentrationdata; 1 means a time series (either input or computed), 2means an annual value, and 3 means 12 monthly values. Inputonly if any QALFG(3)=1. SDFG DFIELD9 d(2 $PHYTFG indicates the source of phytoplankton data; 1 meansa time series (either input or computed), 2 means an annualvalue, and 3 means 12 monthly values. Input only if anyQALFG(3)=1. PHYTFG DFIELD10d(60 l$LAT is the latitude of the RCHRES. Input only if anyQALFG(3)=1. Positive for northern hemisphere.LAT!General input for Section GQUAL. (1X,8I10) NGQUAL <----Flags indicating sources of input data------------> Latitude TEMPFG PHFLAG ROXFG CLDFG SDFG PHYTFG (Degrees)  Atmospheric Deposition Flags RCHRES GQUAL1 GQUAL2 GQUAL3 GQUAL4 GQUAL5 GQUAL6 GQUAL7 x - x GQ-AD-FLAGS@@*(8?1. j!The initial fraction (by weight) of sand in the bed materialThe sum of the three fractions must be 1.00. SANDFR BFIELD5 bPr?0. j"The initial fraction (by weight) of silt in the bed materialThe sum of the three fractions must be 1.00. SILTFR BFIELD6 bPr?0. j"The initial fraction (by weight) of clay in the bed materialThe sum of the three fractions must be 1.00. CLAYFR #Initial fractions of bed sediment. (1X,4(1PE10.3))Init bed Initial fraction of each sizethickness of sediment in the bed (ft) Sand Silt Clay a RCHRES BEDDEP Initial bed composition x - x (m) Sand Silt Clay BED-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. ;!BEDDEP is the initial total depth (thickness) of the bed. BEDDEP AFIELD4 aP8?1. j!The initial fraction (by weight) of sand in the bed materialThe sum of the three fractions must be 1.00. SANDFR BFIELD5 bPr?0. j"The initial fraction (by weight) of silt in the bed materialThe sum of the three fractions must be 1.00. SILTFR BFIELD6 bPr?0. j"The initial fraction (by weight) of clay in the bed materialThe sum of the three fractions must be 1.00. CLAYFR #Initial fractions of bed sediment. (1X,4(1PE10.3))Init bed Initial fraction of each sizethickness of sediment in the bed (m) Sand Silt Clay f RCHRES NGQL TPFG PHFG ROFG CDFG SDFG PYFG LAT x - x deg GQ-GENDATA @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(1 N!NGQUAL is the number of generalized constituents (quals)being simulated. NGQUAL AFIELD4 a(+)he particles in still water. W BFIELD5 bP@@2.65 &"RHO is the density of the particles. RHOBFIELD6 bP.y1.0E10 "TAUCD is the critical bed shear stress for deposition.Above this stress, there will be no deposition; as thestress drops below this value to zero, deposition willgradually increase to the value implied by the fall velocityin still water.TAUCD CFIELD7 cP.y1.0E10 #TAUCS is the critical bed shear stress for scour. Belowthis value, there will be no scour; above it, scour willsteadily increase. In general TAUCD should be less than orequal to TAUCS. TAUCS CFIELD8 cPy0. 3#M is the erodibility coefficient of the sediment. M Parameters for silt or clay. (1X,6(1PE10.3)) D W RHO TAUCD TAUCS M (mm) (mm/sec) (gm/cm3) (kg/m2) (kg/m2)(kg/m2.dy) S RCHRES Suspended sed concs (mg/l) x - x Sand Silt Clay SSED-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. 4!The initial concentration (in suspension) of sand.SSED1 AFIELD4 aPy0. 4!The initial concentration (in suspension) of silt.SSED2 BFIELD5 bPy0. 4"The initial concentration (in suspension) of clay.SSED3 .Initial concentrations of suspended sediment. n (1X,3(1PE10.3)) Suspended sed concs (mg/l) SSED(1) SSED(2) SSED(3) (mg/l) (mg/l) (mg/l) a RCHRES BEDDEP Initial bed composition x - x (ft) Sand Silt Clay BED-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. ;!BEDDEP is the initial total depth (thickness) of the bed. BEDDEP AFIELD4 aP,*ndload inputpower function formula. EXPSND Parameters related to sand.X (1X,5(1PE10.3)) D W RHO KSAND EXPSND (mm) (mm/sec) RCHRES D W RHO TAUCD TAUCS M x - x (in) (in/sec) gm/cm3 lb/ft2 lb/ft2 lb/ft2.d SILT-CLAY-PM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPD;0. /!D is the effective diameter of the particles. D AFIELD4 aPL>0. 9!W is the fall velocity of the particles in still water. W BFIELD5 bP@@2.65 &"RHO is the density of the particles. RHOBFIELD6 bP.y1.0E10 "TAUCD is the critical bed shear stress for deposition.Above this stress, there will be no deposition; as thestress drops below this value to zero, deposition willgradually increase to the value implied by the fall velocityin still water.TAUCD CFIELD7 cP.y1.0E10 #TAUCS is the critical bed shear stress for scour. Belowthis value, there will be no scour; above it, scour willsteadily increase. In general TAUCD should be less than orequal to TAUCS. TAUCS CFIELD8 cPy0. 3#M is the erodibility coefficient of the sediment. M Parameters for silt or clay. (1X,6(1PE10.3)) D W RHO TAUCD TAUCS M (in) (in/sec) (gm/cm3) (lb/ft2) (lb/ft2)(lb/ft2.d)  RCHRES D W RHO TAUCD TAUCS M x - x (mm) (mm/sec) gm/cm3 kg/m2 kg/m2 kg/m2.dy SILT-CLAY-PM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP)\=0. /!D is the effective diameter of the particles. D AFIELD4 aP@0. 9!W is the fall velocity of t-+D1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPn:B-999. !D is the effective diameter of the transported sandparticles. Note that the transport formulae do not actuallyuse D (they use DB50, supplied in Table-type HYDR-PARM2). Dis included here for consistency with the input data suppliedfor cohesive sediment.D AFIELD4 aP ף<C-999. J!W is the fall velocity of transported sand particles instill water. W BFIELD5 bP?@2.65 +"RHO is the density of the sand particles. RHOBFIELD6 bPy0. U"KSAND is the coefficient in the "old" HSPF sandload inputpower function formula. KSAND CFIELD7 cPy0. U#EXPSND is the exponent in the "old" HSPF sandload inputpower function formula. EXPSND Parameters related to sand.X (1X,5(1PE10.3)) D W RHO KSAND EXPSND (in) (in/sec)f RCHRES D W RHO KSAND EXPSND x - x (mm) (mm/sec) (gm/cm3)  SAND-PM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP<@E-999. !D is the effective diameter of the transported sandparticles. Note that the transport formulae do not actuallyuse D (they use DB50, supplied in Table-type HYDR-PARM2). Dis included here for consistency with the input data suppliedfor cohesive sediment.D AFIELD4 aP?PCF-999. J!W is the fall velocity of transported sand particles instill water. W BFIELD5 bP?@2.65 +"RHO is the density of the sand particles. RHOBFIELD6 bPy0. U"KSAND is the coefficient in the "old" HSPF sandload inputpower function formula. KSAND CFIELD7 cPy0. U#EXPSND is the exponent in the "old" HSPF sa.,olby method.) DELTH BFIELD5 bP8B0.01 "DB50 is the median diameter of the bed sediment (assumedconstant throughout the run). This value is used tocalculate the bed shear stress if the RCHRES is a lake, orcalculate the rate of sand transport if the Colby orToffaleti methods are used.DB50 RCHRES geometrical parameters. This table is only required andread if Section HYDR is not active. Nornally these parametersare supplied in Table-type HYDR-PARM2.N (1X,3(1PE10.3)) LEN DELTH DB50 (miles) (ft) (in) R RCHRES LEN DELTH DB50 x - x (km) (m) (mm) SED-HYDPARM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPn<y-999. "!LEN is the length of the RCHRES. LENAFIELD4 aPy0. ^!DELTH is the drop in water elevation from the upstream tothe downstream extremities of the RCHRES. (It is used ifsection OXRX is active and reaeration is being computedusing the Tsivoglou-Wallace equation; or if section SEDTRNis active and sandload transport capacity is being computedusing either the Toffaleti or Colby method.) DELTH BFIELD5 bP #;@E0.25 "DB50 is the median diameter of the bed sediment (assumedconstant throughout the run). This value is used tocalculate the bed shear stress if the RCHRES is a lake, orcalculate the rate of sand transport if the Colby orToffaleti methods are used.DB50 RCHRES geometrical parameters. This table is only required andread if Section HYDR is not active. Nornally these parametersare supplied in Table-type HYDR-PARM2.N (1X,3(1PE10.3)) LEN DELTH DB50 (km) (m) (m) f RCHRES D W RHO KSAND EXPSND x - x (in) (in/sec) (gm/cm3)  SAND-PM@@FIEL/- the depth of bedsediment. BEDWID AFIELD4 aPn:y100. u!BEDWRN is the bed depth which, if exceeded (eg, throughdeposition) will cause a warning message to be printed. BEDWRN BFIELD5 bP=gff?0.5_"POR is the porosity of the bed (volume voids/total volume).It is used to estimate bed depth. POR%General sediment related parameters. D (1X,3(1PE10.3)) BEDWID BEDWRN POR (ft) (ft)H RCHRES BEDWID BEDWRN POR x - x (m) (m) SED-GENPARM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP>y-999. !BEDWID is the width of the cross-section over which HSPFwill assume bed sediment is deposited regardless of stage,top-width, etc. It is used to estimate the depth of bedsediment. BEDWID AFIELD4 aPPI9y30.5 u!BEDWRN is the bed depth which, if exceeded (eg, throughdeposition) will cause a warning message to be printed. BEDWRN BFIELD5 bP=gff?0.5_"POR is the porosity of the bed (volume voids/total volume).It is used to estimate bed depth. POR%General sediment related parameters. D (1X,3(1PE10.3)) BEDWID BEDWRN POR (m) (m)R RCHRES LEN DELTH DB50 x - x (miles) (ft) (in) SED-HYDPARM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP #<y-999. "!LEN is the length of the RCHRES. LENAFIELD4 aPy0. ^!DELTH is the drop in water elevation from the upstream tothe downstream extremities of the RCHRES. (It is used ifsection OXRX is active and reaeration is being computedusing the Tsivoglou-Wallace equation; or if section SEDTRNis active and sandload transport capacity is being computedusing either the Toffaleti or C0.y0.0DELTT5 CFIELD7 cPyy0.0DELTT6 DFIELD8 dPyy0.0DELTT7 M (1X,7(1PE10.3)) Initial water temperature changes for Jobson method (deg C) > RCHRES TW AIRTMP x - x (deg F) (deg F) HEAT-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPBHC60.4!TW is the initial water temperature in the RCHRES.TW AFIELD4 aPC60.6!AIRTMP is the initial air temperature at the RCHRES. AIRTMP &Initial conditions for section HTRCH. : (1X,2(1PE10.3)) TW AIRTMP (deg F) (deg F) > RCHRES TW AIRTMP x - x (deg C) (deg C) HEAT-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPB15.5 4!TW is the initial water temperature in the RCHRES.TW AFIELD4 aPB15.5 6!AIRTMP is the initial air temperature at the RCHRES. AIRTMP &Initial conditions for section HTRCH. : (1X,2(1PE10.3)) TW AIRTMP (deg C) (deg C)  RCHRES x - x SNDFG SANDFG @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(3 !SANDFG indicates the method that will be used for sandloadsimulation; 1 means Toffaleti method, 2 means Colby method,and 3 means the "old" HSPF input power function method. SANDFG Sandload method flag (RCHRES).  (1X,I10) SNDFGH RCHRES BEDWID BEDWRN POR x - x (ft) (ft) SED-GENPARM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP?y-999. !BEDWID is the width of the cross-section over which HSPFwill assume bed sediment is deposited regardless of stage,top-width, etc. It is used to estimate1/ifferences for Jobson bed conductance method (deg F) DELTT DELTT DELTT DELTT DELTT DELTT DELTT RCHRES 1 2 3 4 5 6 7 x - x 8 9 10 11 12 13 etc. HT-BED-DELTT @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD2 aPyy0.0! DELTT are the initial water temperature changes for the past TSTOP time intervals (see Table-type HT-BED-FLAGS); used for Jobson method (BEDFLG = 3). A maximum of 100 values are allowed. DELTT values are positive if the water temperature is increasing. DELTT1 AFIELD3 aPyy0.0DELTT2 BFIELD4 bPyy0.0DELTT3 BFIELD5 bPyy0.0DELTT4 CFIELD6 cPyy0.0DELTT5 CFIELD7 cPyy0.0DELTT6 DFIELD8 dPyy0.0DELTT7 M (1X,7(1PE10.3)) Initial water temperature changes for Jobson method (deg F) 9 Initial temp differences for Jobson bed conductance method (deg C) DELTT DELTT DELTT DELTT DELTT DELTT DELTT RCHRES 1 2 3 4 5 6 7 x - x 8 9 10 11 12 13 etc. HT-BED-DELTT @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD2 aPyy0.0! DELTT are the initial water temperature changes for the past TSTOP time intervals (see Table-type HT-BED-FLAGS); used for Jobson method (BEDFLG = 3). A maximum of 100 values are allowed. DELTT values are positive if the water temperature is increasing. DELTT1 AFIELD3 aPyy0.0DELTT2 BFIELD4 bPyy0.0DELTT3 BFIELD5 bPyy0.0DELTT4 CFIELD6 cPy20D1 " RCHRES to which these data apply. OPNID `AAFIELD2 aPyy0.0*! DELH are the bed-to-water heat fluxes per degree change in water temperature for the past TSTOP time intervals (see Table-type HT-BED-FLAGS); used for Jobson method (BEDFLG = 3). A maximum of 100 values are allowed. DELH values should be negative. Note: DELH values are time-step dependent. DELH1 AFIELD3 aPyy0.0DELH2 BFIELD4 bPyy0.0DELH3 BFIELD5 bPyy0.0DELH4 CFIELD6 cPyy0.0DELH5 CFIELD7 cPyy0.0DELH6 DFIELD8 dPyy0.0DELH7 Q (1X,7(1PE10.3)) Sediment-to-water heat fluxes for Jobson method (BTU/ft2.F.ivl) 6 Heat fluxes for Jobson bed conductance method (kcal/m2.C.ivl) DELH DELH DELH DELH DELH DELH DELH RCHRES 1 2 3 4 5 6 7 x - x 8 9 10 11 12 13 etc. HT-BED-DELH@@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD2 aPyy0.0*! DELH are the bed-to-water heat fluxes per degree change in water temperature for the past TSTOP time intervals (see Table-type HT-BED-FLAGS); used for Jobson method (BEDFLG = 3). A maximum of 100 values are allowed. DELH values should be negative. Note: DELH values are time-step dependent. DELH1 AFIELD3 aPyy0.0DELH2 BFIELD4 bPyy0.0DELH3 BFIELD5 bPyy0.0DELH4 CFIELD6 cPyy0.0DELH5 CFIELD7 cPyy0.0DELH6 DFIELD8 dPyy0.0DELH7 Q (1X,7(1PE10.3)) Sediment-to-water heat fluxes for Jobson method (kcal/m2.C.ivl) : Initial temp d3159.TGRND9 EFIELD12e(`AB59.TGRND10FFIELD13f(`AB59.TGRND11FFIELD14f(`AB59.TGRND12i Monthly ground temperatures; input only if BEDFLG = 1 or 2, and TGFLG = 3 in Table-type HT-BED-FLAGS. (1X,12(1PE10.3)) Monthly ground temperatures (deg F) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC RCHRES Monthly values of ground temperatures (deg C) x - x TG1 TG2 TG3 TG4 TG5 TG6 TG7 TG8 TG9 TG10 TG11 TG12 MON-HT-TGRND @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a( 4B15.-!TGRND1 is the ground temperature in January. TGRND1 AFIELD4 a( 4B15.TGRND2 BFIELD5 b( 4B15.TGRND3 BFIELD6 b( 4B15.TGRND4 CFIELD7 c( 4B15.TGRND5 CFIELD8 c( 4B15.TGRND6 DFIELD9 d( 4B15.TGRND7 DFIELD10d( 4B15.TGRND8 EFIELD11e( 4B15.TGRND9 EFIELD12e( 4B15.TGRND10FFIELD13f( 4B15.TGRND11FFIELD14f( 4B15.TGRND12i Monthly ground temperatures; input only if BEDFLG = 1 or 2, and TGFLG = 3 in Table-type HT-BED-FLAGS. (1X,12(1PE10.3)) Monthly ground temperatures (deg C) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC7 Heat fluxes for Jobson bed conductance method (BTU/ft2.F.ivl) DELH DELH DELH DELH DELH DELH DELH RCHRES 1 2 3 4 5 6 7 x - x 8 9 10 11 12 13 etc. HT-BED-DELH@@FIEL42D (1X,7(1PE10.3)) Heat conductance parameters for single and two-layer methods MUDDEP TGRND KMUD KGRND (ft) (deg F) (kcal/m2.C.hr)  Bed Heat Conduction Parameters for Single and Two-layer Methods RCHRES MUDDEP TGRND KMUD KGRND x - x (m) (deg C) (kcal/m2/C/hr) HT-BED-PARM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD2 aP #<y0.1Y! Depth of mud layer; used for two-layer method (BEDFLG = 2 in Table-type HT-BED-FLAGS). MUDDEP AFIELD3 aP 4B15.! Temperature of ground if constant; used for single layer and two layer methods (BEDFLG = 1 or 2, and TGFLG = 2, in Table-type HT-BED-FLAGS). TGRND BFIELD4 bPy50.n" Heat conductance coefficient between water and the ground (if BEDFLG = 1) or the mud layer (if BEDFLG = 2). KMUD BFIELD5 bPy1.4Z" Heat conductance coefficient between the ground and the mud layer (used if BEDFLG = 2). KGRND (1X,7(1PE10.3)) Heat conductance parameters for single and two-layer methods MUDDEP TGRND KMUD KGRND (ft) (deg C) (kcal/m2.C.hr)  RCHRES Monthly values of ground temperatures (deg F) x - x TG1 TG2 TG3 TG4 TG5 TG6 TG7 TG8 TG9 TG10 TG11 TG12 MON-HT-TGRND @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(`AB59.-!TGRND1 is the ground temperature in January. TGRND1 AFIELD4 a(`AB59.TGRND2 BFIELD5 b(`AB59.TGRND3 BFIELD6 b(`AB59.TGRND4 CFIELD7 c(`AB59.TGRND5 CFIELD8 c(`AB59.TGRND6 DFIELD9 d(`AB59.TGRND7 DFIELD10d(`AB59.TGRND8 EFIELD11e(`AB53 KEVAP x - x (m) (m) HEAT-PARM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP@F0. $!ELEV is the mean RCHRES elevation.ELEV AFIELD4 aPyy0. !ELDAT is the difference in elevation between the RCHRES andthe air temperature gage (positive if RCHRES is higher thanthe gage). ELDAT BFIELD5 bPn:@1. x"CFSAEX is the correction factor for solar radiation (itincludes fraction of RCHRES surface exposed to radiation).CFSAEX BFIELD6 bP?A9.37 ."KATRAD is the longwave radiation coefficient KATRAD CFIELD7 cP?A6.12 J#KCOND is the conduction-convection heat transportcoefficient. KCOND CFIELD8 cP? A2.24 '#KEVAP is the evaporation coefficient. KEVAP Parameters for section HTRCH. b (1X,6(1PE10.3)) ELEV ELDAT CFSAEX KATRAD KCOND KEVAP (m) (m)  Bed Heat Conduction Parameters for Single and Two-layer Methods RCHRES MUDDEP TGRND KMUD KGRND x - x (ft) (deg F) (kcal/m2/C/hr) HT-BED-PARM@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD2 aP #<y0.33 Y! Depth of mud layer; used for two-layer method (BEDFLG = 2 in Table-type HT-BED-FLAGS). MUDDEP AFIELD3 aP`AB59.! Temperature of ground if constant; used for single layer and two layer methods (BEDFLG = 1 or 2, and TGFLG = 2, in Table-type HT-BED-FLAGS). TGRND BFIELD4 bPy50.n" Heat conductance coefficient between water and the ground (if BEDFLG = 1) or the mud layer (if BEDFLG = 2). KMUD BFIELD5 bPy1.4Z" Heat conductance coefficient between the ground and the mud layer (used if BEDFLG = 2). KGRN64@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD2 a(0 ! Bed conductance flag: 0 - bed conductance not simulated 1 - single layer heat transfer method 2 - two layer heat transfer method 3 - Jobson method BEDFLG AFIELD3 a(2 ! TGFLG specifies the source of the ground temperature for either the the single layer or two layer heat transfer methods (BEDFLG = 1 or 2). TGFLG BFIELD4 b(d55 " TSTOP is the number of prior timesteps that impact the heat flux at the current timestep when using the Jobson method (BEDFLG = 3). TSTOP ) (1X,7I10) BEDFLG TGFLG TSTOP f RCHRES ELEV ELDAT CFSAEX KATRAD KCOND KEVAP x - x (ft) (ft) HEAT-PARM @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP`F0. $!ELEV is the mean RCHRES elevation.ELEV AFIELD4 aPyy0. !ELDAT is the difference in elevation between the RCHRES andthe air temperature gage (positive if RCHRES is higher thanthe gage). ELDAT BFIELD5 bPn:@1. x"CFSAEX is the correction factor for solar radiation (itincludes fraction of RCHRES surface exposed to radiation).CFSAEX BFIELD6 bP?A9.37 ."KATRAD is the longwave radiation coefficient KATRAD CFIELD7 cP?A6.12 J#KCOND is the conduction-convection heat transportcoefficient. KCOND CFIELD8 cP? A2.24 '#KEVAP is the evaporation coefficient. KEVAP Parameters for section HTRCH. b (1X,6(1PE10.3)) ELEV ELDAT CFSAEX KATRAD KCOND KEVAP (ft) (ft) f RCHRES ELEV ELDAT CFSAEX KATRAD KCOND 75j0 *Value of 0 indicates that concentration of conservative constituent #10in precipitation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(20) J7Conservative constituent atmospheric deposition flags.  (1X,10(2X,2I4)) Atmospheric Deposition Flags CONS1 CONS2 CONS3 CONS4 CONS5 CONS6 CONS7 CONS8 CONS9 CONS10 FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON R RCHRES x - x Substance-id Conc ID CONV QTYID CONS-DATA @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 c!Any string of up to 20 characters may be supplied as thename of the conservative constituent. CONID aAFIELD4 aPy0. 7!CON is the initial concentration of the conservative. CONBFIELD5 w"CONCID is a string of up to 8 characters which specifiesthe concentration units for the conservative constituent. CONCID b@BFIELD6 bP`B y-999. "CONV is the conversion factor from QTYID/VOL to the desiredconcentration units (CONCID): CONC = CONV*(QTY/VOL). IfUUNITS is 1, VOL is in ft3; if it is 2, VOL is in m3.CONV CFIELD7 #QTYID is a string of up to 8 characters which specifies theunits in which the total flow of constituent into, or outof, the RCHRES will be expressed, eg "kg". QTYID c@.Information about one conservative substance. (1X,5A4,1(1PE10.3),2X,2A4,1(1PE10.3),2X,2A4) Substance id Concentration Conv Qty- Init-val Units fact id @ RCHRES Bed Heat Conductance Flags x - x BDFG TGFG TSTP HT-BED-FLAGS 86t concentration of conservative constituent #7in precipitation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(14) GHFIELD17h0 (Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #8 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(15) HHFIELD18h0 (Value of 0 indicates that concentration of conservative constituent #8in precipitation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(16) HIFIELD19i0 )Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #9 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(17) IIFIELD20i0 )Value of 0 indicates that concentration of conservative constituent #9in precipitation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(18) IJFIELD21j0 *Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #10 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(19) JJFIELD2297itation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(8) DEFIELD11e0 %Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #5 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(9) EEFIELD12e0 %Value of 0 indicates that concentration of conservative constituent #5in precipitation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(10) EFFIELD13f0 &Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #6 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(11) FFFIELD14f0 &Value of 0 indicates that concentration of conservative constituent #6in precipitation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(12) FGFIELD15g0 'Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #7 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(13) GGFIELD16g0 'Value of 0 indicates tha:8series as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(2) ABFIELD5 b0 "Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #2 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(3) BBFIELD6 b0 "Value of 0 indicates that concentration of conservative constituent #2in precipitation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(4) BCFIELD7 c0 #Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #3 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(5) CCFIELD8 c0 #Value of 0 indicates that concentration of conservative constituent #3in precipitation is either absent or is supplied as a direct timeseries as COADCN. A value greater than 0 indicates the index number ofthe MONTH-DATA block to be used to supply atmospheric deposition data. COADFG(6) CDFIELD9 d0 $Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #4 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(7) DDFIELD10d0 $Value of 0 indicates that concentration of conservative constituent #4in precip;9 simulation. Input of this value is not necessary ifsection HYDR is active. VOLData for section ADCALC. : (1X,2(1PE10.3)) CRRAT VOL (acre-ft) I RCHRES Data for section ADCALC x - x CRRAT VOL (Mm3) ADCALC-DATA@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP?y1.5u!CRRAT is the ratio of maximum velocity to mean velocity inthe RCHRES cross section under typical flow conditions. CRRAT AFIELD4 aPy0. !VOL is the volume of water in the RCHRES at the start ofthe simulation. Input of this value is not necessary ifsection HYDR is active. VOLData for section ADCALC. : (1X,2(1PE10.3)) CRRAT VOL (Mm3)  RCHRES x - xNCONS  NCONS @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a( 1 :!NCONS is the no. of conservative constituents simulated. NCONS 9Number of conservative constituents simulated in RCHRES.  (1X,I10) NCONS Atmospheric Deposition Flags RCHRES CONS1 CONS2 CONS3 CONS4 CONS5 CONS6 CONS7 CONS8 CONS9 CONS10 x - x  CONS-AD-FLAGS @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 a0 !Value of 0 indicates that atmospheric deposition flux of conservativeconstituent #1 is either absent or is supplied as a direct time seriesas COADFX. A value greater than 0 indicates the index number of theMONTH-DATA block to be used to supply atmospheric deposition data. COADFG(1) AAFIELD4 a0 !Value of 0 indicates that concentration of conservative constituent #1in precipitation is either absent or is supplied as a direct time<:ority COTDGT x - x (yyyy/mm/dd)(m3/s) (yyyy/mm/dd)(m3/s) HYDR-CDEMAND @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 ! Category for this fraction. CTAG1 a AFIELD4 a@0.0'! Exit from which this demand is drawn. CEXIT1 BFIELD5 " Priority of this category. This can be either a real number or a date in the format ' YYYY/MM/DD '. Earlier dates are higher priority. Blank or zero priority is considered lowest priority. CPRI1 b`BFIELD6 b0y0.0)" Initial value of the COTDGT timeseries. CDEM1 CFIELD7 # Category for this fraction. CTAG2 c# CFIELD8 c@0.0'# Exit from which this demand is drawn. CEXIT2 DFIELD9 $ Priority of this category. This can be either a real number or a date in the format ' YYYY/MM/DD '. Earlier dates are higher priority. Blank or zero priority is considered lowest priority. CPRI2 d)`DFIELD10d0y0.0*$ Initial value of this COTDGT timeseries. CDEM2  (1X,2(A10,F10.0,A20,1PE10.3)) Category Priority and Initial Value of G(T) Demands Cat Ex Priority COTDGT Cat Ex Priority COTDGT YYYY MM DD (m3/s) YYYY MM DD (m3/s)<------------------------------------------------><------------------------------------------------> K RCHRES Data for section ADCALC x - x CRRAT VOL (ac-ft) ADCALC-DATA@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP?y1.5u!CRRAT is the ratio of maximum velocity to mean velocity inthe RCHRES cross section under typical flow conditions. CRRAT AFIELD4 aPy0. !VOL is the volume of water in the RCHRES at the start ofthe=;x Pri Frac Cat Ex Pri Frac Cat Ex Pri Frac<--------------------------------------><--------------------------------------><-------------------------------------->  Category Priorities and Initial Values for G(T) Demands RCHRES c x Priority COTDGT c x Priority COTDGT x - x (yyyy/mm/dd) (cfs) (yyyy/mm/dd) (cfs) HYDR-CDEMAND @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 ! Category for this fraction. CTAG1 a AFIELD4 a@0.0'! Exit from which this demand is drawn. CEXIT1 BFIELD5 " Priority of this category. This can be either a real number or a date in the format ' YYYY/MM/DD '. Earlier dates are higher priority. Blank or zero priority is considered lowest priority. CPRI1 b`BFIELD6 b0y0.0)" Initial value of the COTDGT timeseries. CDEM1 CFIELD7 # Category for this fraction. CTAG2 c# CFIELD8 c@0.0'# Exit from which this demand is drawn. CEXIT2 DFIELD9 $ Priority of this category. This can be either a real number or a date in the format ' YYYY/MM/DD '. Earlier dates are higher priority. Blank or zero priority is considered lowest priority. CPRI2 d)`DFIELD10d0y0.0*$ Initial value of this COTDGT timeseries. CDEM2  (1X,2(A10,F10.0,A20,1PE10.3)) Category Priority and Initial Value of G(T) Demands Cat Ex Priority COTDGT Cat Ex Priority COTDGT YYYY MM DD (cfs) YYYY MM DD (cfs)<------------------------------------------------><------------------------------------------------>  Category Priorities and Initial Values for G(T) Demands RCHRES c x Priority COTDGT c x Pri><--------------------><----------------------------><----------------------------><----------------------------> RCHRES Category Fractions and Priorities for F(VOL) Outflow x - x c x pr frac c x pr frac c x pr frac c x pr frac HYDR-CFVOL @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 ! Category for this fraction. CTAG1 a AFIELD4 a@0.0&! Exit to which this priority applies. CEXIT1 BFIELD5 by0.0" Priority of this category.CPRI1 BFIELD6 b0?0.0W" Fraction of FVOL flow which is taken from specified category at this priority level. CFVOL1 CFIELD7 # Category for this fraction. CTAG2 c CFIELD8 c@0.0&# Exit to which this priority applies. CEXIT2 DFIELD9 dy0.0$ Priority of this category.CPRI2 DFIELD10d0?0.0W$ Fraction of FVOL flow which is taken from specified category at this priority level. CFVOL2 EFIELD11% Category for this fraction. CTAG3 e) EFIELD12e@0.0&% Exit to which this priority applies. CEXIT3 FFIELD13fy0.0& Priority of this category.CPRI3 FFIELD14f0?0.0W& Fraction of FVOL flow which is taken from specified category at this priority level. CFVOL3 GFIELD15' Category for this fraction. CTAG4 g8 GFIELD16g@0.0&' Exit to which this priority applies. CEXIT4 HFIELD17hy0.0( Priority of this category.CPRI4 HFIELD18h0?0.0W( Fraction of FVOL flow which is taken from specified category at this priority level. CFVOL G (1X,3(A10,F10.0,F10.0,1PE10.3)) Category Fraction and Priority of FVOL Outflow Cat E?=---------><------------------><------------------><------------------>  RCHRES Category Fractions and Priorities for Evaporation x - x c pr frac c pr frac c pr frac c pr frac c pr frac HYDR-CEVAP @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 ! Category for this fraction. CTAG1 a AFIELD4 ay0.0! Priority of this category.CPRI1 BFIELD5 b0?0.0Y" Fraction of evaporation which is taken from specified category at this priority level. CEVAP1 BFIELD6 " Category for this fraction. CTAG2 b CFIELD7 cy0.0# Priority of this category.CPRI2 CFIELD8 c0?0.0Y# Fraction of evaporation which is taken from specified category at this priority level. CEVAP2 DFIELD9 $ Category for this fraction. CTAG3 d% DFIELD10dy0.0$ Priority of this category.CPRI3 EFIELD11e0?0.0Y% Fraction of evaporation which is taken from specified category at this priority level. CEVAP3 EFIELD12% Category for this fraction. CTAG4 e2 FFIELD13fy0.0& Priority of this category.CPRI4 FFIELD14f0?0.0Y& Fraction of evaporation which is taken from specified category at this priority level. CEVAP4 GFIELD15' Category for this fraction. CTAG5 g? GFIELD16gy0.0' Priority of this category.CPRI5 HFIELD17h0?0.0Y( Fraction of evaporation which is taken from specified category at this priority level. CEVAP5 @ (1X,4(A10,F10.0,1PE10.3)) Category Fraction and Priority of Evaporation Cat Pri Frac Cat Pri Frac Cat Pri Frac Cat Pri Frac<--------@> Cat Frac Cat Frac Cat Frac Cat Frac Cat Frac Cat Frac<------------------><------------------><------------------><------------------><------------------><------------------> ~ RCHRES Category Fractions for Precipitation x - x c frac c frac c frac c frac c frac c frac c frac HYDR-CPREC @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 ! Category for this fraction. CTAG1 a AFIELD4 a0?0.0@!Fraction of precipitation which is added to specified category.CPREC1 BFIELD5 " Category for this fraction. CTAG2 b BFIELD6 b0?0.0@"Fraction of precipitation which is added to specified category.CPREC2 CFIELD7 # Category for this fraction. CTAG3 c CFIELD8 c0?0.0@#Fraction of precipitation which is added to specified category.CPREC3 DFIELD9 $ Category for this fraction. CTAG4 d' DFIELD10d0?0.0@$Fraction of precipitation which is added to specified category.CPREC4 EFIELD11% Category for this fraction. CTAG5 e1 EFIELD12e0?0.0@%Fraction of precipitation which is added to specified category.CPREC5 FFIELD13& Category for this fraction. CTAG6 f; FFIELD14f0?0.0@&Fraction of precipitation which is added to specified category.CPREC6 GFIELD15' Category for this fraction. CTAG7 gE GFIELD16g0?0.0@'Fraction of precipitation which is added to specified category.CPREC7 / (1X,6(A10,1PE10.3)) Category Fraction of Precipitation Cat Frac Cat Frac Cat Frac Cat Frac Cat Frac Cat Frac<------------------><------------------><---------A? # of G(T) FVOL flows from each possible exit: demands Precip Evap 1 2 3 4 5 NCOGT | RCHRES Initial Category Storage Fractions x - x c cfrac c cfrac c cfrac c cfrac c cfrac c cfrac c cfrac HYDR-CINIT @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 ! Category for this fraction. CTAG1 a AFIELD4 a0?0.0]!Fraction of initial storage VOL in Table-type HYDR-INIT which belongsto specified category. CFRAC1 BFIELD5 " Category for this fraction. CTAG2 b BFIELD6 b0?0.0]"Fraction of initial storage VOL in Table-type HYDR-INIT which belongsto specified category. CFRAC2 CFIELD7 # Category for this fraction. CTAG3 c CFIELD8 c0?0.0]#Fraction of initial storage VOL in Table-type HYDR-INIT which belongsto specified category. CFRAC3 DFIELD9 $ Category for this fraction. CTAG4 d' DFIELD10d0?0.0]$Fraction of initial storage VOL in Table-type HYDR-INIT which belongsto specified category. CFRAC4 EFIELD11% Category for this fraction. CTAG5 e1 EFIELD12e0?0.0]%Fraction of initial storage VOL in Table-type HYDR-INIT which belongsto specified category. CFRAC5 FFIELD13& Category for this fraction. CTAG6 f; FFIELD14f0?0.0]&Fraction of initial storage VOL in Table-type HYDR-INIT which belongsto specified category. CFRAC6 GFIELD15' Category for this fraction. CTAG7 gE GFIELD16g0?0.0]'Fraction of initial storage VOL in Table-type HYDR-INIT which belongsto specified category. CFRAC7 1 (1X,6(A10,1PE10.3)) Category Fraction of Initial Storage B@lows from this exit willbe taken from the specified category first. If an integer is given,then that number of categories will be specified in Table-type HYDR-CFVOLfor that exit. If blank or 0, outflows will be taken from all activecategories according to their current storage fraction. CFVOL1 b BFIELD6 R"If a category tag is given, then F(VOL) outflows from this exit willbe taken from the specified category first. If an integer is given,then that number of categories will be specified in Table-type HYDR-CFVOLfor that exit. If blank or 0, outflows will be taken from all activecategories according to their current storage fraction. CFVOL2 b CFIELD7 R#If a category tag is given, then F(VOL) outflows from this exit willbe taken from the specified category first. If an integer is given,then that number of categories will be specified in Table-type HYDR-CFVOLfor that exit. If blank or 0, outflows will be taken from all activecategories according to their current storage fraction. CFVOL3 c CFIELD8 R#If a category tag is given, then F(VOL) outflows from this exit willbe taken from the specified category first. If an integer is given,then that number of categories will be specified in Table-type HYDR-CFVOLfor that exit. If blank or 0, outflows will be taken from all activecategories according to their current storage fraction. CFVOL4 c% DFIELD9 R$If a category tag is given, then F(VOL) outflows from this exit willbe taken from the specified category first. If an integer is given,then that number of categories will be specified in Table-type HYDR-CFVOLfor that exit. If blank or 0, outflows will be taken from all activecategories according to their current storage fraction. CFVOL5 d* DFIELD10d(0 L$Number of category G(T) demands to be specified in Table-Type HYDR-CDEMAND.NOCGT  (1X,7(6X,A4),I10) Category associated with: CAIN1. COLIN3 CFIELD7 c(@A4. #See help for COLIN1. COLIN4 DFIELD8 d(@A4. $See help for COLIN1. COLIN5 DFIELD9 d(y0. s$The array OUTDG1 specifies the G(T) component of theinitial outflow demand for each exit from the RCHRES. OUTDG1 EFIELD10e(y0. %See help for OUTDG1. OUTDG2 EFIELD11e(y0. %See help for OUTDG1. OUTDG3 FFIELD12f(y0. &See help for OUTDG1. OUTDG4 FFIELD13f(y0. &See help for OUTDG1. OUTDG5 .Initial conditions for HYDR section (RCHRES). $ (1X,1PE10.3,F5.0,5(1PE10.3),5X,5(1PE10.3)) (Mm3) CAT Init value of COLIND for each poss exit Init value of OUTDGT for each poss exit (m/s) VOL 1 2 3 4 5 1 2 3 4 5 Categories specified for Outflows, Precipitation and Evaporation RCHRES Categories associated with: x - x prec evap fv1 fv2 fv3 fv4 fv5 gt HYDR-CATEGORY @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 &!If a category tag is given, precipitation is added to the specified category.If an integer is given, then that number of categories will be specified inTable-Type HYDR-CPREC. If blank or zero, precipitation will be added to allactive categories according to their current storage fraction. CPREC a AFIELD4 -!If a category tag is given, evaporation is taken first from the specifiedcategory. If an integer is given, then that number of categories will bespecified in Table-Type HYDR-CEVAP. If blank or zero, evaporation will betaken from all active categories according to their current storage fraction. CEVAP a BFIELD5 R"If a category tag is given, then F(VOL) outfDBN1 BFIELD5 b(@A4. "See help for COLIN1. COLIN2 CFIELD6 c(@A4. #See help for COLIN1. COLIN3 CFIELD7 c(@A4. #See help for COLIN1. COLIN4 DFIELD8 d(@A4. $See help for COLIN1. COLIN5 DFIELD9 d(y0. s$The array OUTDG1 specifies the G(T) component of theinitial outflow demand for each exit from the RCHRES. OUTDG1 EFIELD10e(y0. %See help for OUTDG1. OUTDG2 EFIELD11e(y0. %See help for OUTDG1. OUTDG3 FFIELD12f(y0. &See help for OUTDG1. OUTDG4 FFIELD13f(y0. &See help for OUTDG1. OUTDG5 .Initial conditions for HYDR section (RCHRES). & (1X,1PE10.3,F5.0,5(1PE10.3),5X,5(1PE10.3)) (acre-ft) CAT Init value of COLIND for each poss exit Init value of OUTDGT for each poss exit (ft3/s) VOL 1 2 3 4 5 1 2 3 4 5  Initial conditions for HYDR section RCHRES VOL CAT Initial value of COLIND initial value of OUTDGT x - x Mm3 for each possible exit for each possible exit,m3 HYDR-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD2 aPy0. 3!VOL is the initial volume of water in the RCHRES. VOLAFIELD3 5!ICAT is the initial category of water in the RCHRES. ICAT a BFIELD4 b(@A4. "The value of COLIN1 for an exit indicates the pair ofcolumns used to evaluate the initial value of the F(VOL)component of outflow demand for the exit.COLIN1 BFIELD5 b(@A4. "See help for COLIN1. COLIN2 CFIELD6 c(@A4. #See help for COLECe data apply. OPNID `QAFIELD2 aP@0. !IREXIT is the exit number that will be used for irrigation withdrawals.This exit should have no other demands, such as f(VOL) or g(t).IREXIT AFIELD3 aPy0. S!IRMINV is a floor value for VOL below which no irrigation withdrawalsmay be made. IRMINV dThese parameters are used when irrigation withdrawals for a PERLND areto be made from this RCHRES.X (1X,2(1PE10.3))Values of irrigation withdrawal parameters IREXIT IRMINV (ac.ft)i Irrigation withdrawal parameters RCHRES IREXIT IRMINV x - x (Mm3) HYDR-IRRIG @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD2 aP@0. !IREXIT is the exit number that will be used for irrigation withdrawals.This exit should have no other demands, such as f(VOL) or g(t).IREXIT AFIELD3 aPy0. S!IRMINV is a floor value for VOL below which no irrigation withdrawalsmay be made. IRMINV dThese parameters are used when irrigation withdrawals for a PERLND areto be made from this RCHRES.V (1X,2(1PE10.3))Values of irrigation withdrawal parameters IREXIT IRMINV (Mm3)  Initial conditions for HYDR section RCHRES VOL CAT Initial value of COLIND initial value of OUTDGT x - x ac-ft for each possible exit for each possible exit,ft3 HYDR-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD2 aPy0. 3!VOL is the initial volume of water in the RCHRES. VOLAFIELD3 5!ICAT is the initial category of water in the RCHRES. ICAT a BFIELD4 b(@A4. "The value of COLIN1 for an exit indicates the pair ofcolumns used to evaluate the initial value of the F(VOL)component of outflow demand for the exit.COLIFDouting. Choiceof a realistic KS value is discussed in the functionaldescription of the HYDR section in Part E. KS DFIELD9 dP #;@E0.25 $DB50 is the median diameter of the bed sediment (assumedconstant throughout the run). This value is used tocalculate the bed shear stress if the RCHRES is a lake, orcalculate the rate of sand transport if the Colby orToffaleti methods are used.DB50 &Parameters for HYDR section (RCHRES). (1X,7(1PE10.3)) KM M M MM DSN FTBN LEN DELTH STCOR KS DB50 u RCHRES Monthly f(VOL) adjustment factors x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-CONVF @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(y0. 7!Value of F(VOL) adjustment factor at start of January. VOLJAN AFIELD4 a(y0. VOLFEB BFIELD5 b(y0. VOLMAR BFIELD6 b(y0. VOLAPR CFIELD7 c(y0. VOLMAY CFIELD8 c(y0. VOLJUN DFIELD9 d(y0. VOLJUL DFIELD10d(y0. VOLAUG EFIELD11e(y0. VOLSEP EFIELD12e(y0. VOLOCT FFIELD13f(y0. VOLNOV FFIELD14f(y0. VOLDEC AMonthly values of F(VOL) adjustment factors at start of each mon (1X,12(1PE10.3))Values of CONVF at the start of each calendar month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC i Irrigation withdrawal parameters RCHRES IREXIT IRMINV x - x (ac-ft) HYDR-IRRIG @@FIELD1 " RCHRES to which thesGEKS DFIELD9 dP8B0.01 $DB50 is the median diameter of the bed sediment (assumedconstant throughout the run). This value is used tocalculate the bed shear stress if the RCHRES is a lake, orcalculate the rate of sand transport if the Colby orToffaleti methods are used.DB50 &Parameters for HYDR section (RCHRES). (1X,7(1PE10.3)) MILES FT FT IN DSN FTBN LEN DELTH STCOR KS DB50  RCHRES FTBW FTBU LEN DELTH STCOR KS DB50 x - x (km) (m) (m) (mm) HYDR-PARM2 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(yD0. v!FTBW is WDM table dataset number for the F-Table which containsthe geometric and hydraulic properties of the RCHRES. FTBW AFIELD4 a(?yD-999. !FTBU is the user's number for the F-Table which containsthe geometric and hydraulic properties of the RCHRES. IfFTBW is zero, the F-Table is found in the FTABLES Block.If FTBW is positive, then FTBU is the number of the tablewithin that dataset. FTBW BFIELD5 bPn<y-999. ""LEN is the length of the RCHRES. LENBFIELD6 bPy0. ^"DELTH is the drop in water elevation from the upstream tothe downstream extremities of the RCHRES. (It is used ifsection OXRX is active and reaeration is being computedusing the Tsivoglou-Wallace equation; or if section SEDTRNis active and sandload transport capacity is being computedusing either the Toffaleti or Colby method.) DELTH CFIELD7 cPyy0. ]#STCOR is the correction to the RCHRES depth to calculatestage. (Depth + STCOR = Stage) STCOR CFIELD8 cPp}?0.00 #KS is the weighting factor for hydraulic rHFFIELD20i1 )See help for FUNCT1. FUNCT4 JFIELD21j1 *See help for FUNCT1. FUNCT5 !Flags for HYDR section (RCHRES). (1X,4I10,3(5X,5I3)) VCONFG AUX1FG AUX2FG AUX3FG ODFV-flags for ODGT-flags for FUNCT-flags for each poss. exit poss. exit each poss. exit  RCHRES FTBW FTBU LEN DELTH STCOR KS DB50 x - x (miles) (ft) (ft) (in) HYDR-PARM2 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(yD0. v!FTBW is WDM table dataset number for the F-Table which containsthe geometric and hydraulic properties of the RCHRES. FTBW AFIELD4 a(?yD-999. !FTBU is the user's number for the F-Table which containsthe geometric and hydraulic properties of the RCHRES. IfFTBW is zero, the F-Table is found in the FTABLES Block.If FTBW is positive, then FTBU is the number of the tablewithin that dataset. FTBUCI BFIELD5 bP #<y-999. ""LEN is the length of the RCHRES. LENBFIELD6 bPy0. ^"DELTH is the drop in water elevation from the upstream tothe downstream extremities of the RCHRES. (It is used ifsection OXRX is active and reaeration is being computedusing the Tsivoglou-Wallace equation; or if section SEDTRNis active and sandload transport capacity is being computedusing either the Toffaleti or Colby method.) DELTH CFIELD7 cPyy0. ]#STCOR is the correction to the RCHRES depth to calculatestage. (Depth + STCOR = Stage) STCOR CFIELD8 cPp}?0.00 #KS is the weighting factor for hydraulic routing. Choiceof a realistic KS value is discussed in the functionaldescription of the HYDR section in Part E. IGntcomponent. A value greater than 0 indicates the columnnumber in RCHTAB which contains the F(VOL) component. Ifthe value specified for ODFVF1 is less than 0, the absolutevalue indicates the element of array COLIND( ) which definesa pair of columns in RCHTAB which are used to evaluate theF(VOL) component. Further explanation of this latter optionis provided in the functional description of the HYDRsection in Part E. A value of ODFVF1 can be specified foreach exit from a RCHRES.ODFVF1 CFIELD8 c0 #See help for ODFVF1. ODFVF2 DFIELD9 d0 $See help for ODFVF1. ODFVF3 DFIELD10d0 $See help for ODFVF1. ODFVF4 EFIELD11e0 %See help for ODFVF1. ODFVF5 EFIELD12e0 f%The value specified for ODGTF1 determines the G(T)component of the outflow demand. A value of 0 means thatthe outflow demand does not have such a component. A valuegreater than 0 indicates the element number of the arrayOUTDGT( ) which contains the G(T) component. A value ofODGTF1 can be specified for each exit from a RCHRES. ODGTF1 FFIELD13f0 &See help for ODGTF1. ODGTF2 FFIELD14f0 &See help for ODGTF1. ODGTF3 GFIELD15g0 'See help for ODGTF1. ODGTF4 GFIELD16g0 'See help for ODGTF1. ODGTF5 HFIELD17h1 (FUNCT1 determines the function used to combine thecomponents of an outflow demand; 1 means use the smaller ofF(VOL) and G(T), 2 means use the larger of F(VOL) and G(T),and 3 means use the sum of F(VOL) and G(T). FUNCT1 HFIELD18h1 (See help for FUNCT1. FUNCT2 IFIELD19i1 )See help for FUNCT1. FUNCT3 IJH (1X,5A4,I10,2I10,3I10,2I10)Reach/reservoir-id NEXITS Unit systems Print-file nos Lake- BinaryOutfileNos IUNITS OUNITS English Metric flag English Metric  Flags for HYDR section RCHRES VC A1 A2 A3 ODFVFG for each *** ODGTFG for each FUNCT for each x - x FG FG FG FG possible exit *** possible exit possible exit HYDR-PARM1 @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 a0 !A value of 1 for VCONFG means that F(VOL) outflow demandcomponents are multiplied by a factor which is allowed tovary.VCONFG AFIELD4 a0 f!A value of 1 for AUX1FG means subroutine AUXIL will becalled to compute depth, stage, surface area, average depth,and topwidth, and values for these parameters will bereported in the printout. A value of 0 supresses thecalculation and printout of this information. A value of 2forces AUXIL to compute the variables even if VOL=0. AUX1FG BFIELD5 b0 ("A value of 1 for AUX2FG means average velocity and averagecross sectional area will be calculated, and values forthese parameters will be reported in the printout. A valueof 0 supresses the calculation and printout of thisinformation. If AUX2FG is 1, AUX1FG must also be 1.AUX2FG BFIELD6 b0 "A value of 1 for AUX3FG means the shear velocity and bedshear stress will be calculated. These are used in thecalculation of deposition and scour of sediment (inorganicand organic). AUX3FG may only be turned ON (=1) if AUX1FGand AUX2FG are also =1. AUX3FG CFIELD7 c0 #The value specified for ODFVF1 determines the F(VOL)component of the outflow demand. A value of 0 means thatthe outflow demand does not have a volume dependeKIwritten. Note thatprintout for each Reach can be obtained in either theEnglish or Metric systems, or both (irrespective of thesystem used to supply the inputs). PUNITE CFIELD8 c(c0 ΁#PUNIT(2) indicates the destinations of printout in Metricunits. A value 0 means no printout is required in Metricunits. A non-zero value means printout is required inMetric units and and the value is the Fortran unit no. ofthe file to which the printout is to be written. Note thatprintout for each Reach can be obtained in either theEnglish or Metric systems, or both (irrespective of thesystem used to supply the inputs). PUNITM DFIELD9 d(0 $LKFG indicates whether the RCHRES is a lake (1) or astream/river (0). This affects the method of calculatingbed shear stress (in Section HYDR) and the reaerationcoefficient (Section OXRX). LKFG DFIELD10d(c0 $BUNIT(1) indicates the destinations of output in Englishunits. A value 0 means no output is required in Englishunits. A non-zero value means output is required inEnglish units and the value is the Fortran unit no. of thefile to which the output is to be written. Note that outputfor each Reach can be obtained in either the English orMetric systems, or both (irrespective of the system used tosupply the inputs). BUNITE EFIELD11e(c0 %BUNIT(2) indicates the destinations of output in Metricunits. A value 0 means no output is required in Metricunits. A non-zero value means output is required inMetric units and the value is the Fortran unit no. of thefile to which the output is to be written. Note that outputfor each Reach can be obtained in either the English orMetric systems, or both (irrespective of the system used tosupply the inputs). BUNITM General information for RCHRES.LJDELT=PIVL*DELT mins). PIVL must be chosen such that thereare an integer no. of PDELT periods in a day. PIVLPR FFIELD14f( 9 €&PYREND is the calendar month which will terminate the yearfor output purposes. Thus, the annual summary can reflectthe situation over the past water year or the past calendaryear, etc. PYREND Table of binary output level flags for RCHRES.HSPF permits the user to vary the output level (maximumfrequency) for the various active sections of an operation.2 means every PIVL intervals, 3 means every day, 4 meansevery month, 5 means every year, 6 means never. (1X,10I5,5X,2I10) Binary Output level flags Print-ivl Print-yrend HYDR ADCA CONS HEAT SED GQL OXRX NUTR PLNK PHCB PIVL PYREND Name Nexits Unit Systems Printer RCHRES t-series Engl Metr LKFG x - x in out GEN-INFO @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 V!Any string of up to 20 characters may be supplied as theidentifier for a RCHRES. RCHID aAFIELD4 a(1 -!NEXITS is the no. of exits from the RCHRES. NEXITS BFIELD5 b(1 x"IUNITS indicates the system of units for data in the inputtime series; 1 means English units, 2 means Metric units.IUNITS BFIELD6 b(1 y"OUNITS indicates the system of units for data in the outputtime series; 1 means English units, 2 means Metric units. OUNITS CFIELD7 c(c0 #PUNIT(1) indicates the destinations of printout in Englishunits. A value 0 means no printout is required in Englishunits. A non-zero value means printout is required inEnglish units and the value is the Fortran unit no. of thefile to which the printout is to be MK 9 €&PYREND is the calendar month which will terminate the yearfor printout purposes. Thus, the annual summary can reflectthe situation over the past water year or the past calendaryear, etc. PYREND Table of printout level flags for RCHRES.HSPF permits the user to vary the printout level (maximumfrequency) for the various active sections of an operation.2 means every PIVL intervals, 3 means every day, 4 meansevery month, 5 means every year, 6 means never. (1X,10I5,5X,2I10) Printout level flags Print-ivl Print-yrend HYDR ADCA CONS HEAT SED GQL OXRX NUTR PLNK PHCB PIVL PYRENDm RCHRES Binary Output level flags x - x HYDR ADCA CONS HEAT SED GQL OXRX NUTR PLNK PHCB PIVL PYR BINARY-INFO@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(4 !Output level for section HYDR. HYDRPR AFIELD4 a(4 !!Output level for section ADCALC. ADCAPR BFIELD5 b(4 "Output level for section CONS. CONSPR BFIELD6 b(4 "Output level for section HTRCH.HEATPR CFIELD7 c(4 !#Output level for section SEDTRN. SEDPR CFIELD8 c(4 #Output level for section GQUAL.GQLPR DFIELD9 d(4 $Output level for section OXRX. OXRXPR DFIELD10d(4 $Output level for section NUTRX.NUTRPR EFIELD11e(4 %Output level for section PLANK.PLNKPR EFIELD12e(4 -%Output level for sections PHCARB and ACIDPH. PHCBPR FFIELD13f(1 "&A value need only be supplied for PIVL if one or moresections have a output level of 2. For those sections,output will occur every PIVL intervals (that is, everyPNLValue of 1 indicates section NUTRX is active. NUTFG EFIELD11e(0 /%Value of 1 indicates section PLANK is active. PLKFG EFIELD12e(0 %Value of 1 indicates section PHCARB is active.Value of 2 indicates section ACIDPH is active.Value of 3 indicates both sections are active.PHFG Active sections of RCHRES. p (1X,10I10) HYDRFG ADFG CONSFG HTFG SEDFG GQUALFG OXFG NUTFG PLKFG PHFGh RCHRES Printout level flags x - x HYDR ADCA CONS HEAT SED GQL OXRX NUTR PLNK PHCB PIVL PYR PRINT-INFO @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(4 !!Printout level for section HYDR. HYDRPR AFIELD4 a(4 #!Printout level for section ADCALC. ADCAPR BFIELD5 b(4 !"Printout level for section CONS. CONSPR BFIELD6 b(4 ""Printout level for section HTRCH. HEATPR CFIELD7 c(4 ##Printout level for section SEDTRN. SEDPR CFIELD8 c(4 "#Printout level for section GQUAL. GQLPR DFIELD9 d(4 !$Printout level for section OXRX. OXRXPR DFIELD10d(4 "$Printout level for section NUTRX. NUTRPR EFIELD11e(4 "%Printout level for section PLANK. PLNKPR EFIELD12e(4 /%Printout level for sections PHCARB and ACIDPH. PHCBPR FFIELD13f(1 "&A value need only be supplied for PIVL if one or moresections have a printout level of 2. For those sections,printout will occur every PIVL intervals (that is, everyPDELT=PIVL*DELT mins). PIVL must be chosen such that thereare an integer no. of PDELT periods in a day. PIVLPR FFIELD14f(OM0. .0254 SAND-PM W243 2 0. .001 SAND-PM W130 1 0. .0833 SILT-CLAY-PM D244 1 0. .001 SILT-CLAY-PM D130 2 0. .0254 SILT-CLAY-PM W244 2 0. .001 SILT-CLAY-PM W130 6 0. 4.880 SILT-CLAY-PM M150 1 -32. .555 GQ-VALUES TWAT151 0 -32. .555 MON-WATEMP TEMPM248 1 0. 3.281 SCOUR-PARMS SCRVEL249 3 0. 3.281 OX-GENPARM KODSET250 1 0. 3.281 ELEV ELEV169 1 0. 5280. OX-LEN-DELTH LEN251 1 0. 1000. OX-LEN-DELTH LEN252 5 0. 0.3048 PLNK-PARM1 EXTB188 5 -32. .555 PLNK-PARM2 TALGRH188 6 -32. .555 PLNK-PARM2 TALGRL188 7 -32. .555 PLNK-PARM2 TALGRM254 5 0. 3.281 PHYTO-PARM PHYSET254 6 0. 3.281 PHYTO-PARM REFSET203 4 0. 0.3048 BENAL-RESSCR CSLOF2255 4 0. 0.3048 BENAL-RESSCR CSLOF2256 3 0. 0.3048 BENAL-LIGHT CKTRB1257 2 0. 3.281 BENAL-RIFF1 CMMVY RCHRES Active sections x - x HYFG ADFG CNFG HTFG SDFG GQFG OXFG NUFG PKFG PHFG ACTIVITY @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(0 .!Value of 1 indicates section HYDR is active. HYDRFG AFIELD4 a(0 0!Value of 1 indicates section ADCALC is active.ADFG BFIELD5 b(0 ."Value of 1 indicates section CONS is active. CONSFG BFIELD6 b(0 /"Value of 1 indicates section HTRCH is active. HTFG CFIELD7 c(0 0#Value of 1 indicates section SEDTRN is active.SEDFG CFIELD8 c(0 /#Value of 1 indicates section GQUAL is active. GQALFG DFIELD9 d(0 .$Value of 1 indicates section OXRX is active. OXFG DFIELD10d(0 /$PN @ PH-INIT @ ACID-INIT @@ PH-PARM1 n Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PH-PARM1 table. ` ) A@ PH-PARM2 n! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PH-PARM2 table. a ) A@ PH-INIT m! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PH-INIT table. a %  B@ ACID-FLAGS p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES ACID-FLAGS table.b 1 B@ ACID-PARMS p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES ACID-PARMS table.b 1 C@ ACID-INITo# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES ACID-INIT table. c -l 105 3 0. 5280. HYDR-PARM2 LEN230 3 0. 1000. HYDR-PARM2 LEN105 7 0. .0833 HYDR-PARM2 DB50230 7 0. .001 HYDR-PARM2 DB50107 2 0. 43560. HYDR-IRRIG IRMINV231 2 0. 1.0E06 HYDR-IRRIG IRMINV108 1 0. 43560. HYDR-INIT VOL232 1 0. 1.0E06 HYDR-INIT VOL115 2 0. 43560. ADCALC-DATA VOL234 2 0. 1.0E06 ADCALC-DATA VOL235 1 0. 3.281 HEAT-PARM ELEV235 2 0. 3.281 HEAT-PARM ELDAT121 1 0. .3048 HT-BED-PARM MUDDEP121 2 -32. .555 HT-BED-PARM TGRND122 0 -32. .555 MON-HT-TGRND TGRNDM123 0 0. 4.882 HT-BED-DELH DELH124 0 0. .555 HT-BED-DELTT DELTT125 0 -32. .555 HEAT-INIT (ALL)128 1 0. 5280. SED-HYDPARM LEN242 1 0. 1000. SED-HYDPARM LEN128 3 0. .0833 SED-HYDPARM DB50242 3 0. .001 SED-HYDPARM DB50129 1 0. .0833 SAND-PM D243 1 0. .001 SAND-PM D129 2 QOggle this field on to edit the RCHRES NUT-ADSINIT table. e 5( E@ MON-PHVALo% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-PHVAL table. e -, F@ PLNK-FLAGS p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PLNK-FLAGS table.f 10F@ PLNK-AD-FLAGSs& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PLNK-AD-FLAGS table. f =4G@ SURF-EXPOSED r' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES SURF-EXPOSED table. g 98 G@ PLNK-PARM1 p' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PLNK-PARM1 table.g 1< H@ PLNK-PARM2 p( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PLNK-PARM2 table.h 1@ H@ PLNK-PARM3 p( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PLNK-PARM3 table.h 1D I@ PHYTO-PARM p) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PHYTO-PARM table.i 1H I@ ZOO-PARM1o) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES ZOO-PARM1 table. i -L J@ ZOO-PARM2o* Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES ZOO-PARM2 table. j -P J@ BENAL-PARM p* Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES BENAL-PARM table.j 1T K@ PLNK-INITo+ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PLNK-INIT table. k -X  Select RCHRES table(s) to modify. PHCARB ACIDPH @ PH-PARM1 @ ACID-FLAGS @ PH-PARM2 @ ACID-PARMSRPO  Select RCHRES table(s) to modify. NUTRX PLANK @ NUT-FLAGS @BNUT-BEDCONC @ PLNK-FLAGS @ PHYTO-PARM @ BENAL-FLAGS @ BENAL-RIFF1 @ NUT-AD-FLAGS @ NUT-ADSPARM @ PLNK-AD-FLAGS @ ZOO-PARM1 @ BENAL-GROW @ BENAL-RIFF2 @ CONV-VAL1 @ NUT-DINIT @ SURF-EXPOSED @ ZOO-PARM2 @ BENAL-GRAZE @ BENAL-INIT @ANUT-BENPARM @ NUT-ADSINIT @ PLNK-PARM1 @ BENAL-PARM @ BENAL-RESSCR @ NUT-NITDENIT @ MON-PHVAL @ PLNK-PARM2 @ PLNK-INIT @ BENAL-LIGHT @ NUT-NH3VOLAT @ PLNK-PARM3 @ PLNK-PARM4 @ MON-BINV @@ NUT-FLAGSo Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NUT-FLAGS table. ` -A@ NUT-AD-FLAGS r! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NUT-AD-FLAGS table. a 9 A@ CONV-VAL1o! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES CONV-VAL1 table. a - B@A q" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NUT-BENPARM table. b 7B@ NUT-NITDENIT r" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NUT-NITDENIT table. b 9C@ NUT-NH3VOLAT r# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NUT-NH3VOLAT table. c 9C@B q# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NUT-BENCONC table. c 7D@ NUT-ADSPARM q$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NUT-ADSPARM table. d 5  D@ NUT-DINITo$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NUT-DINIT table. d -$E@ NUT-ADSINIT q% Toggle field On (X) or Off ( ) using the space bar. ToSQOGLOU @ SCOUR-PARMS @ OX-GENPARM @ OX-LEN-DELTH @ ELEV @ OX-TCGINV1 @ OX-BENPARM @ OX-REAPARM @ OX-CFOREA @ OX-INIT @@ BENTH-FLAG p Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES BENTH-FLAG table.` 1A@ SCOUR-PARMS q! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES SCOUR-PARMS table. a 5 A@ OX-FLAGS n! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-FLAGS table. a )  B@ OX-GENPARM p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-GENPARM table.b 1B@ ELEV j" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES ELEV table. b  C@ OX-BENPARM p# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-BENPARM table.c 1 C@ OX-CFOREAo# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-CFOREA table. c -D@ OX-TSIVOGLOU r$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-TSIVOGLOU table. d 9 D@ OX-LEN-DELTH r$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-LEN-DELTH table. d 9$ E@ OX-TCGINV1 p% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-TCGINV1 table.e 1( E@ OX-REAPARM p% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-REAPARM table.e 1, F@ OX-INIT m& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES OX-INIT table. f %0TR(X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-ADTHETA table.h 1@H@B p( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-SEDCONC table.h 3D I@ GQ-VALUESo) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-VALUES table. i -H I@ MON-WATEMP p) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-WATEMP table.i 1LJ@ MON-ROXYGEN q* Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-ROXYGEN table. j 5P J@ GQ-ALPHA n* Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-ALPHA table. j )T K@ GQ-GAMMA n+ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-GAMMA table. k )X K@ GQ-DELTA n+ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-DELTA table. k )\ L@ GQ-CLDFACT p, Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-CLDFACT table.l 1` L@ MON-CLOUDo, Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-CLOUD table. l -dM@ MON-SEDCONC q- Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-SEDCONC table. m 5h M@ MON-PHYTOo- Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-PHYTO table. m -lN@ GQ-DAUGHTER q. Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-DAUGHTER table. n 5pA  Select RCHRES table(s) to modify. RQUAL OXRX @ BENTH-FLAG @ OX-FLAGS @ OX-TSIVuSs field on to edit the RCHRES GQ-AD-FLAGS table. a 1 A@ GQ-QALDATA p! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-QALDATA table.a 1  B@ GQ-QALFG n" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-QALFG table. b ) B@ GQ-FLG2 m" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-FLG2 table. b % C@ GQ-HYDPM n# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-HYDPM table. c ) C@ GQ-ROXPM n# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-ROXPM table. c ) D@ GQ-PHOTPMo$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-PHOTPM table. d -  D@ GQ-CFGAS n$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-CFGAS table. d )$ E@ GQ-BIOPM n% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-BIOPM table. e )( E@ MON-BIO m% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-BIO table. e %,F@ GQ-GENDECAY q& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-GENDECAY table. f 50F@A q& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-SEDDECAY table. f 74G@ GQ-KDk' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-KD table. g 8 G@ GQ-ADRATEo' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-ADRATE table. g -< H@ GQ-ADTHETA p( Toggle field On V $!20050516143722 20050516143722 BMPRACTS9֪CnīItʬ Kv̭&Q|Ү(S~ԯ.Yڰ0[ܱ 6a 8c, INFLOW 10RECEIV 30ROFLOW 50REMOVE 70F IVOLCIVOLICONIHEATISEDIDQALISQALIOXIDNUTISNUTIPLKIPHIACID F IVOLCIVOLICONIHEATISEDIDQALISQALIOXIDNUTISNUTIPLKIPHIACID S ROVOLCROVOLROCONROHEATROSEDRODQALROSQALROOXRODNUTROSNUTROPLKROPHROACID S RMVOLCRMVOLRMCONRMHEATRMSEDRMDQALRMSQALRMOXRMDNUTRMSNUTRMPLKRMPHRMACID IVOL 1 1 1 1 2 0 2 0 74 ENG acft/iv 0 1 0 1.23E-3 Inflow of water MET Mm3/iv 0 810.71 0 1 CIVOL 100 1 -9 1 2 0 2 0 576 ENG acft/iv 0 1 0 1.23E-3 Inflow of water by category MET Mm3/iv 0 810.71 0 1 ICON 10 1 -7 1 2 0 2 0 2052 ENG qty/iv 0 1 0 1 Inflow of conservative constits. MET qty/iv 0 1 0 1 IHEAT 1 1 1 1 2 0 2 0 2407 ENG BTU/iv 0 1 0 0.2520 Inflow of heat MET kcl/iv 0 3.969 0 1 ISED 3 1 3 1 2 0 2 0 2450 ENG tn/iv 0 1 0 0.9070 Inflows of sediment MET tne/iv 0 1.1025 0 1 IDQAL 3 1 -8 1 2 0 2 0 2549 ENG qty/iv 0 1 0 1 Inflow of dissolved qual MET qty/iv 0 1 0 1 ISQAL 3 3 3 -8 2 0 2 0 2600 ENG qty/iv 0 1UW 0 1 Inflows of sed-assoc qual MET qty/iv 0 1 0 1 IOX 2 1 2 1 2 0 2 0 2961 ENG lb/iv 0 1 0 0.4536 Inflows of DO and BOD MET kg/iv 0 2.205 0 1 IDNUT 4 1 4 1 2 0 2 0 3037 ENG lb/iv 0 1 0 0.4536 Inflows of dissolved nutrients MET kg/iv 0 2.205 0 1 ISNUT 3 2 3 2 2 0 2 0 3075 ENG lb/iv 0 1 0 0.4536 Inflows of adsorbed NH4 and PO4 MET kg/iv 0 2.205 0 1 IPLK 5 1 5 1 2 0 2 0 3372 ENG lb/iv 0 1 0 0.4536 Inflows of plankton related constituents MET kg/iv 0 2.205 0 1 IPH 2 1 2 1 2 0 2 0 3522 ENG lb/iv 0 1 0 0.4536 Inflows of TIC and CO2 MET kg/iv 0 2.205 0 1 IACID 7 1 -10 1 2 0 2 0 3613 ENG lb/iv 0 1 0 0.4536 Inflows of acid chemicals MET kg/iv 0 2.205 0 1 IVOL 1 1 1 1 2 0 0 75 ENG acft/iv 0 1 0 1.23E-3 Inflow of water MET Mm3/iv 0 810.71 0 1 CIVOL 100 1 -9 1 2 0 0 676 ENG acft/iv 0 1 0 1.23E-3 Inflow of water by category MET Mm3/iv 0 810.71 0 1 ICON 10 1 -7 1 2 0 0 2062 ENG qty/iv 0 1 0 1 Inflow of conservative constits. MET qty/iv 0 1 0 1 IHEAT 1 1 1 1 2 0 0 2408 ENG BTU/iv 0 1 0 0.2520 Inflow of heat MET kcl/iv 0 3.969 0 1 ISED 3 1 3 1 2 0 0 2453 ENG tn/iv 0 1 0 0.9070 Inflows of sediment MET tne/iv 0 1.1025 0 1 IDQAL 3 1 -8 1 2 0 VX0 2552 ENG qty/iv 0 1 0 1 Inflow of dissolved qual MET qty/iv 0 1 0 1 ISQAL 3 3 3 -8 2 0 0 2609 ENG qty/iv 0 1 0 1 Inflows of sed-assoc qual MET qty/iv 0 1 0 1 IOX 2 1 2 1 2 0 0 2963 ENG lb/iv 0 1 0 0.4536 Inflows of DO and BOD MET kg/iv 0 2.205 0 1 IDNUT 4 1 4 1 2 0 0 3041 ENG lb/iv 0 1 0 0.4536 Inflows of dissolved nutrients MET kg/iv 0 2.205 0 1 ISNUT 3 2 3 2 2 0 0 3081 ENG lb/iv 0 1 0 0.4536 Inflows of adsorbed NH4 and PO4 MET kg/iv 0 2.205 0 1 IPLK 5 1 5 1 2 0 0 3377 ENG lb/iv 0 1 0 0.4536 Inflows of plankton related constituents MET kg/iv 0 2.205 0 1 IPH 2 1 2 1 2 0 0 3524 ENG lb/iv 0 1 0 0.4536 Inflows of TIC and CO2 MET kg/iv 0 2.205 0 1 IACID 7 1 -10 1 2 0 0 3620 ENG lb/iv 0 1 0 0.4536 Inflows of acid chemicals MET kg/iv 0 2.205 0 1 ROVOL 1 1 1 1 2 0 0 795 ENG acft/iv 0 1 0 1.23E-3 Outflow of water MET Mm3/iv 0 810.71 0 1 CROVOL100 1 -9 1 2 0 0 1296 ENG acft/iv 0 1 0 1.23E-3 Outflow of water by category MET Mm3/iv 0 810.71 0 1 ROCON 10 1 -7 1 2 0 0 2332 ENG qty/iv 0 1 0 1 Outflow of conservative constits. MET qty/iv 0 1 0 1 ROHEAT 1 1 1 1 2 0 0 2428 ENG BTU/iv 0 1 0 0.2520 Outflow of heat MET kcl/iv 0 3.969 0 1 ROSEWYD 3 1 3 1 2 0 0 2513 ENG tn/iv 0 1 0 0.9070 Outflows of sediments MET tne/iv 0 1.1025 0 1 RODQAL 3 1 -8 1 2 0 0 2822 ENG qty/iv 0 1 0 1 Outflow of dissolved qual MET qty/iv 0 1 0 1 ROSQAL 3 3 3 -8 2 0 0 2870 ENG qty/iv 0 1 0 1 Outflows of sed-assoc qual MET qty/iv 0 1 0 1 ROOX 2 1 2 1 2 0 0 3003 ENG lb/iv 0 1 0 0.4536 Outflows of DO and BOD MET kg/iv 0 4.537E2 0 1000. RODNUT 4 1 4 1 2 0 0 3247 ENG lb/iv 0 1 0 0.4536 Outflows of dissolved nutrients MET kg/iv 0 4.537E2 0 1000. ROSNUT 3 2 3 2 2 0 0 3281 ENG lb/iv 0 1 0 0.4536 Outflows of adsorbed NH4 and PO4 MET kg/iv 0 4.537E2 0 1000. ROPLK 5 1 5 1 2 0 0 3477 ENG lb/iv 0 1 0 0.4536 Outflows of plankton related constituents MET kg/iv 0 4.537E2 0 1000. ROPH 2 1 2 1 2 0 0 3564 ENG lb/iv 0 1 0 0.4536 Outflows of TIC and CO2 MET kg/iv 0 4.537E2 0 1000. ROACID 7 1 -10 1 2 0 0 3760 ENG lb/iv 0 1 0 0.4536 Outflows of acid chemicals MET kg/iv 0 0.4537 0 1. RMVOL 1 1 1 1 2 0 0 1401 ENG acft/iv 0 1 0 1.23E-3 Removal of water MET Mm3/iv 0 810.71 0 1 CRMVOL100 1 -9 1 2 0 0 1902 ENG acft/iv 0 1 0 1.23E-3 Removal of water by category MET Mm3/iv 0 810.71 0 1 RMCON 10 1 -7 1 2 0 0 2392 ENG qty/iv 0 1 0 1 Removal of conservative constits. MET qty/iv 0 X 1 0 1 RMHEAT 1 1 1 1 2 0 0 2434 ENG BTU/iv 0 1 0 0.2520 Removal of heat MET kcl/iv 0 3.969 0 1 RMSED 3 1 3 1 2 0 0 2531 ENG tn/iv 0 1 0 0.9070 Removals of sediments MET tne/iv 0 1.1025 0 1 RMDQAL 3 1 -8 1 2 0 0 2894 ENG qty/iv 0 1 0 1 Removal of dissolved qual MET qty/iv 0 1 0 1 RMSQAL 3 3 3 -8 2 0 0 2942 ENG qty/iv 0 1 0 1 Removals of sed-assoc qual MET qty/iv 0 1 0 1 RMOX 2 1 2 1 2 0 0 3015 ENG lb/iv 0 1 0 0.4536 Removals of DO and BOD MET kg/iv 0 2.205 0 1 RMDNUT 4 1 4 1 2 0 0 3307 ENG lb/iv 0 1 0 0.4536 Removals of dissolved nutrients MET kg/iv 0 2.205 0 1 RMSNUT 3 2 3 2 2 0 0 3341 ENG lb/iv 0 1 0 0.4536 Removals of adsorbed NH4 and PO4 MET kg/iv 0 2.205 0 1 RMPLK 5 1 5 1 2 0 0 3507 ENG lb/iv 0 1 0 0.4536 Removals of plankton related constituents MET kg/iv 0 2.205 0 1 RMPH 2 1 2 1 2 0 0 3576 ENG lb/iv 0 1 0 0.4536 Removals of TIC and CO2 MET kg/iv 0 2.205 0 1 RMACID 7 1 -10 1 2 0 0 3802 ENG lb/iv 0 1 0 0.4536 Removals of acid chemicals MET kg/iv 0 2.205 0 1 [ $!20000309112933 20000309112933 HRINDSS  Uδ,\ ._  20 1 1 5 VOLNO: &I Specified data record number not defined in PATHNAMES block  20 1 1 5 VOLNO: &I Specified gap value is invalid. UNDF (undefined) was substituted. Valid values are ZERO, UNDF. Supplied value was &CCC.  20 1 1 5 VOLNO: &I Specified amend string is invalid. ADD was substituted. Valid values are ADD and REPL. Supplied value was &CCC. p  20 1 1 5 VOLNO: &I Specified pathname does not conform to conventions for a regular timeseries.V  20 1 1 5 VOLNO: &I Specified data record is not a regular timeseries.  20 1 1 5 VOLNO: &I Program bug. A fatal error occurred reading the first and last data points. Return code for first point was &I , and for last point was &I .  20 1 1 5 VOLNO: &I Time span of simulation is not within time span of specified DSS source data record(s). At least one endpoint is missing. Return code for first point was &I , and for last point was &I .  20 1 1 5 VOLNO: &I Amend code is ADD, but data already present in record. Data must be absent, or amend code must be REPL.  20 1 1 5 VOLNO: &I Specified system string is invalid. Valid values are ENGL and METR. Supplied value was &CCC.  20 1 1 5 VOLNO: &I Data type not consistent at beginning and end of run. Starting type is&CCCCCCC, and endZing type is &CCCCCCC. ~  20 1 1 5 VOLNO: &I Data type &CCCCCCC specified in PATHNAMES block does not match actual data type &CCCCCCC.  20 1 1 5 VOLNO: &I Specified data record number requires that DSS File number &I must be successfully opened in the FILES block. F39 $!20030814161440 20030814161440 HIRRIG G  510 511 3373 3361 3385 9575 9576 {^ $!20050725133033 20050725133033 SPECACT TxFػ-Iyټ 8fӽ *QoоAYwƿ<^x-N~ 1Qq=^$yVz Qv&W  20 1 1 5 In this configuration of HSPF, Special Actions input requires specifications of the variable name and any necessary subscripts. A memory location was input.  20 1 1 5 In this configuration of HSPF, Special Actions input requires specifications of a memory location. A variable name was input.  20 1 1 5 The variable name '&CCCCC' is invalid for Special Actions. It may be mispelled, placed in the wrong field, or it may not be currently available in the "Special Actions by Variable Name" library.  20 1 1 5 The number of nonzero subscripts specified for the Special Action variable '&CCCCC' is not correct. The correct number of dimensions is &I .  20 1 1 5 At least one of the specified subscripts for the Special Action variable '&CCCCC' exceeds the corresponding dimension of the variable array.  10 1 1 5 User specified a bad time code (TCODE) in the SPEC-ACTIONS block. The supplied value of '&C' was interpreted as: &I Valid values are]_ 'MI','HR','DY','MO','YR' or ' ' (defaults to minutes). U  10 1 1 5 Problem reading special action value from string: '&CCCCCCCCC' g  10 1 1 5 Problem reading special action numerical address from string: &CCCCCCCCCCCCCC  10 1 1 5 Special action instruction has a bad action code (ACTCOD). The value supplied was: &CCC Valid values are: = += -= *= /= ^= MIN MAX ABS INT LOG LN MOD  10 1 1 5 Problem reading the following special action instruction: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC It has been ignored.  10 1 1 5 Operation type '&CCCCC' does not allow special actions. Valid operation types are 'PERLND','IMPLND','RCHRES','COPY ','PLTGEN', 'GENER ' and 'BMPRAC'.  10 1 1 5 The time code for deferral of a special action on failure of logical conditions must be MI (minute), HR (hour), or DY (day). The value supplied for &CCCCC was &C.  10 1 1 5 Special action instruction has a bad type code (TYPCOD). The value supplied was: &IMinimum allowed is : &I Maximum allowed is : &I  10 1 1 5 Special action instruction has a bad action code (ACTCOD). The value supplied was: &I Minimum allowed is : &I Maximum allowed is : &I  10 1 1 5 Special action instruction has a bad number of times to repeat (NUMINC). The value supplied was: &I It must be > than 0.  10 1 1 5 Special action instruction has a bad timestep (TSTEP). The value supplied was: &I It must be > than 0. }  10 1 1 5 Distribution &I does not exist or is out of range. It must be defined before it is referenced. e  10 1 1 5 User defined variable '&CCCCC' is not compatable with operation type '&CCCCC'. ]  10 1 1 5 An undated special action cannot be repeated. ^` Repeat value was &I . l  10 1 1 5 An undated special action cannot be distributed. User specified distribution &I .  10 1 1 5 An undated special action is incompatible with movement between two memory locations. &CCCCC has an action code of &I . n  10 1 1 5 An undated conditional special action cannot be deferred on failure of the conditions. c  10 1 1 5 A distribution is not compatible with movement between two memory locations. ~  10 1 1 5 Deferral of a conditional special action is not compatible with movement between two memory locations.  10 1 1 5 Overflow in logic operation stack while evaluating special action condition &I . Logic chain is too complex.  10 1 1 5 Underflow in logic operation stack while evaluating special action condition &I . Too many "right parentheses" specified in logic chain. f  10 1 1 5 PROGRAM BUG - Logic operation stack for special action conditions not cleared.  10 1 1 5 The IF - END IF logical blocks for the special actions are improperly formed. The number of IFS does not match the number of END IFS. U  10 1 1 5 The workspace variable &CCCCC at address &I was not found. n  10 1 1 5 Distribution index number &I is out of range. It must be between &I and &I . I  10 1 1 5 Distribution index number &I is already in use. v  10 1 1 5 Distribution deferral code '&CCCC' is unknown. Valid codes are ' SKIP', 'SHIFT' and 'ACCUM'. _  10 1 1 5 Distribution timestep &I is not valid. It must be a positive number. p  10 1 1 5 Distribution count value of &I is out of range. It must be between &I and &I .  10 1 1 5 Problem reading the following special action distribution instruction: &CCCCCCCCCCCCCCCC_aCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC It has been ignored.v  10 1 1 5 Too many user-defined variable names have been defined. The maximum number allowed is &I .  10 1 1 5 Too many variables are referenced by user-defined variable names. The maximum number allowed is &I .  10 1 1 5 Operation-type mismatch at &CCCCC found in operation-type &I in user-defined variable &CCCCC in operation-type &I .  10 1 1 5 For user-defined variable &CCCCC, an error occurred reading the count of variables referenced. The input was "&CC".  10 1 1 5 For user-defined variable &CCCCC, an error occurred reading the fraction for base variable &CCCCC. The input was: &CCCCCCCCCCCCCCCCCCCC {  PERLND 1 94 95 98 99 1 909 IMPLND 1 94 95 98 99 844 162 RCHRES 1 93 94 97 98 1006 679 COPY 1 24 25 28 150 1687 8 PLTGEN 1 11 12 15 16 0 0 DISPLY 0 0 0 0 0 0 0 DURANL 0 0 0 0 0 0 0 GENER 1 23 24 27 28 1696 10 MUTSIN 0 0 0 0 0 0 0 BMPRAC 1 63 64 67 68 1708 69 REPORT 0 0 0 0 0 0 0   1779 1 %b YR 84 MON 85 DAY 86HR 87 MIN 88 SPOUT 98SURLI 320 UZLI 321 IFWLI 322LZLI 323 AGWLI `b 324 PETINP 345IRRINP 352 CSNOFG 358 PWPM1 13 358RTOPFG 359 UZFG 360 VCSFG 361VUZFG 362 VNNFG 363 VIFWFG 364VIRCFG 365 VLEFG 366 IFFCFG 367HWTFG 368 IRRGFG 369 IFRDFG 370NSROWS 371 NSCOLS 372 NCRP 373CRPDAT 4 3 374 NSKED 386 IRPM1 5 386SZONFG 387 VCRDFG 388 VAWDFG 389IROPFG 390 IRDATE 5 20 391 IRDURA 20 491IRCHNO 511 IROSVK 512 FOREST 513PWPM2 7 513 LZSN 514 INFILT 515LSUR 516 SLSUR 517 KVARY 518KGW 519 PETMAX 520 PWPM3 7 520PETMIN 521 INFEXP 522 INFILD 523DEEPFR 524 BASETP 525 AGWETP 526FZG 527 PWPM5 2 527 FZGL 528BELV 529 PWPM6 5 529 GWDATM 530PCW 531 PGW 532 UPGW 533SRRC 534 PWPM7 6 534 SREXP 535IFWSC 536 DELTA 537 UELFAC 538LELFAC 539 SELV 540 UELV 541LELV 542 ULGWS 543 LLGWS 544BGWS 545 CEPSCM 12 546 UZSNM 12 558NSURM 12 570 INTFWM 12 582 UZRA 10 594INTGRL 10 604 IRCM 12 614 LZETPM 12 626SURTAB 100 638 SOILD 4 738 SLME 742SLSM 743 ULSM ac 744 LLSM 745ALSM 746 WILTPT 4 747 FDCAP 4 751AWC 4 755 CRPSTG 4 3 759 CRPAWD 4 3 771CRPRDP 2 3 783 IRAFAC 789 IREFF 790ARZI 791 WILTP 792 FLDCAP 793CRDEP 794 IRAWD 795 CAPRIS 796CRDEPM 12 797 IRAWDM 12 809 IRRATE 20 821IRRSRC 3 3 841 IRRTGT 5 850 SMSFG 855FSMSFG 856 CEPS 860 PWST1 9 860SURS 861 UZS 862 IFWS 863LZS 864 AGWS 865 GWVS 866TGWS 867 GWEL 868 INFFAC 869PWST3 2 869 PETADJ 870 PERS 871CEPSC 876 PWST5 6 876 UZSN 877NSUR 878 INTFW 879 IRC 880LZETP 881 SURSS 882 SRC 883DEC 884 IFWK1 885 IFWK2 886LZFRAC 887 RLZRAT 888 RPARM 889RZWSC 890 IRST1 2 890 RZWS 891SUPY 906 SURO 907 IFWO 908AGWO 909 PERO 910 IGWI 911PET 936 CEPE 937 SURET 938UZET 939 LZET 940 AGWET 941BASET 942 TAET 943 IFWI 976UZI 977 INFIL 978 PERC 979LZI 980 AGWI 981 CEPO 1016SURI 1017 IRRDEM 1018 IRSHRT 1019IRDRAW 3 1028 IRRAPP 6 1043bd SLSED 1105CRVFG 1111 SEDPM1 3 1111 VSIVFG 1112SDOPFG 1113 SMPF 1114 KRER 1115JRER 1116 AFFIX 1117 KSER 1118JSER 1119 KGER 1120 JGER 1121COVERM 12 1122 NVSIM 12 1134 DRYDFG 1146DETS 1147 STCAP 1148 COVER 1149WSSD 1153 SCRSD 1154 SOSED 1163DET 1164 NVSI 1165 SLTVFG 1179PTPM1 4 1179 ULTVFG 1180 LGTVFG 1181TSOPFG 1182 ASLTM 12 1183 BSLTM 12 1195ULTP1M 12 1207 ULTP2M 12 1219 LGTP1M 12 1231LGTP2M 12 1243 AIRTC 1255 PTST1 4 1255SLTMP 1256 ULTMP 1257 LGTMP 1258AIRTCS 1259 ASLT 1260 PTST2 6 1260BSLT 1261 ULTP1 1262 ULTP2 1263LGTP1 1264 LGTP2 1265 SLITMP 1270ILITMP 1271 ALITMP 1272 SLIDOX 1273ILIDOX 1274 ALIDOX 1275 SLICO2 1276ILICO2 1277 ALICO2 1278 IDVFG 1288PGPM1 4 1288 ICVFG 1289 GDVFG 1290GCVFG 1291 ELEVGC 1292 IDOXPM 12 1293ICO2PM 12 1305 ADOXPM 12 1317 ACO2PM 12 1329LIFAC 4 1341 SOTMP 1345 PGST1 3 1345IOTMP 1346 AOTMP 1347 SODOX 1348PGST2 6 1348 SOCO2 1349 IODOX 1350IOCO2 1351 AODOX 1352 AOCO2 1353IDOXP 1354 ICO2P 1355 ADOXP ce 1356ACO2P 1357 SOHT 1367 IOHT 1368AOHT 1369 POHT 1382 SODOXM 1383SOCO2M 1384 IODOXM 1385 IOCO2M 1386AODOXM 1387 AOCO2M 1388 PODOXM 1413POCO2M 1414 SLIQO 10 1427 SLIQSP 10 1477ILIQC 10 1487 ALIQC 10 1497 PQADFG 20 1572VPFWFG 10 1612 VPFSFG 10 1622 VQOFG 10 1652VIQCFG 10 1682 VAQCFG 10 1712 PQAFXM 12 10 1762PQACNM 12 10 1882 POTFWM 12 10 2002 POTFSM 12 10 2122ACQOPM 12 10 2242 REMQOM 12 10 2362 WSFAC 10 2482IOQCM 12 10 2492 AOQCM 12 10 2612 SQO 10 2732POTFW 10 2742 POTFS 10 2752 ACQOP 10 2762REMQOP 10 2772 IOQC 10 2782 AOQC 10 2792SOQSP 10 2802 IOQCE 10 2812 AOQCE 10 2822WASHQS 10 2872 SCRQS 10 2922 SOQS 10 2972SOQO 10 2982 SOQOC 10 3032 SOQUAL 10 3042SOQC 10 3052 IOQUAL 10 3062 AOQUAL 10 3112POQUAL 10 3162 POQC 10 3172 PQADDR 10 3182PQADWT 10 3232 PQADEP 10 3282 ISQO 10 3292CFINMA 3452 SLMPF 3453 MSTPM 3 3453ULPF 3454 LLPF 3455 MST 5 3456FRAC 8 3461 LIPSS 5 3 3482 LISDPS 2 3 3557ITMXPS 3 3627 ADOPFG 3 3630 PEADFG 18 3633PEAFXM 12 3 3 3651 PEACNM 12 3 3 3759 GPSPM 8 3 3867SPSPM 8 3 3891 UPSPM 8 3 3915 LPSPM 8 3 3939APSPM 8 3 3963 SCVFG 3 3995 UCVFG 3 3998LCVFG 3 4001 ACVFG 3 4004 SPS 3 df3 4007UPS 3 3 4016 IPS 3 4025 LPS 3 3 4028APS 3 3 4037 TPS 3 3 4046 TPST 5 3 4055TOTPST 3 4070 SXJCT 3 4085 UXJCT 3 4088LXJCT 3 4091 AXJCT 3 4094 SXST 3 4097UXST 3 4100 LXST 3 4103 AXST 3 4106SDPS 2 3 4175 TSPSS 5 3 4205 SSPSS 3 3 4280DEGPS 5 3 4325 SOSDPS 3 4400 SOPEST 3 4403POPST 3 4406 TOPST 3 4409 PEADDR 3 3 4412PEADWT 3 3 4457 PEADEP 3 3 4502 NITIF 4 5 4595INO3 4595 INH3 4596 IORN 4597INITR 4598 LIAMS 5 4619 LINO3 5 4624LISLN 5 4629 LISRN 5 4634 VNUTFG 4769NITFG 10 4769 FORAFG 4770 ITMAXA 4771BNUMN 4772 CNUMN 4773 NUPTFG 4774FIXNFG 4775 AMVOFG 4776 ALPNFG 4777VNPRFG 4778 NIADFG 12 4779 CRPDAY 13 3 4791CRPFRC 13 3 4830 NUPTGT 4869 NYLDPM 2 4869NMXRAT 4870 NIAFXM 12 3 2 4871 NIACNM 12 3 2 4943SKPLNM 12 5015 UKPLNM 12 5027 LKPLNM 12 5039AKPLNM 12 5051 SKRBNM 12 5063 UKRBNM 12 5075LKRBNM 12 5087 AKRBNM 12 5099 KRANM 12 5111SKRLNM 12 5123 UKRLNM 12 5135 BNPRFM 12 5147LNPRFM 12 5159 SKUNIM 12 5171 UKUNIM 12 5183LKUNIM 12 5195 AKUNIM 12 5207 SKUAMM 12 5219UKUAMM 12 5231 LKUAMM 12 5243 AKUAMM 12 5255SKINIM 12 5267 UKINIM 12 5279 LKINIM 12 5291AKINIM 12 5303 SKIAMM 12 5315 UKIAMM 12 eg5327LKIAMM 12 5339 AKIAMM 12 5351 NUPTFM 12 5363SNUPTM 12 5375 UNUPTM 12 5387 LNUPTM 12 5399ANUPTM 12 5411 GNPM 11 5423 NO3UTF 5423NH4UTF 5424 THPLN 5425 THKDSA 5426THKADA 5427 THKIMN 5428 THKAM 5429THKDNI 5430 THKNI 5431 THKIMA 5432CMAXAM 5433 SNPM 11 5434 SKDSAM 5434SKADAM 5435 SKIMNI 5436 SKAM 5437SKDNI 5438 SKNI 5439 SKIMAM 5440SXFIXA 5441 SXMAXA 5442 SKF1AM 5443SN1IAM 5444 UNPM 11 5445 UKDSAM 5445UKADAM 5446 UKIMNI 5447 UKAM 5448UKDNI 5449 UKNI 5450 UKIMAM 5451UXFIXA 5452 UXMAXA 5453 UKF1AM 5454UN1IAM 5455 LNPM 11 5456 LKDSAM 5456LKADAM 5457 LKIMNI 5458 LKAM 5459LKDNI 5460 LKNI 5461 LKIMAM 5462LXFIXA 5463 LXMAXA 5464 LKF1AM 5465LN1IAM 5466 ANPM 11 5467 AKDSAM 5467AKADAM 5468 AKIMNI 5469 AKAM 5470AKDNI 5471 AKNI 5472 AKIMAM 5473AXFIXA 5474 AXMAXA 5475 AKF1AM 5476AN1IAM 5477 SORNPM 4 5478 SKLON 5478SKRON 5479 SKONLR 5480 STHNLR 5481UORNPM 4 5482 UKLON 5482 UKRON 5483UKONLR 5484 UTHNLR 5485 LORNPM 4 5486LKLON 5486 LKRON 5487 LKONLR 5488LTfhHNLR 5489 AORNPM 4 5490 AKLON 5490AKRON 5491 AKONLR 5492 ATHNLR 5493SCSATN 4 5494 SCSUNI 5494 SCSUAM 5495SCSINI 5496 SCSIAM 5497 UCSATN 4 5498UCSUNI 5498 UCSUAM 5499 UCSINI 5500UCSIAM 5501 LCSATN 4 5502 LCSUNI 5502LCSUAM 5503 LCSINI 5504 LCSIAM 5505ACSATN 4 5506 ACSUNI 5506 ACSUAM 5507ACSINI 5508 ACSIAM 5509 SANUFM 12 5510UANUFM 12 5522 LANUFM 12 5534 AANUFM 12 5546SKVOL 5558 AMVOPM 6 5558 UKVOL 5559LKVOL 5560 AKVOL 5561 THVOL 5562TRFVOL 5563 BIVLN 5564 CIVLN 5565AGPLTN 5575 LITTRN 5576 SN 8 5577SORGN 5577 SPLON 5577 SAMAD 5578SAMSU 5579 SNO3 5580 SPLTN 5581SSLON 5582 SPRON 5583 SSRON 5584UN 8 5585 UORGN 5585 UPLON 5585UAMAD 5586 UAMSU 5587 UNO3 5588UPLTN 5589 USLON 5590 UPRON 5591USRON 5592 IN 4 5593 IAMSU 5593INO3 5594 ISLON 5595 ISRON 5596LN 8 5597 LORGN 5597 LPLON 5597LAMAD 5598 LAMSU 5599 LNO3 5600LPLTN 5601 LSLON 5602 LPRON 5603LSRON 5604 AN 8 5605 AORGN 5605APLON 5605 AAMAD 5606 AAMSU 5607ANO3 gi 5608 APLTN 5609 ASLON 5610APRON 5611 ASRON 5612 TN 8 5613TORGN 5613 TPLON 5613 TAMAD 5614TAMSU 5615 TNO3 5616 TPLTN 5617TSLON 5618 TPRON 5619 TSRON 5620TNIT 5 5621 TOTNIT 5626 SNDFC 5631NDFCT 5 5631 UNDFC 5632 LNDFC 5633ANDFC 5634 TNDFC 5635 SKPLN 5693KPLN 4 5693 UKPLN 5694 LKPLN 5695AKPLN 5696 KRETBN 5 5697 SKPRBN 5697UKPRBN 5698 LKPRBN 5699 AKPRBN 5700BGNPRF 5701 KRETAN 4 5702 AGKPRN 5702SKPRLN 5703 UKPRLN 5704 LINPRF 5705SKSATN 4 5706 SKSUNI 5706 SKSUAM 5707SKSINI 5708 SKSIAM 5709 UKSATN 4 5710UKSUNI 5710 UKSUAM 5711 UKSINI 5712UKSIAM 5713 LKSATN 4 5714 LKSUNI 5714LKSUAM 5715 LKSINI 5716 LKSIAM 5717AKSATN 4 5718 AKSUNI 5718 AKSUAM 5719AKSINI 5720 AKSIAM 5721 SNUPTG 5722NUPTG 4 5722 UNUPTG 5723 LNUPTG 5724ANUPTG 5725 SPNUTG 5730 UPNUTG 5731LPNUTG 5732 APNUTG 5733 ANUTF 4 5734SANUTF 5734 UANUTF 5735 LANUTF 5736AANUTF 5737 SNRXF 16 5738 UNRXF 16 5754LNRXF 16 5770 ANRXF 16 5786 SEDN 3 5802TSAMS 5 5817 SSAMS 3 5842 TSNO3 5 5857SSNO3 3 hj 5882 DENIF 5 5897 AMNIT 5 5922AMIMB 5 5947 ORNMN 5 5972 NIADDR 3 2 5997NIADWT 3 2 6027 NIADEP 3 2 6082 NFIXFX 5 6082TSSLN 5 6088 SSSLN 3 6113 TSSRN 5 6128SSSRN 3 6153 NIIMB 5 6168 AMVOL 5 6193REFRON 5 6218 NIUPA 5 6243 AMUPA 5 6268NIUPB 5 6293 AMUPB 5 6318 RETAGN 6343RTLLN 3 6348 RTRLN 3 6363 RTLBN 5 6378RTRBN 5 6403 SOSEDN 6428 PONO3 6429PONH4 6430 POORN 6431 PONITR 6432IPO4 6569 IORP 6570 IPHOS 6571LIP4S 5 6587 LISEDP 2 6612 VPUTFG 6637PHOFG 6 6637 FORPFG 6638 ITMAXP 6639BNUMP 6640 CNUMP 6641 PUPTFG 6642PHADFG 8 6643 PUPTGT 6651 PYLDPM 2 6651PMXRAT 6652 PHAFXM 12 2 2 6653 PHACNM 12 2 2 6701SKPLPM 12 6749 UKPLPM 12 6761 LKPLPM 12 6773AKPLPM 12 6785 PUPTFM 12 6797 SPUPTM 12 6809UPUPTM 12 6821 LPUPTM 12 6833 APUPTM 12 6845GPPM 6 6857 THPLP 6857 THKDSP 6858THKADP 6859 THKIMP 6860 THKMP 6861CMAXP 6862 SPPM 8 6863 SKDSP 6863SKADP 6864 SKIMP 6865 SKMP 6866SXFIXP 6867 SXMAXP 6868 SKF1P 6869SN1IP 6870 UPPM 8 6871 UKDSP 6871UKADP 6872 UKIMP 6873 UKMP 6874UXFIXP 6875 UXMAXP 6876 UKF1P 6877UN1IP 687ik8 LPPM 8 6879 LKDSP 6879LKADP 6880 LKIMP 6881 LKMP 6882LXFIXP 6883 LXMAXP 6884 LKF1P 6885LN1IP 6886 APPM 8 6887 AKDSP 6887AKADP 6888 AKIMP 6889 AKMP 6890AXFIXP 6891 AXMAXP 6892 AKF1P 6893AN1IP 6894 BIVLP 6895 CIVLP 6896SP 4 6905 SORGP 6905 SP4AD 6906SP4SU 6907 SPLTP 6908 UP 4 6909UORGP 6909 UP4AD 6910 UP4SU 6911UPLTP 6912 IP 6913 IP4SU 6913LP 4 6914 LORGP 6914 LP4AD 6915LP4SU 6916 LPLTP 6917 AP 4 6918AORGP 6918 AP4AD 6919 AP4SU 6920APLTP 6921 TP 4 6922 TORGP 6922TP4AD 6923 TP4SU 6924 TPLTP 6925TPHO 5 6926 TOTPHO 6931 SPDFC 6936PDFCT 5 6936 UPDFC 6937 LPDFC 6938APDFC 6939 TPDFC 6940 SKPLP 6973KPLP 4 6973 UKPLP 6974 LKPLP 6975AKPLP 6976 SPUPTG 6977 PUPTG 4 6977UPUPTG 6978 LPUPTG 6979 APUPTG 6980SPPUTG 6985 UPPUTG 6986 LPPUTG 6987APPUTG 6988 SPRXF 5 6989 UPRXF 5 6994LPRXF 5 6999 APRXF 5 7004 SEDP 2 7009TSP4S 5 7019 SSP4S 3 7044 P4IMB 5 7059ORPMN 5 7084 SOSEDP 7109 POPHOS 7110PHADDR 2 2 7111 PHADWjlT 2 2 7131 PHADEP 2 2 7151LITRS 5 7189 TRADFG 4 7223 TRAFXM 12 2 7232TRACNM 12 2 7256 STRSU 7281 TRST1 5 7281UTRSU 7282 ITRSU 7283 LTRSU 7284ATRSU 7285 TRSU 7286 TSTRS 5 7297SSTRS 5 7322 POTRS 7337 TRADDR 2 7338TRADWT 2 7348 TRADEP 2 7358 @@@@@@ 1GATMP 113 LAPSE 24 117 ELDAT 141AIRTMP 142 AIRTS 143 PREC 145DTMPG 150 WINMOV 151 SOLRAD 152ICEFG 157 SNOPFG 158 VKMFG 159SVP 40 160 LAT 200 SNPM1 7 200MELEV 201 SHADE 202 SNOWCF 203COVIND 204 KMELT 205 TBASE 206RDCSN 207 SNPM2 6 207 TSNOW 208SNOEVP 209 CCFACT 210 MWATER 211MGMELT 212 KMELTM 12 213 DRYFG 225SNOFFG 227 RAINFG 228 PACKF 233SNST1 7 233 PACKW 234 PACKI 235PDEPTH 236 COVINX 237 NEGHTS 238XLNMLT 239 RDENPF 240 SNST2 5 240SKYCLR 241 SNOCOV 242 DULL 243ALBEDO 244 PAKTMP 245 SNST3 3 245DEWTMP 246 SNOTMP 247 PACK 248RDNSN 253 MNEGHS 254 PACKWC 255NEGHT 256 GMELTR 257 COMPCT 258SNOWEP 259 MOSTHT 260 VAP 261SNOWF 278 PRAIN km 279 SNOWE 280WYIELD 281 MELT 282 RAINF 313YR 84 MON 85 DAY 86HR 87 MIN 88 SPOUT 98SURLI 320 PETINP 325 CSNOFG 328IWPM1 5 328 RTOPFG 329 VRSFG 330VNNFG 331 RTLIFG 332 LSUR 333IWPM2 2 333 SLSUR 334 PETMAX 335IWPM3 2 335 PETMIN 336 RETSCM 12 337NSURM 12 349 SMSFG 361 FSMSFG 362RETS 364 IWST1 2 364 SURS 365IWST2 366 PETADJ 366 IMPS 367RETSC 372 NSUR 373 SRC 374DEC 375 SUPY 380 SURO 381PET 382 IMPEV 383 RETO 410SURI 411 SLSLD 417 VASDFG 423SLDPM1 3 423 VRSDFG 424 SDOPFG 425ACCSDM 12 426 REMSDM 12 438 KEIM 450JEIM 451 DRYDFG 452 SLDS 453ACCSDP 455 REMSDP 456 SOSLD 457SLITMP 463 SLIDOX 464 SLICO2 465WTFVFG 469 ELEVGC 470 AWTFM 12 471BWTFM 12 483 LIFAC 2 495 AIRTC 497SOTMP 498 IGST1 3 498 SODOX 499SOCO2 500 AWTF 504 BWTF 505SOHT 506 SODOXM 507 SOCO2M 508SLIQO 10 524 SLIQSP 10 574 IQADFG 20 627VPFWFG 10 667 VQOFG 10 ln 697 IQAFXM 12 10 747IQACNM 12 10 867 POTFWM 12 10 987 ACQOPM 12 10 1107REMQOM 12 10 1227 WSFAC 10 1347 SQO 10 1357POTFW 10 1367 ACQOP 10 1377 REMQOP 10 1387SOQSP 10 1397 SOQS 10 1427 SOQO 10 1477SOQOC 10 1527 SOQUAL 10 1537 SOQC 10 1547IQADDR 10 1557 IQADWT 10 1607 IQADEP 10 1657 KK YR 83 MON 84 DAY 85HR 86 MIN 87 SPOUT 97IVOL 112 CIVOL 100 117 PREC 617POTEV 5 618 COLIND 5 827 OUTDGT 5 832COTDGT 5 100 837 COREL 5 100 1337 VCONFG 2348HYPM1 19 2348 AUX1FG 2349 AUX2FG 2350AUX3FG 2351 ODFVFG 5 2352 ODGTFG 5 2357FUNCT 5 2362 VZERPT 2367 NROWS 2368NCOLS 2369 NODFV 2370 NODGT 2371IREXIT 2372 CPREC 2373 CATEG 8 2373CEVAP 2374 CFVOL 5 2375 NCOGT 2380CPRECC 20 2381 CEVAPC 20 2401 CEVAPP 20 2421CFVOLC 20 5 2441 CFVOLP 20 5 2541 COGTC 20 2641COGTE 20 2661 CPRECF 20 2681 CFVOLF 20 5 2701CEVAPF 20 2801 COGTP 20 2821 KS 2841COKS 2842 FACTA1 2843 CONVFM 12 2844DELTH 2856 DB50 2857 AKAPPA 2858GAM 2859 GRAV 2860 RCHTAB 500 2861LEN 3361 STCOR 3362 SLOPE 3363IRMINV -1 3365 ROWPT 3367 VOL -1 3377VOLS -1 3379 PREVOL -4 mo 3381 RIRWDL -1 3389CVOL -100 3391 CDFVOL 5 100 3591 DEP 4091HYST 5 4091 STAGE 4092 AVDEP 4093TWID 4094 HRAD 4095 SAREA 4096AVVEL 4097 AVSECT 4098 USTAR 4099TAU 4100 RO 4101 ROS 4102CRO 100 4103 CONVF 4203 O 5 4916OS 5 4921 CO 5 100 4926 PRSUPY 5931VOLEV 5932 ROVOL 5933 CROVOL 100 5946OVOL 5 6549 COVOL 5 100 6574 RIRDEM 9579RIRSHT 9580 CRRAT 9591 SROVOL 9592AROVOL 2 9592 EROVOL 9593 SOVOL 5 9594AOVOL 5 2 9594 EOVOL 5 9599 ICON 10 9604COADFG 20 9695 CCONCD 2 10 9785 CCONV 10 9805COAFXM 12 10 9815 COACNM 12 10 9935 CON -10 10065RCON -10 10085 ROCON 10 10195 OCON 5 10 10255COADDR 10 10555 COADWT 10 10605 COADEP 10 10655IHEAT 10695 SOLRAD 10700 CLOUD 10701DEWTMP 10702 GATMP 10703 WIND 10704DSOLAR 10705 BEDFLG 10714 TGFLG 10715TSTOP 10716 SHADFG 10717 ELEV 10718HTPM 6 10718 ELDAT 10719 CFSAEX 10720KATRAD 10721 KCOND 10722 KEVAP 10723LAPSE 24 10724 CFPRES 10748 MUDDEP 10749KMUD 10750 KGRND 10751 TGRNDM 12 10752DELH 100 10764 TGRND 10866 DELTT 100 10867TMUD 10967 TMUDDT 10968 RHEAT -1 10969TW 10979 HTST2 2 109np79 AIRTMP 10980SHDFAC 10983 HTEXCH 10985 ROHEAT 10986OHEAT 5 10997 QTOTAL 11027 QSOLAR 11028QLONGW 11029 QEVAP 11030 QCON 11031QPREC 11032 QBED 11033 ISED 4 11069SANDFG 11096 SDPM 6 3 11097 BEDWID 11115SDGPM 3 11115 BEDWRN 11116 POR 11117DB50E 11118 DB50M 11119 WSANDE 11120RSSED -3 11133 RSED 10 11163 SSED 4 11173TSED 3 11177 BEDDEP 11180 DEPSCR 4 11199ROSED 4 11219 OSED 5 4 11247 IDQAL 7 11367ISQAL 4 7 11402 TIQAL 7 11542 PHVAL 11549ROC 11550 BIO 7 11551 TEMPFG 11652PHFLAG 11653 ROXFG 11654 CLDFG 11655SDFG 11656 PHYTFG 11657 LAT 11658GQADFG 14 11659 GQPM2 7 7 11673 DAUGFG 7 11722GDAUFG 6 11729 QALFG 7 7 11735 QALGFG 7 11784GQALFG 7 11791 CONV 7 11855 CINV 7 11862GQAFXM 12 7 11869 GQACNM 12 7 11953 TEMPM 12 12037PHVALM 12 12049 HYDPM 4 7 12061 ROCM 12 12089ROXPM 2 7 12101 SDCNCM 12 12115 PHYM 12 12127CLDM 12 12139 ALPH 18 12151 GAMM 18 12169DEL 18 12187 LIT 18 4 12205 PHOTPM 20 7 12277FACT1 12417 KCLD 18 12418 CFGAS 7 12436BIOM 12 7 12443 BIOPM 2 7 12527 GENPM 2 7 12541C 7 7 6 12555 ADPM 6 3 7 12849 ADDCPM 4 7 12975LITFG 13003 LSET 13004 TWAT 13020PHY 13021 SDCNC 13022 CLD oq 13023DQAL 7 13024 SQAL 6 7 13031 RDQAL 7 13073RSQAL 12 7 13080 RRQAL 7 13164 GQST -7 5 13171PDQAL 7 13388 DDQAL 7 7 13423 RODQAL 7 13668DSQAL 4 7 13703 ROSQAL 4 7 13843 TROQAL 7 13983SQDEC 7 7 13990 ADQAL 7 7 14235 ODQAL 5 7 14480OSQAL 5 3 7 14655 TOSQAL 5 7 15180 TOQAL 5 7 15215GQADDR 7 15250 GQADWT 7 15285 GQADEP 7 15320BENRFG 15782 SCRVEL 15783 SCRPM 2 15783SCRMUL 15784 SCRFAC 15787 DEPCOR 15788AVDEPE 15789 AVVELE 15790 IDOX 15791IBOD 15792 REAMFG 15805 OXPM1 15805KBOD20 15806 OXPM2 4 15806 TCBOD 15807KODSET 15808 SUPSAT 15809 CFOREA 15810REAKT 15811 BENOD 15812 OXPM3 6 15812TCBEN 15813 EXPOD 15814 BRBOD 2 15815EXPREL 15817 TCGINV 15818 OXPM4 4 15818REAK 15819 EXPRED 15820 EXPREV 15821DOX 15823 OXST 2 15823 BOD 15824RDOX 15825 RBOD 15826 SATDO 15835RODOX 15839 ROBOD 15840 KOREA 15851BODOX 15852 ODOX 5 15853 OBOD 5 15858READOX 15913 BODDOX 15914 BENDOX 15915NITDOX 15916 PHYDOX 15917 ZOODOX 15918BALDOX 15919 TOTDOX 15920 DECBOD 15953BNRBOD 15954 SNKBOD 15955 DENBOD 15956PHYBOD 15957 ZOOBOD 15958 BALBOD 15959TOTBOD 15960 INO3 16009 ITAM pr 16010INO2 16011 IPO4 16012 ISNH4 4 16029ISPO4 4 16033 TNUIF 4 16069 NUADFG 6 16105TAMFG 16111 NUPM1 7 16111 NO2FG 16112PO4FG 16113 AMVFG 16114 DENFG 16115ADNHFG 16116 ADPOFG 16117 NUAFXM 12 3 16118NUACNM 12 3 16154 CVBN 16190 CVBO 16191CVBP 16192 CVBPC 16193 CVBPN 16194BPCNTC 16195 CVOC 16196 CVON 16197CVOP 16198 BRTAM 2 16199 NUPM2 5 16199BRPO4 2 16201 ANAER 16203 BNH4 3 16204NUPM3 6 16204 BPO4 3 16207 KTAM20 16210NUPM4 6 16210 KNO220 16211 TCNIT 16212KNO320 16213 TCDEN 16214 DENOXT 16215EXPNVG 16216 NUPM5 2 16216 EXPNVL 16217ADNHPM 3 16218 NUADPM 6 16218 ADPOPM 3 16221NO3 16229 DNUST 6 16229 TAM 16230NO2 16231 PO4 16232 NH4 16233NH3 16234 SNH4 3 16235 SPO4 3 16238RNO3 16241 DNUST2 6 16241 RTAM 16242RNO2 16243 RPO4 16244 RNH4 16245RNH3 16246 RSNH4 12 16247 RSPO4 12 16259RRNO3 16271 RRTAM 16272 RRNO2 16273RRPO4 16274 RONO3 16337 ROTAM 16338RONO2 16339 ROPO4 16340 ROSNH4 4 16357ROSPO4 4 16361 TNUCF1 4 16397 DSNH4 4 16401DSPO4 4 16405 NITNO3 16441 DENNO3 16442BODNO3 16443 PHYNO3 16444 ZOONO3 qs 16445BALNO3 16446 TOTNO3 16447 NITTAM 16476VOLNH3 16477 BNRTAM 16478 BODTAM 16479PHYTAM 16480 ZOOTAM 16481 BALTAM 16482TOTTAM 16483 NITNO2 16516 BNRPO4 16521BODPO4 16522 PHYPO4 16523 ZOOPO4 16524BALPO4 16525 TOTPO4 16526 ADNH4 4 16551ADPO4 4 16555 ONO3 5 16591 OTAM 5 16596ONO2 5 16601 OPO4 5 16606 OSNH4 5 4 16691OSPO4 5 4 16711 TNUCF2 5 4 16891 DECCO2 16911NUADDR 3 16912 NUADWT 3 16927 NUADEP 3 16942IPHYTO 17088 IZOO 17089 IORN 17090IORP 17091 IORC 17092 ITORN 17123ITORP 17124 ITORC 17125 ITOTN 17126ITOTP 17127 PLADFG 6 17159 PHYFG 17165PKFG 9 17165 ZOOFG 17166 BALFG 17167SDLTFG 17168 AMRFG 17169 DECFG 17170NSFG 17171 ZFOOD 17172 BNPFG 17173BFIXFG 4 17175 BINVFG 17179 PLAFXM 12 3 17180PLACNM 12 3 17216 CVBC 17252 CVBCL 17253CVNRBO 17254 CVPB 17255 RATCLP 17256PKPM1 7 17256 NONREF 17257 LITSED 17258ALNPR 17259 EXTB 17260 MALGR 17261PARADF 17262 CMMLT 17263 PKPM2 7 17263CMMN 17264 CMMNP 17265 CMMP 17266TALGRH 17267 TALGRL 17268 TALGRM 17269ALR20 17270 PKPM3 6 17270 ALDH 17271ALDL 17272 OXALD 17273 NALDH 17274rtPALDH 17275 NMINGR 17276 PKPM12 5 17276PMINGR 17277 CMINGR 17278 LMINGR 17279NMINC 17280 SEED 17281 PKPM4 6 17281MXSTAY 17282 OREF 17283 CLALDH 17284PHYSET 17285 REFSET 17286 MZOEAT 17287PKPM5 5 17287 ZFIL20 17288 ZRES20 17289ZD 17290 OXZD 17291 TCZFIL 17292PKPM6 4 17292 TCZRES 17293 ZEXDEL 17294ZOMASS 17295 MBAL 17296 PKPM7 7 17296CFBALR 17297 CFBALG 17298 MINBAL 17299CAMPR 17300 FRAVL 17301 NMAXFX 17302MBALGR 4 17303 TCBALG 4 17307 CMMNB 4 17311CMMPB 4 17315 CMMD1 4 17319 CMMD2 4 17323CSLIT 4 17327 BALR20 4 17331 TCBALR 4 17335CSLOF1 4 17339 CSLOF2 4 17343 GRORES 4 17347CREMVL 17351 PKPM8 4 17351 CMMBI 17352BINV 17353 TCGRAZ 17354 BINVM 12 17356CTRBQ1 17368 PKPM9 4 17368 CTRBQ2 17369CKTRB1 17370 CKTRB2 17371 FRRIF 17372PKPM10 5 17372 CMMV 17373 RIFCQ1 17374RIFCQ2 17375 RIFCQ3 17376 RIFVEL 4 17377PKPM11 8 17377 RIFDEP 4 17381 JDAT 17389BALDEP 17390 BALVEL 17391 PHYTO 17392PKST1 3 17392 PHYCLA 17393 LIMPHY 17394BENAL 4 17395 PKST2 4 3 17395 BALCLA 4 17399LIMBAL 4 17403 TBENAL 2 17407 ORN 17409PKST3 7 17409 ORP 17410 ORC 17411TORN su 17412 TORP 17413 TORC 17414POTBOD 17415 ZOO 17416 TN 17417PKST4 2 17417 TP 17418 ROPHYT 17441ROZOO 17442 ROORN 17443 ROORP 17444ROORC 17445 ROTORN 17466 ROTORP 17467ROTORC 17468 ROTOTN 17469 ROTOTP 17470OPHYT 5 17491 OZOO 5 17496 OORN 5 17501OORP 5 17506 OORC 5 17511 OTORN 5 17616OTORP 5 17621 OTORC 5 17626 OTOTN 5 17631OTOTP 5 17636 PLADDR 3 17741 PLADWT 3 17756PLADEP 3 17771 SNKPHY 17774 ZOOPHY 17775DTHPHY 17776 GROPHY 17777 TOTPHY 17778GROZOO 17799 DTHZOO 17800 TOTZOO 17801FLXBAL 3 4 17814 GROTBA 17874 DTHTBA 17875TOTTBA 17876 SNKORN 17889 PHYORN 17890ZOOORN 17891 BALORN 17892 TOTORN 17893SNKORP 17914 PHYORP 17915 ZOOORP 17916BALORP 17917 TOTORP 17918 SNKORC 17939PHYORC 17940 ZOOORC 17941 BALORC 17942TOTORC 17943 PYCO2 17964 ZOCO2 17965BACO2 17966 ITIC 18074 ICO2 18075PHCNT 18088 PHPM1 2 18088 ALKCON 18089CFCINV 18090 PHPM2 3 18090 BRCO2 2 18091TIC 18095 PHST 3 18095 CO2 18096PH 18097 SATCO2 18101 ROTIC 18103ROCO2 18104 OTIC 5 18115 OCO2 5 18120BODCO2 18175 PHYCO2 18176 ZOOCO2 18177BALCO2 tv 18178 BENCO2 18179 INVCO2 18180TOTCO2 18181 ACFLAG 14 18217 ACPARM 7 18231NUMCON 18239 NUMGQL 18240 ACCONC 7 18277ACSTOR 7 5 18291 ACINFL 7 5 18333 ACFLX1 7 5 18382ACFLX2 5 7 5 18424 ACFLXC 10 5 18634 ACFLXG 7 5 18694ACFLX3 7 5 18736 ACPH 18771 ACCONV 7 18773TOPFL 18780 VEGFL 18781 NSSP 18782TSA 250 12 18783 DISL 250 10 21783 DISR 250 10 24283WIDL 250 10 26783 WIDR 250 10 29283 HABSL 250 10 31783HABSR 250 10 34283 HDEML 250 10 36783 HDEMR 250 10 39283LATDEG 41783 LONDEG 41784 LONSTD 41785DENL 250 10 41786 DENR 250 10 44286 NVPL 250 46786NVPR 250 47036 JDAY 47286 LATRAD 47287SO 250 47288 TSAL 250 47538 TSAR 250 47788SKOP 250 48038 VSAL 250 48288 VSAR 250 48538DLT1 48788 DEC 48789 HFDLT 48790DF 48791 @@@@@@ 1 @@@@@@ 1YR 18 MON 19 DAY 20HR 21 MIN 22 POINT 20 110MEAN 20 130 SPOUT 28 @@@@@@ 1YR 17 MON 18 DAY 19HR 20 MIN 21 OPCODE 30NTERMS 31 K 7 32 SUM 39SPOUT 27 @@@@@@ 1 @@@@@@ 1YR 54 MON 55 DAY 56HR 57 MIN 58 SPOUT 67IVOL 69 CIVOL 100 76 VOLFRM 12 777VOLFRC uw789 ROVOL 790 CROVOL 100 796RMVOL 1396 CRMVOL 100 1402 ICON 10 2002CONFRM 12 10 2082 CONFRC 10 2272 ROCON 10 2282RMCON 10 2342 IHEAT 2402 HTFRM 12 2410HTFRC 2422 ROHEAT 2423 RMHEAT 2429ISED 3 2435 SEDFRM 12 3 2459 SEDFRC 3 2495ROSED 3 2498 RMSED 3 2516 IDQAL 3 2534ISQAL 3 3 2555 GQDFRM 12 3 2630 GQSFRM 12 3 3 2666GQDFRC 3 2795 GQSFRC 3 3 2798 RODQAL 3 2807ROSQAL 3 3 2825 RMDQAL 3 2879 RMSQAL 3 3 2897IOX 2 2951 OXFRM 12 2 2967 OXFRC 2 2991ROOX 2 2993 RMOX 2 3005 IDNUT 4 3017ISNUT 3 2 3045 DNUFRM 12 4 3097 SNUFRM 12 3 2 3145DNUFRC 4 3217 SNUFRC 3 2 3221 RODNUT 4 3227ROSNUT 3 2 3251 RMDNUT 4 3287 RMSNUT 3 2 3311IPLK 5 3347 PLKFRM 12 5 3387 PLKFRC 5 3447ROPLK 5 3452 RMPLK 5 3482 IPH 2 3512PHFRM 12 2 3528 PHFRC 2 3552 ROPH 2 3554RMPH 2 3566 IACID 7 3578 ACIFRM 12 7 3634ACIFRC 7 3718 ROACID 7 3725 RMACID 7 3767  1 1 40 2 0 0 3 0 0 4 0 0 5 0 0 6 0 0 7 0 0 8 0 0 9 0 0$ SPLON IORN SAMAD INH3SAMSU INH3 SNO3 INO3SPRON IORN SSLON IORNSSRON IORN UPLON IORNUAMAD INH3 UAMSU INH3UNO3 INO3 UPRON IORNUSLON IORN USRON IORNLPLON IORN vx LAMAD INH3LAMSU INH3 LNO3 INO3LPRON IORN LSLON IORNLSRON IORN APLON IORNAAMAD INH3 AAMSU INH3ANO3 INO3 APRON IORNASLON IORN ASRON IORNSORGP IORP SP4AD IPO4SP4SU IPO4 UORGP IORPUP4AD IPO4 UP4SU IPO4LORGP IORP LP4AD IPO4LP4SU IPO4 AORGP IORPAP4AD IPO4 AP4SU IPO4  10 1 1 5 Problem reading the following user-defined variable quantity: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC It has been ignored. o  10 1 1 5 User-defined variable quantity name &CCCCC cannot be duplicated. Names must be unique.  10 1 1 5 User-defined variable quantity &CCCCC refers to invalid operation-type &CCCCC. Valid values are: PERLND IMPLND RCHRES COPY PLTGEN DISPLY DURANL GENER MUTSINy  10 1 1 5 User-defined variable quantity &CCCCC refers to base variable in inactive operation &CCCCC &I .  10 1 1 5 User-defined variable quantity &CCCCC has a bad type code (TYPCOD). The value supplied was: &IMinimum allowed is : &I Maximum allowed is : &I  10 1 1 5 The time code for lag or aggregation of a user-defined variable quantity must be MI (minute), HR (hour), or DY (day). The value supplied for &CCCCC was &C.  10 1 1 5 The time step for lag or aggregation of a user-defined variable quantity must be non-negative. The value supplied for &CCCCC was &I .  10 1 1 5 Invalid aggregation code &CCC for user-defined quantity &CCCCC. Valid values are: SUM, AVER, MAX, MIN. Exception: Integer variables maywy not be AVERaged.  10 1 1 5 The IF statement before line &I in the SPEC-ACTIONS block is too deeply nested. The maximum nesting level is &I . v  10 1 1 5 The ELSE statement before line &I in the SPEC-ACTIONS block does not match an IF statement. x  10 1 1 5 The END IF statement before line &I in the SPEC-ACTIONS block does not match an IF statement.  10 1 1 5 The ELSE or ELSE IF statement before line &I in the SPEC-ACTIONS block follows an ELSE at the same nesting level of IF statements.  10 1 1 5 The IF or ELSE statement before line &I in the SPEC-ACTIONS block creates too many logic blocks. The maximum number of blocks is &I .  10 1 1 5 The IF or ELSE IF statement before line &I in the SPEC-ACTIONS block creates too many logic chains. The maximum number of chains is &I . $  10 1 1 5 The IF or ELSE IF statement before line &I in the SPEC-ACTIONS block creates too many logic chain references, which means that the logic is more complicated than the program can handle in the current configuration. The maximum number of chain references is &I .{  10 1 1 5 Too many user-defined variable quantities have been defined. The maximum number allowed is &I .  10 1 1 5 The left parenthesis in column &I does not appear in a proper position. Left parentheses may only appear at the beginning of a logic chain or immediately after a logic operator (AND or OR).  10 1 1 5 The right parenthesis in column &I does not appear in a proper position. Right parentheses may only appear after the second operand (quantity) of a comparison operator ( '=', '>', etc.) or another right parenthesis. j  10 1 1 5 The right parenthesis in column &I does not match a preceding left parenthesis.  10 1 1 5 The right parenthesis in cx~olumn &I is not the same type (round: "()"; square: "[]", or curly: "{}" ) as the corresponding left parenthesis. I  10 1 1 5 The quantity '&CCCCCCCCC' in column &I does not appear in a proper position. Quantities may only appear: 1) at the beginning of a logic chain, 2) immediately after a left parenthesis, 3) immediately after a logic operator (AND or OR), or 4) immediately after a comparison operator ( '=', '>', etc.)  10 1 1 5 The comparison operator '&C' in column &I does not appear in a proper position. A comparison operator may only appear immediately after a quantity which acts as its left operand.  10 1 1 5 The comparison operator '&CCCCCCCCC' in column &I is not valid. Valid options are: = != > >= < <=   10 1 1 5 The logical operator '&CC' in column &I does not appear in a proper position. A logical operator may only appear: 1) immediately after a quantity-comparison operator-quantity sequence; or 2) immediately after a right parenthesis.  10 1 1 5 The delimiter 'THEN' in column &I does not appear in a proper position. This delimiter may only appear: 1) immediately after a quantity-comparison operator-quantity sequence; or 2) immediately after a right parenthesis.  10 1 1 5 The number of right parentheses in the current conditional line does not match the number of left parentheses.  10 1 1 10 Internal pipe overflow while processing special actions. The lag plus aggregation period in intervals summed over all user-defined quantities must be less than or equal to &I intervals.  10 1 1 5 The address of base variable for user-defined variable quantity &CCCCC is beyond the end of the active sections in source operation. Address is &I . Max is &I . a  20 1 1 5 Category tag &C was supplied in message WDM file. This is a program bug. 4{ $!20000309112933 20000309112933 BMPRAC 1Tk"-q)~/L  x qKVY1HZcp r h  61b;=(q;  11 z| 1 1PRINT-INFO 101 101 301 301 1 12 1 1GEN-INFO 102 102 302 302 2 1 1 1FLOW-FLAG 103 103 303 303 3 1 1 2FLOW-FRAC 104 104 304 304 4 10 1 1CONS-FLAG 105 105 305 305 5 8 10 2CONS-FRAC 106 106 306 306 6 1 1 1HEAT-FLAG 107 107 307 307 7 1 1 2HEAT-FRAC 108 108 308 308 8 3 1 1SED-FLAG 109 109 309 309 9 3 1 2SED-FRAC 110 110 310 310 10 12 1 1GQ-FLAG 111 111 311 311 11 11 3 2GQ-FRAC 112 112 312 312 12 2 1 1OXY-FLAG 113 113 313 313 13 2 1 2OXY-FRAC 114 114 314 314 14 10 1 1NUT-FLAG 115 115 315 315 15 4 1 2DNUT-FRAC 116 116 316 316 16 6 1 2ADSNUT-FRAC 117 117 317 317 17 5 1 1PLANK-FLAG 118 118 318 318 18 5 1 2PLANK-FRAC 119 119 319 319 19 2 1 1PH-FLAG 120 120 320 320 20 2 1 2PH-FRAC 121 121 321 321 21 8 1 1ACID-FLAG 122 122 322 322 22 7 1 2ACID-FRAC 123 123 323 323 23 0 0 0END BMPRAC 000 000 000 000 S CONS-FRAC CONIDGQ-FRAC GQID   Select BMPRAC table to modify. @ PRINT-INFO @EHEAT-FLAG @ OXY-FLAG @GPLANK-FLAG @ GEN-INFO @FHEAT-FRAC @ OXY-FRAC @HPLANK-FRAC @AFLOW-FLAG @ SED-FLAG @ NUT-FLAG @ PH-FLAG @BFLOW-FRAC @ SED-FRAC @ DNUT-FRAC @ PH-FRAC @ ADSNUT-FRAC @CCONS-FLAG @ GQ-FLAG @IACID-FLAG @DCONS-FRAC @ GQ-FRAC @JACID-FRAC @@ PRINT-INFO p Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC PRINT-INFO table.`{} 1 A@ GEN-INFO n! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC GEN-INFO table. a )A@A o! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC FLOW-FLAG table. a - B@B o" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC FLOW-FRAC table. b -B@C o" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC CONS-FLAG table. b -C@D o# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC CONS-FRAC table. c -C@E o# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC HEAT-FLAG table. c -D@F o$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC HEAT-FRAC table. d -  D@ SED-FL n$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC SED-FLAG table. d )$ E@ SED-FR n% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC SED-FRAC table. e )(E@ GQ-FLm% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC GQ-FLAG table. e %,F@ GQ-FRm& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC GQ-FRAC table. f %0 F@ OXY-FL n& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC OXY-FLAG table. f )4 G@ OXY-FR n' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC OXY-FRAC table. g )8G@ NUT- n' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC NUT-FLAG table. g )<H@ DN|~UT-o( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC DNUT-FRAC table. h -@ H@ ADSNUT- q( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC ADSNUT-FRAC table. h 5DI@G p) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC PLANK-FLAG table.i 1HI@H p) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC PLANK-FRAC table.i 1LJ@ PH-FLm* Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC PH-FLAG table. j %PJ@ PH-FRm* Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC PH-FRAC table. j %TK@I o+ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC ACID-FLAG table. k -XK@J o+ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the BMPRAC ACID-FRAC table. k -\c BMPRAC Printout level flags x - x FLOW CONS HEAT SED GQ OXY NUT PLNK PH PIVL PYR PRINT-INFO @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(4 !Printout level for flow. FLOWPR AFIELD4 a(4 "!Printout level for conservatives. CONSPR BFIELD5 b(4 "Printout level for heat. HEATPR BFIELD6 b(4 "Printout level for sediment. SEDPR CFIELD7 c(4 "#Printout level for general quals. GQPR CFIELD8 c(4 &#Printout level for oxygen components. OXRXPR DFIELD9 d(4 $Printout level for nutrients. NUTPR DFIELD10d(4 ($Printout level for plank}ton components.PLNKPR EFIELD11e(4 ,%Printout level for pH and inorganic carbon.PHPR EFIELD12e(1 "%A value need only be supplied for PIVL if one or moresections have a printout level of 2. For those sections,printout will occur every PIVL intervals (that is, everyPDELT=PIVL*DELT mins). PIVL must be chosen such that thereare an integer no. of PDELT periods in a day. PIVL FFIELD13f( 9 &PYREND is the calendar month which will terminate the yearfor printout purposes. Thus, the annual summary can reflectthe situation over the past water year or the past calendaryear, etc. PYREND Table of printout level flags for BMPRAC.HSPF permits the user to vary the printout level (maximumfrequency) for the various active sections of an operation.2 means every PIVL intervals, 3 means every day, 4 meansevery month, 5 means every year, 6 means never. (1X,9I5,5X,2I10) Printout level flags Print-ivl Print-yrend FLOW CONS HEAT SED GQ OXY NUT PLNK PH PIVL PYREND  Name BMP Unit Systems Printer BMPRAC Type NCON NGQ t-series Engl Metr x - x<------------------> in out GEN-INFO @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 R!Any string of up to 20 characters may be supplied as theidentifier for a BMPRAC. BMPID aAFIELD4 a(1 t!BMPTYP is the type of BMP implementation. 1 means simple removalfractions. No other type is currently supported.BMPTYP BFIELD5 b( 0 ="NCONS is the number of conservative constituents simulated. NCONS BFIELD6 b(0 J"NGQUAL is the number of generalized constituents (quals)being simulated. NGQUAL ~CFIELD7 c(1 u#IUNITS indicates the system of units for data in the inputtime series; 1 means English units, 2 means Metric units. IUNITS CFIELD8 c(1 v#OUNITS indicates the system of units for data in the outputtime series; 1 means English units, 2 means Metric units. OUNITS DFIELD9 d(c0 $PUNIT(1) indicates the destinations of printout in Englishunits. A value 0 means no printout is required in Englishunits. A non-zero value means printout is required inEnglish units and the value is the Fortran unit no. of thefile to which the printout is to be written. Note thatprintout for each BMP can be obtained in either the Englishor Metric systems, or both (irrespective of the system usedto supply the inputs). PUNITE DFIELD10d(c0 $PUNIT(2) indicates the destinations of printout in Metricunits. A value 0 means no printout is required in Metricunits. A non-zero value means printout is required inMetric units and the value is the Fortran unit no. of thefile to which the printout is to be written. Note thatprintout for each BMP can be obtained in either the Englishor Metric systems, or both (irrespective of the system usedto supply the inputs).PUNITM General information for BMPRAC. (1X,5A4,3I10,10X,2I10,10X,2I10)Best Management-id BMPTYP NCONS NGQUAL Unit systems Print-file nos IUNITS OUNITS English Metric 1 BMPRAC Monthly variable flag x - x VOLF FLOW-FLAG @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for flow isconstant, given in FLOW-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specifythe monthly removal factors. VOLFFG Flow flags. (1X,I10) Flow flag VOLFFG 1 BMPRAC Removal fraction x - x VOLFRC FLOW-FRAC @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 aP?0. -!VOLFRC is the BMP removal fraction for flow. VOLFRC Removal fraction for flow. / (1X,1PE10.3)Flow removal fraction VOLFRC j BMPRAC Monthly variable flags x - x C1F C2F C3F C4F C5F C6F C7F C8F C9F C10F CONS-FLAG @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for conservativeconstituent #1 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(1) AFIELD4 a(0 !Value of 0 indicates that the BMP removal factor for conservativeconstituent #2 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(2) BFIELD5 b(0 "Value of 0 indicates that the BMP removal factor for conservativeconstituent #3 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(3) BFIELD6 b(0 "Value of 0 indicates that the BMP removal factor for conservativeconstituent #4 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(4) CFIELD7 c(0 #Value of 0 indicates that the BMP removal factor for conservativeconstituent #5 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(5) CFIELD8 c(0 #Value of 0 indicates that the BMP removal factor for conservativeconstituent #6 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(6) DFIELD9 d(0 $Value of 0 indicates that the BMP removal factor for conservativeconstituent #7 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(7) DFIELD10d(0 $Value of 0 indicates that the BMP removal factor for conservativeconstituent #8 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(8) EFIELD11e(0 %Value of 0 indicates that the BMP removal factor for conservativeconstituent #9 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(9) EFIELD12e(0 %Value of 0 indicates that the BMP removal factor for conservativeconstituent #10 is constant, given in CONS-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. CONFFG(10) Conservative constituent flags. (1X,10I10) Conservative Constituent Flags CONS1 CONS2 CONS3 CONS4 CONS5 CONS6 CONS7 CONS8 CONS9 CONS10 l BMPRAC Name Units Removal fraction x - x<-------CONID------> CONFRC CONS-FRAC @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 _!Any string of up to 20 characters may be supplied as thename of the conservative constituent. CONID aAFIELD4 !CQTYID is a string of up to 8 characters which specifies theunits in which the inflows and outflows of constituent willbe expressed, eg "kg".CQTYID a@BFIELD5 bP?0. I"CONFRC(*) is the BMP removal fraction for this conservativeconstituent. CONFRC(*) :Name and removal fraction for one conservative substance. (1X,5A4,2X,2A4,1PE10.3) Conservative data Name Units Removal fraction CONID CQTYID CONFRC 1 BMPRAC Monthly variable flag x - x HTF HEAT-FLAG @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for heat isconstant, given in HEAT-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specifythe monthly removal factors. HTFFG Heat flags. (1X,I10) Heat flag HTFFG 1 BMPRAC Removal fraction x - x HTFRC HEAT-FRAC @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 aP?0. (!HTFRC is the removal fraction for heat.HTFRC Removal fraction for heat. / (1X,1PE10.3)Heat removal fraction HTFRC < BMPRAC Monthly variable flags x - x Sand Silt Clay SED-FLAG @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for sand isconstant, given in SED-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specifythe monthly removal factors. SEDFG(1) AFIELD4 a(0 ؀!Value of 0 indicates that the BMP removal factor for silt isconstant, given in SED-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specifythe monthly removal factors. SEDFG(2) BFIELD5 b(0 "Value of 0 indicates that the BMP removal factor for clay isconstant, given in SED-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specifythe monthly removal factors. SEDFG(3) Sediment flags.B (1X,3I10) Sediment flags SAND SILT CLAY N BMPRAC Removal fractions x - x sand silt clay SED-FRAC @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 aP?0. 0!SEDFRC(1) is the BMP removal fraction for sand. SEDFRC(1) AFIELD4 aP?0. 0!SEDFRC(2) is the BMP removal fraction for silt. SEDFRC(2) BFIELD5 bP?0. 0"SEDFRC(3) is the BMP removal fraction for clay. SEDFRC(3) Removal fractions for sediment.J (1X,3PE10.3) Sediment removal fractions Sand Silt Clay  Monthly variable flags BMPRAC<------Qual 1------><------Qual 2------><------Qual 3------> x - x Soln Sand Silt Clay Soln Sand Silt Clay Soln Sand Silt Clay  GQ-FLAG@@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for qual #1 insolution is constant, given in GQ-FRAC. A value greater than 0indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. GQFFG(1) AFIELD4 a(0 !Value of 0 indicates that the BMP removal factor for qual #1adsorbed to sand is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(2) BFIELD5 b(0 "Value of 0 indicates that the BMP removal factor for qual #1adsorbed to silt is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(3) BFIELD6 b(0 "Value of 0 indicates that the BMP removal factor for qual #1adsorbed to clay is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(4) CFIELD7 c(0 #Value of 0 indicates that the BMP removal factor for qual #2 insolution is constant, given in GQ-FRAC. A value greater than 0indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. GQFFG(5) CFIELD8 c(0 #Value of 0 indicates that the BMP removal factor for qual #2adsorbed to sand is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(6) DFIELD9 d(0 $Value of 0 indicates that the BMP removal factor for qual #2adsorbed to silt is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(7) DFIELD10d(0 $Value of 0 indicates that the BMP removal factor for qual #2adsorbed to clay is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(8) EFIELD11e(0 %Value of 0 indicates that the BMP removal factor for qual #3 insolution is constant, given in GQ-FRAC. A value greater than 0indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. GQFFG(9) EFIELD12e(0 %Value of 0 indicates that the BMP removal factor for qual #3adsorbed to sand is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(10) FFIELD13f(0 &Value of 0 indicates that the BMP removal factor for qual #3adsorbed to silt is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(11) FFIELD14f(0 &Value of 0 indicates that the BMP removal factor for qual #3adsorbed to clay is constant, given in GQ-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. GQFFG(12) "General constituent (qual) flags. 0 (1X,12I10) Generalized Quality Constituent Flags QUAL 1 QUAL 2 QUAL 3 soln sand silt clay soln sand silt clay soln sand silt clay BMPRAC Name Units Removal fractions x - x<-------GQID-------> Soln Sand Silt Clay  GQ-FRAC@@FIELD1 " BMPRAC to which these data apply. OPNID `AAFIELD3 f!Any string of up to 20 characters may be supplied as thename of the generalized quality constituent. GQID aAFIELD4 !GQTYID is a string of up to 8 characters which specifies theunits in which the inflows and outflows of the qual willbe expressed, eg "kg". GQTYID a@BFIELD5 bP?0. >"GQDFRC is the BMP removal fraction for this qual in solution. GQDFRC(*) BFIELD6 bP?0. H"GQSFRC(1,*) is the BMP removal fraction for this qual adsorbed to sand. GQSFRC(1,*)CFIELD7 cP?0. H#GQSFRC(2,*) is the BMP removal fraction for this qual adsorbed to silt. GQSFRC(2,*)CFIELD7 cP?0. H#GQSFRC(3,*) is the BMP removal fraction for this qual adsorbed to clay. GQSFRC(3,*)CName and removal fraction for one generalized quality constituent. (1X,5A4,2X,2A4,4(1PE10.3)) Qual data Name Units Removal fractions GQID GQTYID Soln Sand Silt Clay 8 BMPRAC Monthly variable flags x - x DOXF BODF OXY-FLAG @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for dissolvedoxygen is constant, given in OXY-FRAC. A value greater than 0indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. OXFFG(1) AFIELD4 a(0 !Value of 0 indicates that the BMP removal factor for biochemicaloxygen demand is constant, given in OXY-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. OXFFG(2) Oxygen components flags. 7 (1X,2I10) Oxygen component flags DOX BOD > BMPRAC Removal fractions x - x DOX BOD OXY-FRAC @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 aP?0. <!OXYFRC(1) is the BMP removal fraction for dissolved oxygen. OXYFRC(1) AFIELD4 aP?0. E!OXYFRC(2) is the BMP removal fraction for biochemical oxygen demand. OXYFRC(2) )Removal fractions for oxygen components. I (1X,2PE10.3) Oxygen components removal fractions DOX BOD  Monthly variable flags BMPRAC<-----Solution-----><---Ads-NH4---><---Ads-PO4---> x - x NO3 TAM NO2 PO4 Sand Silt Clay Sand Silt Clay NUT-FLAG @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for nitrateis constant, given in DNUT-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specify themonthly removal factors. NUTFFG(1) AFIELD4 a(0 !Value of 0 indicates that the BMP removal factor for dissolvedammonia is constant, given in DNUT-FRAC. A value greater than 0indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. NUTFFG(2) BFIELD5 b(0 "Value of 0 indicates that the BMP removal factor for nitriteis constant, given in DNUT-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specify themonthly removal factors. NUTFFG(3) BFIELD6 b(0 "Value of 0 indicates that the BMP removal factor for dissolvedphosphate is constant, given in DNUT-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. NUTFFG(4) CFIELD7 c(0 #Value of 0 indicates that the BMP removal factor for ammoniaadsorbed to sand is constant, given in ADSNUT-FRAC. A valuegreater than 0 indicates the index number of the MONTH-DATAblock to be used to specify the monthly removal factors. NUTFFG(5) CFIELD8 c(0 #Value of 0 indicates that the BMP removal factor for ammoniaadsorbed to silt is constant, given in ADSNUT-FRAC. A valuegreater than 0 indicates the index number of the MONTH-DATAblock to be used to specify the monthly removal factors. NUTFFG(6) DFIELD9 d(0 $Value of 0 indicates that the BMP removal factor for ammoniaadsorbed to clay is constant, given in ADSNUT-FRAC. A valuegreater than 0 indicates the index number of the MONTH-DATAblock to be used to specify the monthly removal factors. NUTFFG(7) DFIELD10d(0 $Value of 0 indicates that the BMP removal factor for phosphateadsorbed to sand is constant, given in ADSNUT-FRAC. A valuegreater than 0 indicates the index number of the MONTH-DATAblock to be used to specify the monthly removal factors. NUTFFG(8) EFIELD11e(0 %Value of 0 indicates that the BMP removal factor for phosphateadsorbed to silt is constant, given in ADSNUT-FRAC. A valuegreater than 0 indicates the index number of the MONTH-DATAblock to be used to specify the monthly removal factors. NUTFFG(9) EFIELD12e(0 %Value of 0 indicates that the BMP removal factor for phosphateadsorbed to clay is constant, given in ADSNUT-FRAC. A valuegreater than 0 indicates the index number of the MONTH-DATAblock to be used to specify the monthly removal factors. NUTFFG(10) Nutrient flags. (1X,10I10) Nutrient flags Solution Adsorbed Ammonia Adsorbed Phosphate NO3 TAM NO2 PO4 SAND SILT CLAY SAND SILT CLAY ^ BMPRAC Removal fractions x - x NO3 TAM NO2 PO4 DNUT-FRAC @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 aP?0. =!DNUFRC(1) is the BMP removal fraction for dissolved nitrate. DNUFRC(1) AFIELD4 aP?0. C!DNUFRC(2) is the BMP removal fraction for dissolved total ammonia. DNUFRC(2) BFIELD5 bP?0. ="DNUFRC(3) is the BMP removal fraction for dissolved nitrite. DNUFRC(3) BFIELD6 bP?0. D"DNUFRC(4) is the BMP removal fraction for dissolved orthophosphate. DNUFRC(4) +Removal fractions for dissolved nutrients. ] (1X,4PE10.3) Dissolved nutrient removal fractions NO3 TAM NO3 PO4  Removal fractions BMPRAC Ammonia Phosphate x - x Sand Silt Clay Sand Silt Clay ADSNUT-FRAC@@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 aP?0. D!SNUFRC(1) is the BMP removal fraction for ammonia adsorbed to sand. SNUFRC(1) AFIELD4 aP?0. D!SNUFRC(2) is the BMP removal fraction for ammonia adsorbed to silt. SNUFRC(2) BFIELD5 bP?0. D"SNUFRC(3) is the BMP removal fraction for ammonia adsorbed to clay. SNUFRC(3) BFIELD6 bP?0. F"SNUFRC(4) is the BMP removal fraction for phosphate adsorbed to sand. SNUFRC(4) CFIELD7 cP?0. F#SNUFRC(5) is the BMP removal fraction for phosphate adsorbed to silt. SNUFRC(5) CFIELD8 cP?0. F#SNUFRC(6) is the BMP removal fraction for phosphate adsorbed to clay. SNUFRC(6) *Removal fractions for adsorbed nutrients. (1X,6PE10.3) Adsorbed nutrient removal fractions Ammonia Phosphate Sand Silt Clay Sand Silt ClayG BMPRAC Monthly variable flags x - x Phyt Zoo ORN ORP ORC PLANK-FLAG @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for phytoplanktonis constant, given in PLANK-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specify themonthly removal factors. PLKFFG(1) AFIELD4 a(0 !Value of 0 indicates that the BMP removal factor for zooplanktonis constant, given in PLANK-FRAC. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to specify themonthly removal factors. PLKFFG(2) BFIELD5 b(0 "Value of 0 indicates that the BMP removal factor for dead refractoryorganic nitrogen is constant, given in PLANK-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to be usedto specify the monthly removal factors. PLKFFG(3) BFIELD4 b(0 "Value of 0 indicates that the BMP removal factor for dead refractoryorganic phosphorus is constant, given in PLANK-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to be usedto specify the monthly removal factors. PLKFFG(4) CFIELD7 c(0 #Value of 0 indicates that the BMP removal factor for dead refractoryorganic carbon is constant, given in PLANK-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. PLKFFG(5) Plankton components flags. d (1X,5I10) Plankton component flags PHYT ZOO ORN ORP ORCk BMPRAC Removal Fractions x - x Phyt Zoo ORN ORP ORC PLANK-FRAC @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 aP?0. 9!PLKFRC(1) is the BMP removal fraction for phytoplankton. PLKFRC(1) AFIELD4 aP?0. 7!PLKFRC(2) is the BMP removal fraction for zooplankton. PLKFRC(2) BFIELD5 bP?0. L"PLKFRC(3) is the BMP removal fraction for dead refractory organicnitrogen. PLKFRC(3) BFIELD6 bP?0. N"PLKFRC(4) is the BMP removal fraction for dead refractory organicphosphorus. PLKFRC(4) CFIELD7 cP?0. J#PLKFRC(5) is the BMP removal fraction for dead refractory organiccarbon. PLKFRC(5) +Removal fractions for plankton components. h (1X,5PE10.3) Plankton components removal fractions Phyto Zoo Org N Org P Org C8 BMPRAC Monthly variable flags x - x TIC CO2 PH-FLAG@@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 !Value of 0 indicates that the BMP removal factor for totalinorganic carbon is constant, given in PH-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. PHFFG(1) AFIELD4 a(0 !Value of 0 indicates that the BMP removal factor for dissolvedcarbon dioxide is constant, given in PH-FRAC. A value greaterthan 0 indicates the index number of the MONTH-DATA block to beused to specify the monthly removal factors. PHFFG(2) #Inorganic carbon components flags. A (1X,2I10) Inorganic carbon component flags TIC CO2 ? BMPRAC Removal fractions x - x TIC CO2  PH-FRAC@@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 aP?0. A!PHFRC(1) is the BMP removal fraction for total inorganic carbon. PHFRC(1) AFIELD4 aP?0. C!PHFRC(2) is the BMP removal fraction for dissolved carbon dioxide. PHFRC(2) 3Removal fractions for inorganic carbon components. S (1X,2PE10.3) Inorganic carbon components removal fractions TIC CO2 ` BMPRAC Num Monthly variable flags x - x Chem ACI1 ACI2 ACI3 ACI4 ACI5 ACI6 ACI7 ACID-FLAG @@FIELD1 " BMPRAC to which these data apply. OPNID `QAFIELD3 a(0 ?!Number of chemicals used in acid mine drainage section ACIDPH. NACID AFIELD4 a(0 !Value of 0 indicates that the BMP removal factor for acid minechemical #1 is constant, given in ACID-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. ACIFFG(1) BFIELD5 b(0 "Value of 0 indicates that the BMP removal factor for acid minechemical #2 is constant, given in ACID-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. ACIFFG(2) BFIELD6 b(0 "Value of 0 indicates that the BMP removal factor for acid minechemical #3 is constant, given in ACID-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. ACIFFG(3) CFIELD7 c(0 #Value of 0 indicates that the BMP removal factor for acid minechemical #4 is constant, given in ACID-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. ACIFFG(4) CFIELD8 c(0 #Value of 0 indicates that the BMP removal factor for acid minechemical #5 is constant, given in ACID-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. ACIFFG(5) DFIELD9 d(0 $Value of 0 indicates that the BMP removal factor for acid minechemical #6 is constant, given in ACID-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. ACIFFG(6) DFIELD10d(0 $Value of 0 indicates that the BMP removal factor for acid minechemical #7 is constant, given in ACID-FRAC. A value greater than0 indicates the index number of the MONTH-DATA block to be used tospecify the monthly removal factors. ACIFFG(7) %Acid mine drainage components flags. u (1X,7I10) Acid mine drainage component flags ACI1 ACI2 ACI3 ACI4 ACI5 ACI6 ACI7  BMPRAC Removal fractions x - x ACI1 ACI2 ACI3 ACI4 ACI5 ACI6 ACI7 ACID-FRAC @@FIELD1 " BMPRAC to which these data apply. OPNID `AAFIELD3 aP?0. A!ACIFRC(1) is the BMP removal fraction for acid mine chemical #1. ACIFRC(1) AFIELD4 aP?0. A!ACIFRC(2) is the BMP removal fraction for acid mine chemical #2. ACIFRC(2) BFIELD5 bP?0. A"ACIFRC(3) is the BMP removal fraction for acid mine chemical #3. ACIFRC(3) BFIELD6 bP?0. A"ACIFRC(4) is the BMP removal fraction for acid mine chemical #4. ACIFRC(4) CFIELD7 cP?0. A#ACIFRC(5) is the BMP removal fraction for acid mine chemical #5. ACIFRC(5) CFIELD8 cP?0. A#ACIFRC(6) is the BMP removal fraction for acid mine chemical #6. ACIFRC(6) DFIELD9 dP?0. A$ACIFRC(7) is the BMP removal fraction for acid mine chemical #7. ACIFRC(7) 3Removal fractions for acid mine drainage chemicals (1X,7PE10.3) Acid mine drainage chemcial removal fractions ACI1 ACI2 ACI3 ACI4 ACI5 ACI6 ACI7} $!20000607144934 20000607144934 PLTGENTS INPUT 10 POINTMEAN POINT 20 1 -2 1 1 0 2 0 1064 ENG any 0 1 0 1 Point-valued input time series MET any 0 1 0 1 MEAN 99 1 -3 1 2 0 2 0 1084 ENG any 0 1 0 1 Mean-valued input time series MET any 0 1 0 1 4 $!20000309112934 20000309112934 HPERAGUTj!` !P  20 1 1 5 5 -4&D Pervious land segment: &I Layer: &CCC The iteration technique (subroutine iter) used to solve the Freundlich adsorption/desorption equation did not converge within the allowed no. of iterations. Relevant data are: Pesticide &CCCCCCCCCCCCCCCCCCC Frac TCM X Soilm C MOISTM &R &R &R &R &R &R Where: Frac is the ratio of total (adsorbed+solution) pesticide (TCM) to the value implied by the values of X and C X is the adsorbed conc (ppm, on soil) after the last iteration C is the solution conc (ppm, in water) after the last iteration Soilm is the mass of soil in this layer (lb/acre or kg/ha) moistm is the mass of water in this layer (lb/acre or kg/ha) (TCM is in lb/acre or kg/ha))  20 11 0 5 5 -4&D Pervious land segment: &I The quantity of soil/sediment removed from the surface in this time interval exceeds the quantity of soil in the surface layer. Thus, the computed value of FSD was > 1.0 . FSD will be arbitrarily reduced to 1.0 . Relevant data are: FSD SOSED SLME &R &R &R Where: FSD is SOSED/SLME SOSED is the total quantity of soil/sediment removed from the surface (tons/acre) SLME is the mass of soil in the surface layer (tons/acre) p  5 11 0 5 5 -4&D Pervious land segment: &I The simulated quantity of soil/sediment removed from the surface in this interval is less than 1/100000 of the quantity of soil in the surface layer. To avoid likely resulting problems due to lack of significance (using single precision variables), FSD will be arbitrarily set to zero. Relevant data are: FSD SOSED SLME &R &R &R Where: FSD is SOSED/SLME SOSED is the total quantity of soil/sediment removed from the surface (tons/acre) SLME is the mass of soil in the surface layer (tons/acre)  20 11 0 5 5 -4 Pervious land segment: &I Layer: &CCC The combination of recalculation interval and one or more rate parameters for first-order reactions is such that the computing algorithm will likely try to generate negative concentrations. The rate parameters in question are indicated by a "1" printed below the following set of numbers. Value no. in user's input table: 1 2 3 4 5 6 7 8 9 10 &I &I &I &I &I &I &I &I &I &I @  20 1 1 5 Crop dates specified in Table-type CROP-DATES are not consistent. The planting and harvesting dates for crop number &I are: &I /&I - &I /&I and the planting and harvesting dates for crop number &I are: &I /&I - &I /&I Cropping seasons are not allowed to overlap.4 $!20000309112934 20000309112934 HDSSUT ""  1 2 1 5DSS file number &I is an incorrect DSS version; processing must terminate.Version returned by ZINQIR is &CCCC. Only versions 6-* are allowed by HSPF. $!20000309112934 20000309112934 HPRBUT $$$$`  The count for the ERROR printed above has reached its maximum. The RUN has been terminated.j  The count for ERRORs generated by the RUN INTERPRETER is at its maximum. The RUN has been terminated.  The count for the WARNING printed above has reached its maximum. If the condition is encountered again the message will not be repeated.  133 259 333 459 34 4 6 1 2IRRIG-SOURCE 134 134 334 334 35 4 6 1 2IRRIG-TARGET 135 135 335 335 36 4 14 1 2IRRIG-SCHED 136 260 336 460 37 4 12 1 2MON-IRR-CRDP 137 261 337 461 38 4 12 1 2MON-IRR-AWD 138 138 338 338 39 4 0 0 0CCCCCCCCCCCC 000 000 000 000 40 3 1 1SED-PARM1 139 139 339 339 41 5 6 1 2SED-PARM2 140 262 340 462 42 5 4 1 2SED-PARM3 141 141 341 341 43 5 12 1 2MON-COVER 142 142 342 342 44 5 12 1 2MON-NVSI 143 263 343 463 45 5 1 1 2SED-STOR 144 264 344 464 46 5 4 1 1PSTEMP-PARM1 145 145 345 345 47 6 6 1 2PSTEMP-PARM2 146 265 346 465 48 6 12 1 2MON-ASLT 147 266 347 466 49 6 12 1 2MON-BSLT 148 267 348 467 50 6 12 1 2MON-ULTP1 149 268 349 468 51 6 12 1 2MON-ULTP2 150 269 350 469 52 6 12 1 2MON-LGTP1 151 270 351 470 53 6 12 1 2MON-LGTP2 152 271 352 471 54 6 4 1 2PSTEMP-TEMPS 153 272 353 472 55 6 0 0 0EEEEEEEEEEEE 000 000 000 000 56 0 0 0FFFFFFFFFFFF 000 000 000 000 57 4 1 1PWT-PARM1 154 154 354 354 58 7 5 1 2PWT-PARM2 155 273 355 473 59 7 4 1 2LAT-FACTOR 156 156 356 356 60 7 12 1 2MON-IFWDOX 157 157 357 357 61 7 12 1 2MON-IFWCO2 158 158 358 358 62 7 12 1 2MON-GRNDDOX 159 159 359 359 63 7 12 1 2MON-GRNDCO2 160 160 360 360 64 7 3 1 2PWT-TEMPS 161 274 361 74 65 7 6 1 2PWT-GASES 162 162 362 362 66 7 1 1 1NQUALS 163 163 363 363 67  8 20 1 1PQL-AD-FLAGS 164 164 364 364 68 8 13 10 1QUAL-PROPS 165 165 365 365 69 81 8 10 2QUAL-INPUT 166 275 366 75 70 81 12 10 2MON-POTFW 167 276 367 76 71 81 12 10 2MON-POTFS 168 277 368 77 72 81 12 10 2MON-ACCUM 169 278 369 78 73 81 12 10 2MON-SQOLIM 170 279 370 79 74 81 12 10 2MON-IFLW-CONC 171 280 371 80 75 81 12 10 2MON-GRND-CONC 172 281 372 81 76 81 0 0 0GGGGGGGGGGGG 000 000 000 000 77 0 0 0HHHHHHHHHHHH 000 000 000 000 78 1 1 1VUZFG 173 173 373 373 79 9 3 1 2UZSN-LZSN 174 282 374 82 80 9 3 1 2MST-PARM 175 175 375 375 81 9 3 1 2MST-TOPSTOR 176 283 376 83 82 9 5 1 2MST-TOPFLX 177 177 377 377 83 9 2 1 2MST-SUBSTOR 178 284 378 84 84 9 3 1 2MST-SUBFLX 179 179 379 379 85 9 7 1 1PEST-FLAGS 180 180 380 380 86 10 18 1 1PEST-AD-FLAGS 181 181 381 381 87 10 5 3 2PEST-ID 182 182 382 382 88 10 2 3 2PEST-THETA 183 183 383 383 89 10 1 12 2PEST-FIRSTPM 184 184 384 384 90 10 1 3 2PEST-CMAX 185 185 385 385 91 10 3 12 2PEST-SVALPM 186 186 386 386 92 10 4 12 2PEST-NONSVPM 187 187 387 387 93 10 4 3 2PEST-DEGRAD 188 188 388 388 94 10 3 12 2PEST-STOR1 189 285 389 85 95 10 1 3 2PEST-STOR2 190 286 390 86 96 10 0 0 0IIIIIIIIIIII 000 000 000 000 97 0 0 0JJJJJJJJJJJJ 000 000 000 000 98 10 1 1NIT-FLAGS 191 191 391 391 99 11 12 1 1NIT-AD-FLAGS 192 192 392 392 100 11 4 1 2NIT-UPTAKE 193 193 393 393 101 11 12 4 2MON-NITUPT 194 194 394 394 102 11 10 1 2NIT-FSTGEN 195 195 395 395 103 11 7 4 2NIT-FSTPM 196 196 396 396 104 11 1 1 2NIT-CMAX 197 197 397 397 105 11 3 4 2NIT-SVALPM 198 198 398 398 106 11 4 4 2NIT-UPIMKMAX 199 199 399 399 107 11 4 4 2NIT-UPIMCSAT 200 200 400 400 108 11 12 4 2MON-NITUPNI 201 201 401 401 109 11 12 4 2MON-NITUPAM 202 202 402 402 110 11 12 4 2MON-NITIMNI 203 203 403 403 111 11 12 4 2MON-NITIMAM 204 204 404 404 112 11 5 1 2NIT-AMVOLAT 205 205 405 405 113 11 2 1 2NIT-YIELD 206 287 406 87 114 11 12 1 2MON-NUPT-FR1 207 207 407 407 115 11 12 4 2MON-NUPT-FR2 208 208 408 408 116 11 4 4 2NIT-ORGPM 209 209 409 409 117 11 5 1 2NIT-BGPLRET 210 210 410 410 118 11 4 1 2NIT-AGPLRET 211 211 411 411 119 11 12 4 2MON-NPRETBG 212 212 412 412 120 11 12 1 2MON-NPRETAG 213 213 413 413 121 11 12 2 2MON-NPRETLI 214 214 414 414 122 11 12 1 2MON-NPRETFBG 215 215 415 415 123 11 12 1 2MON-NPRETFLI 216 216 416 416 124 11 4 1 2NIT-AGUTF 217 217 417 417 125 11 12 4 2MON-NITAGUTF 218 218 418 418 126 11 6 4 2NIT-STOR1 219 288 419 88 127 11 6 1 2NIT-STOR2 220 289 420 89 128 11 0 0 0KKKKKKKKKKKK 000 000 000 000 129 0 0 0LLLLLLLLLLLL 000 000 000 000 130 6 1 1PHOS-FLAGS 221 221 421 421 131 12 8 1 1PHOS-AD-FLAGS 222 222 422 422 132 12 4 1 2PHOS-UPTAKE 223 223 423 423 133 12 12 4 2MON-PHOSUPT 224 224 424 424 134 12 5 1 2PHOS-FSTGEN 225 225 425 425 135 12 4 4 2PHOS-FSTPM 226 226 426 426 136 12 1 1 2PHOS-CMAX 227 227 427 427 137 12 3 4 2PHOS-SVALPM 228 228 428 428 138 12 2 1 2PHOS-YIELD 229 290 429 90 139 12 12 1 2MON-PUPT-FR1 230 230 430 430 140 12 12 4 2MON-PUPT-FR2 231 231 431 431 141 12 4 4 2PHOS-STOR1 232 291 432 91 142 12 1 1 2PHOS-STOR2 233 292 433 92 143 12 4 1 1TRAC-AD-FLAGS 234 234 434 434 144 13 5 1 2TRAC-ID 235 235 435 435 145 13 2 1 2TRAC-TOPSTOR 236 293 436 93 146 13 2 1 2TRAC-SUBSTOR 237 294 437 94 147 13 0 0 0END PERLND 000 000 000 000 148 GENERAL 1ATEMP 2SNOW 3PWATER 4SEDMNT 5PSTEMP 6PWTGAS 7PQUAL 8MSTLAY 9PEST 10NITR 11PHOS 12TRACER 13) CROP-STAGES FIRST CROPCROP-STAGES SECOND CROPCROP-STAGES THIRD CROPCROP-SEASPM FIRST CROPCROP-SEASPM SECOND CROPCROP-SEASPM THIRD CROPQUAL-PROPS QUALIDQUAL-INPUT QUALIDMON-POTFW QUALID QSDFGMON-POTFS QUALID QSDFGMON-ACCUM QUALID QSOFGMON-SQOLIM QUALID QSOFGMON-IFLW-CONC QUALID QIFWFGMON-GRND-CONC QUALID QAGWFGPEST-ID PESTIDPEST-THETA PESTIDPEST-FIRSTPM SURFACE LAYER PESTIDPEST-FIRSTPM UPPER LAYER PESTIDPEST-FIRSTPM LOWER LAYER PESTIDPEST-FIRSTPM GROUNDWATER LAYER PESTIDPEST-CMAX PESTIDPEST-SVALPM SURFACE LAYER PESTIDPEST-SVALPM UPPER LAYER PESTIDPEST-SVALPM LOWER LAYER PESTIDPEST-SVALPM GROUNDWATER LAYER PESTIDPEST-NONSVPM SURFACE LAYER PESTIDPEST-NONSVPM UPPER LAYER PESTIDPEST-NONSVPM LOWER LAYER PESTIDPEST-NONSVPM GROUNDWATER LAYER PESTIDPEST-DEGRAD PESTIDPEST-STOR1 SURFACE LAYER PESTIDPEST-STOR1 UPPER LAYER PESTIDPEST-STOR1 LOWER LAYER PESTIDPEST-STOR1 GROUNDWATER LAYER PESTIDPEST-STOR2 PESTIDMON-NITUPT SURFACE LAYERMON-NITUPT UPPER LAYERMON-NITUPT LOWER LAYERMON-NITUPT GROUNDWATER LAYERNIT-FSTPM SURFACE LAYERNIT-FSTPM UPPER LAYERNIT-FSTPM LOWER LAYERNIT-FSTPM GROUNDWATER LAYERNIT-SVALPM SURFACE LAYERNIT-SVALPM UPPER LAYERNIT-SVALPM LOWER LAYERNIT-SVALPM GROUNDWATER LAYERNIT-UPIMKMAX SURFACE LAYERNIT-UPIMKMAX UPPER LAYERNIT-UPIMKMAX LOWER LAYERNIT-UPIMKMAX GROUNDWATER LAYERNIT-UPIMCSAT SURFACE LAYERNIT-UPIMCSAT UPPER LAYERNIT-UPIMCSAT LOWER LAYERNIT-UPIMCSAT GROUNDWATER LAYERMON-NITUPNI SURFACE LAYERMON-NITUPNI UPPER LAYERMON-NITUPNI LOWER LAYERMON-NITUPNI GROUNDWATER LAYERMON-NITUPAM SURFACE LAYERMON-NITUPAM UPPER LAYERMON-NITUPAM LOWER LAYERMON-NITUPAM GROUNDWATER LAYERMON-NITIMNI SURFACE LAYERMON-NITIMNI UPPER LAYERMON-NITIMNI LOWER LAYERMON-NITIMNI GROUNDWATER LAYERMON-NITIMAM SURFACE LAYERMON-NITIMAM UPPER LAYERMON-NITIMAM LOWER LAYERMON-NITIMAM GROUNDWATER LAYERMON-NUPT-FR2 SURFACE LAYERMON-NUPT-FR2 UPPER LAYERMON-NUPT-FR2 LOWER LAYERMON-NUPT-FR2 GROUNDWATER LAYERNIT-ORGPM SURFACE LAYERNIT-ORGPM UPPER LAYERNIT-ORGPM LOWER LAYERNIT-ORGPM GROUNDWATER LAYERMON-NPRETBG SURFACE LAYERMON-NPRETBG UPPER LAYERMON-NPRETBG LOWER LAYERMON-NPRETBG GROUNDWATER LAYERMON-NPRETFLI SURFACE LAYERMON-NPRETFLI UPPER LAYERMON-NITAGUTF SURFACE LAYERMON-NITAGUTF UPPER LAYERMON-NITAGUTF LOWER LAYERMON-NITAGUTF GROUNDWATER LAYERNIT-STOR1 SURFACE LAYERNIT-STOR1 UPPER LAYERNIT-STOR1 LOWER LAYERNIT-STOR1  GROUNDWATER LAYERMON-PHOSUPT SURFACE LAYERMON-PHOSUPT UPPER LAYERMON-PHOSUPT LOWER LAYERMON-PHOSUPT GROUNDWATER LAYERPHOS-FSTPM SURFACE LAYERPHOS-FSTPM UPPER LAYERPHOS-FSTPM LOWER LAYERPHOS-FSTPM GROUNDWATER LAYERPHOS-SVALPM SURFACE LAYERPHOS-SVALPM UPPER LAYERPHOS-SVALPM LOWER LAYERPHOS-SVALPM GROUNDWATER LAYERMON-PUPT-FR2 SURFACE LAYERMON-PUPT-FR2 UPPER LAYERMON-PUPT-FR2 LOWER LAYERMON-PUPT-FR2 GROUNDWATER LAYERPHOS-STOR1 SURFACE LAYERPHOS-STOR1 UPPER LAYERPHOS-STOR1 LOWER LAYERPHOS-STOR1 GROUNDWATER LAYER  0 11 12 27 40 16 57 19 78 18 98 19 117 11 130 17  Select PERLND section(s) to modify. @ GENERAL, ATEMP, SNOW @ PWATER @ SEDMNT, PSTEMP @ PWTGAS, PQUAL @ MSTLAY, PEST @ NITR 1 @ NITR 2 @ PHOS, TRACER @@ GENER Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit tables in the GENER, ATEMP, or SNOW sections. ` Y A@ PWATER q! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit tables in the PWATER section. a ! A@ SEDMNT |! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit tables in the SEDMNT or PSTEMP sections.a A  B@ PWTGAS {" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit tables in the PWTGAS or PQUAL sections. b = B@ MSTLAY z" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit tables in the MSTLAY or PEST sections. b 9 C@ NITR 1 # Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the first set of tables in the NITR section.c 9 C@ NITR 2 # Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the second set of tables in the NITR section. c 9D@ PHOS z$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit tables in the PHOS or TRACER sections. d 9   Select PERLND table(s) to modify. GENERAL ATEMP SNOW @ ACTIVITY @ ATEMP-DAT @ ICE-FLAG @ PRINT-INFO @ SNOW-FLAGS @ BINARY-INFO @BSNOW-PARM1 @ GEN-INFO @CSNOW-PARM2 @ MON-MELT-FAC @DSNOW-INIT1 @ESNOW-INIT2@@ ACTIVn Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND ACTIVITY table. ` )A@ PRINTp! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PRINT-INFO table.a 1 A@ BINARY q! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND BINARY-INFO table. a 5  B@ GEN-IN n" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND GEN-INFO table. b )B@ ATEMPo" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND ATEMP-DAT table. b - C@ ICE-FLAG n# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND ICE-FLAG table. c ) C@ SNOW-FLAGS p# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SNOW-FLAGS table.c 1D@B p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SNOW-PARM1 table.d 3 D@C p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SNOW-PARM2 table.d 3$E@ MON-MELT-FAC r% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-MELT-FAC table. e 9(E@D p% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SNOW-INIT1 table.e 3,F@E p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SNOW-INIT2 table.f 30o  Select PERLND table(s) to modify. PWATER-General PWATER-Irrigation@APWAT-PARM1 @ PWAT-STATE1 @JSOIL-DATA @OIRRIG-PARM1@BPWAT-PARM2 @HMON-INTERCEP @KSOIL-DATA2 @PIRRIG-PARM2@CPWAT-PARM3 @ MON-UZSN @LSOIL-DATA3 @QIRRIG-SOURCE@DPWAT-PARM4 @ MON-MANNING @ CROP-DATES @RIRRIG-TARGET@EPWAT-PARM5 @IMON-INTERFLW @MCROP-STAGES @SIRRIG-SCHED@FPWAT-PARM6 @ MON-IRC @NCROP-SEASPM @TMON-IRR-CRDP@GPWAT-PARM7 @ MON-LZETPARM @UMON-IRR-AWD @@A p Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWAT-PARM1 table.` 3A@B p! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWAT-PARM2 table.a 3A@C p! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWAT-PARM3 table.a 3 B@D p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWAT-PARM4 table.b 3B@E p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWAT-PARM5 table.b 3C@F p# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWAT-PARM6 table.c 3C@G p# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWAT-PARM7 table.c 3 D@ PWAT-S q$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWAT-STATE1 table. d 5 D@H r$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-INTERCEP table. d ;$ E@ MON-UZ n% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-UZSN table. e )(E@ MON-MANNING q% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-MANNING table. e 5,F@I r& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-INTERFLW table. f ;0 F@ MON-IR m& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-IRC table. f %4 G@ MON-LZ r' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-LZETPARM table. g 98G@J o' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SOIL-DATA table. g /<H@K p( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SOIL-DATA2 table.h 3@H@L p( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SOIL-DATA3 table.h 3D I@ CROP-D p) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND CROP-DATES table.i 1HI@M q) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND CROP-STAGES table. i 7LJ@N q* Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND CROP-SEASPM table. j 7PJ@O q* Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND IRRIG-PARM1 table. j 7TK@P q+ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND IRRIG-PARM2 table. k 7XK@Q r+ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND IRRIG-SOURCE table. k ;\L@R r, Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND IRRIG-TARGET table. l ;`L@S q, Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND IRRIG-SCHED table. l 7dM@T r- Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-IRR-CRDP table. m ;hM@U q- Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-IRR-AWD table. m 7lN  Select PERLND table(s) to modify. SEDMNT PSTEMP @ASED-PARM1 @EPSTEMP-PARM1 @KMON-LGTP1 @BSED-PARM2 @FPSTEMP-PARM2 @JMON-LGTP2 @CSED-PARM3 @ MON-ASLT @ PSTEMP-TEMPS @ MON-COVER @ MON-BSLT @ MON-NVSI @GMON-ULTP1 @ SED-STOR @HMON-ULTP2 @@A o Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SED-PARM1 table. ` /A@B o! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SED-PARM2 table. a /A@C o! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SED-PARM3 table. a /  B@ MON-COVERo" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-COVER table. b - B@ MON-NVSI n" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NVSI table. b ) C@ SED-STOR n# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND SED-STOR table. c )C@E r# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PSTEMP-PARM1 table. c ;D@F r$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PSTEMP-PARM2 table. d ;  D@ MON-ASLT n$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-ASLT table. d )$ E@ MON-BSLT n% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-BSLT table. e )(E@G o% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-ULTP1 table. e /,F@H o& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-UTLP2 table. f /0F@K o& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-LGTP1 table. f /4G@J o' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-LGTP2 table. g /8G@ PSTEMP-TEMPS r' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PSTEMP-TEMPS table. g 9<  Select PERLND table(s) to modify. PWTGAS PQUAL @APWT-PARM1 @FMON-GRNDCO2 @ NQUALS @ MON-ACCUM @BPWT-PARM2 @ PWT-TEMPS @ PQL-AD-FLAGS @ MON-SQOLIM @ LAT-FACTOR @ PWT-GASES @ QUAL-PROPS @KMON-IFLW-CONC @HMON-IFWDOX @ QUAL-INPUT @GMON-GRND-CONC @JMON-IFWCO2 @CMON-POTFW @EMON-GRNDDOX @DMON-POTFS @@A o Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWT-PARM1 table. ` /A@B o! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWT-PARM2 table. a / A@ LAT-FACTOR p! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND LAT-FACTOR table.a / B@H p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-IFWDOX table.b 3B@J p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-IFWCO2 table.b 3C@E q# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-GRNDDOX table. c 7C@F q# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-GRNDCO2 table. c 7 D@ PWT-TEMPSo$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWT-TEMPS table. d -  D@ PWT-GASESo$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PWT-GASES table. d -$ E@ NQUALS l% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NQUALS table.e !(E@ PQL-AD-FLAGS r% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PQL-AD-FLAGS table. e 9, F@ QUAL-PROPS p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND QUAL-PROPS table.f 10 F@ QUAL-INPUT p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND QUAL-INPUT table.f 14G@C o' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-POTFW table. g /8G@D o' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-POTFS table. g /< H@ MON-ACCUMo( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-ACCUM table. h -@ H@ MON-SQOLIM p( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-SQOLIM table.h 1DI@K s) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-IFLW-CONC table. i ?HI@G s) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-GRND-CONC table. i ?L  Select PERLND table(s) to modify. MSTLAY PEST @ VUZFG @DMST-SUBFLX @ PEST-FLAGS @ PEST-CMAX @ UZSN-LZSN @ PEST-AD-FLAGS @ PEST-SVALPM @ MST-PARM @ PEST-ID @ PEST-NONSVPM @ MST-TOPSTOR @ PEST-THETA @ PEST-DEGRAD @ MST-TOPFLX @ PEST-FIRSTPM @APEST-STOR1 @CMST-SUBSTOR @BPEST-STOR2 @@ VUZFGk Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND VUZFG table. `  A@ UZSN-LZSNo! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND UZSN-LZSN table. a - A@ MST-PARM n! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MST-PARM table. a ) B@ MST-TOPSTOR q" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MST-TOPSTOR table. b 5 B@ MST-TOPFLX p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MST-TOPFLX table.b 1C@C q# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MST-SUBSTOR table. c 7C@D p# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MST-SUBFLX table.c 3 D@ PEST-FLAGS p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-FLAGS table.d 1 D@ PEST-AD-FLAGSs$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-AD-FLAGS table. d =$ E@ PEST-ID m% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-ID table. e %( E@ PEST-THETA p% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-THETA table.e 1,F@ PEST-FIRSTPM r& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-FIRSTPM table. f 90 F@ PEST-CMAXo& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-CMAX table. f -4G@ PEST-SVALPM q' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-SVALPM table. g 58G@ PEST-NONSVPM r' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-NONSVPM table. g 9<H@ PEST-DEGRAD q( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-DEGRAD table. h 5@H@A p( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-STOR1 table.h 3DI@B p) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PEST-STOR2 table.i 3H  Select PERLND table(s) to modify. NITR - First Group @ NIT-FLAGS @ NIT-SVALPM @ NIT-AMVOLAT @ NIT-AD-FLAGS @CNIT-UPIMKMAX @ NIT-YIELD @ NIT-UPTAKE @DNIT-UPIMCSAT @JMON-NUPT-FR1 @PMON-NITUPT  @EMON-NITUPNI @KMON-NUPT-FR2 @ NIT-FSTGEN @FMON-NITUPAM @ NIT-ORGPM @ NIT-FSTPM @GMON-NITIMNI @ NIT-CMAX @HMON-NITIMAM @@ NIT-FLAGSo Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-FLAGS table. ` -A@ NIT-AD-FLAGS r! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-AD-FLAGS table. a 9 A@ NIT-UPTAKE p! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-UPTAKE table.a 1 B@P p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NITUPT table.b 3 B@ NIT-FSTGEN p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-FSTGEN table.b 1 C@ NIT-FSTPMo# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-FSTPM table. c - C@ NIT-CMAX n# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-CMAX table. c ) D@ NIT-SVALPM p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-SVALPM table.d 1 D@C r$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-UPIMKMAX table. d ;$E@D r% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-UPIMCSAT table. e ;(E@E q% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NITUPNI table. e ;,F@F q& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NITUPAM table. f ;0F@G q& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NITIMNI table. f 74G@H q' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NITIMAM table. g 78G@ NIT-AMVOLAT q' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-AMVOLAT table. g 5< H@ NIT-YIELDo( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-YIELD table. h -@H@J r( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NUPT-FR1 table. h ;DI@K r) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NUPT-FR2 table. i ;H I@ NIT-ORGPMo) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-ORGPM table. i -L  Select PERLND table(s) to modify. NITR - Second Group @ NIT-BGPLRET @RMON-NPRETFLI @ NIT-AGPLRET @ NIT-AGUTF @LMON-NPRETBG @SMON-NITAGUTF @MMON-NPRETAG @ANIT-STOR1 @NMON-NPRETLI @BNIT-STOR2 @QMON-NPRETFBG @@ NIT-BGPLRET q Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-BGPLRET table. ` 5A@ NIT-AGPLRET q! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-AGPLRET table. a 5A@L q! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NPRETBG table. a 7 B@M q" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NPRETAG table. b 7B@N q" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NPRETLI table. b 7C@Q r# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NPRETFBG table. c ;C@R r# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NPRETFLI table. c ; D@ NIT-AGUTFo$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-AGUTF table. d 5 D@S r$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-NITAGUTF table. d ;$E@A o% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-STOR1 table. e /(E@B o% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND NIT-STOR2 table. e /,  Select PERLND table(s) to modify. PHOS TRACER @ PHOS-FLAGS @ PHOS-SVALPM @ TRAC-AD-FLAGS @ PHOS-AD-FLAGS @ PHOS-YIELD @ TRAC-ID @ PHOS-UPTAKE @AMON-PUPT-FR1 @ TRAC-TOPSTOR @ MON-PHOSUPT @BMON-PUPT-FR2 @ TRAC-SUBSTOR @CPHOS-FSTGEN @EPHOS-STOR1 @DPHOS-FSTPM @FPHOS-STOR2 @ PHOS-CMAX @@ PHOS-FLAGS p Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-FLAGS table.` 1A@ PHOS-AD-FLAGSs! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-AD-FLAGS table. a =A@ PHOS-UPTAKE q! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-UPTAKE table. a 5 B@ MON-PHOSUPT q" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-PHOSUPT table. b 5B@C q" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-FSTGEN table. b 7C@D p# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-FSTPM table.c 3 C@ PHOS-CMAXo# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-CMAX table. c -D@ PHOS-SVALPM q$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-SVALPM table. d 5  D@ PHOS-YIELD p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-YIELD table.d 1$E@A r% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-PUPT-FR1 table. e ;(E@B r% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND MON-PUPT-FR2 table. e ;,F@E p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-STOR1 table.f 30F@F p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND PHOS-STOR2 table.f 34G@ TRAC-AD-FLAGSs' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND TRAC-AD-FLAGS table. g =8 G@ TRAC-ID m' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND TRAC-ID table. g %<H@ TRAC-TOPSTOR r( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND TRAC-TOPSTOR table. h 9@H@ TRAC-SUBSTOR r( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PERLND TRAC-SUBSTOR table. h 9D 240 1 0. 3.28 ATEMP-DAT ELDAT240 2 17.77 1.8 ATEMP-DAT AIRTMP241 2 0. 3.28 SNOW-PARM1 MELEV241 5 0. 0.0394 SNOW-PARM1 COVIND241 6 0. 0.0219 SNOW-PARM1 KMELT241 7 17.77 1.8 SNOW-PARM1 TBASE242 2 17.77 1.8 SNOW-PARM2  TSNOW242 6 0. 0.0394 SNOW-PARM2 MGMELT243 0 0. 0.0219 MON-MELT-FAC KMELTM244 1 0. 0.0394 SNOW-INIT1 Pack-snow244 2 0. 0.0394 SNOW-INIT1 Pack-ice244 3 0. 0.0394 SNOW-INIT1 Pack-water244 6 17.77 1.8 SNOW-INIT1 PAKTMP245 1 0. 0.0394 SNOW-INIT2 COVINX245 2 0. 0.0394 SNOW-INIT2 XLNMLT246 2 0. 0.0394 PWAT-PARM2 LZSN246 3 0. 0.0394 PWAT-PARM2 INFILT246 4 0. 3.28 PWAT-PARM2 LSUR246 6 0. 25.4 PWAT-PARM2 KVARY247 1 17.77 1.8 PWAT-PARM3 PETMAX247 2 17.77 1.8 PWAT-PARM3 PETMIN248 1 0. 0.0394 PWAT-PARM4 CEPSC248 2 0. 0.0394 PWAT-PARM4 UZSN249 1 0. 25.4 PWAT-PARM5 FZG117 2 0. 12.0 PWAT-PARM6 BELV117 3 0. 12.0 PWAT-PARM6 GWDATM250 1 0. 3.28 PWAT-PARM6 MELEV250 2 0. 39.4 PWAT-PARM6 BELV250 3 0. 39.4 PWAT-PARM6 GWDATM251 4 0. 0.0394 PWAT-PARM7 IFWSC251 5 0. 0.0394 PWAT-PARM7 DELTA252 0 0. 0.0394 PWAT-STATE1 (ALL)253 0 0. 0.0394 MON-INTERCEP CEPSCM254 0 0. 0.0394 MON-UZSN UZSNM256 0 0. 0.394 SOIL-DATA2 (ALL)257 0 0. 0.394 SOIL-DATA3 (ALL)258 5 0. 0.394 CROP-SEASPM SCRDPI258 6 0. 0.394 CROP-SEASPM SCRDPF133 1 0. 3630. IRRIG-PARM2 IRAFAC259 1 0. 254. IRRIG-PARM2 IRAFAC259 6 0. 0.394 IRRIG-PARM2 CRDEP259 8 0. 0.394 IRRIG-PARM2 CAPRIS260 7 0. 0.0394 IRRIG-SCHED IRRAT1260 14 0. 0.0394 IRRIG-SCHED IRRAT2261 0 0. 0.394 MON-IRR-CRDP CRDEPM140 6 0. .0005 SED-PARM2 NVSI262 6 0. .000446 SED-PARM2 NVSI143 0 0. .0005 MON-NVSI NVSI263 0 0. .000446 MON-NVSI NVSI264 0 0. .446 SED-STOR DETS146 1 -32. .555 PSTEMP-PARM2 ASLT146 6 0. .555 PSTEMP-PARM2 LGTP2147 0 -32. .555 MON-ASLT ASLTM152 0 0. .555 MON-LGTP2 LGTP2M153 0 -32. .555 PSTEMP-TEMPS (ALL)273 1 0. 3.28 PWT-PARM2 ELEV161 0 -32. .555 PWT-TEMPS (ALL)166 7 0. 3630. QUAL-INPUT IOQC166 8 0. 3630. QUAL-INPUT AOQC275 1 0. 0.4047 QUAL-INPUT SQO275 2 0. 0.907 QUAL-INPUT POTFW275 3 0. 0.907 QUAL-INPUT POTFS275 4 0. 0.4047 QUAL-INPUT ACQOP275 5 0. 0.4047 QUAL-INPUT SQOLIM275 6 0. 0.0394 QUAL-INPUT WSQOP275 7 0. 102833. QUAL-INPUT IOQC275 8 0. 102833. QUAL-INPUT AOQC276 0 0. 0.907 MON-POTFW POTFWM277 0 0. 0.907 MON-POTFS POTFSM278 0 0. 0.4047 MON-ACCUM ACQOPM279 0 0. 0.4047 MON-SQOLIM SQOLIM171 0 0. 3630. MON-IFLW-CON IOQC280 0 0. 102833. MON-IFLW-CON IOQC172 0 0. 3630. MON-GRND-CON AOQC281 0 0. 102833. MON-GRND-CON AOQC282 0 0. 0.0394 UZSN-LZSN (ALL)200 0 0. 1.0E-3 NIT-UPIMCSAT (ALL)  Active Sections *** x - x ATMP SNOW PWAT SED PST PWG PQAL MSTL PEST NITR PHOS TRAC *** ACTIVITY @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 .!Value of 1 indicates section ATEMP is active AIRTFG AAFIELD3 a(0 -!Value of 1 indicates section SNOW is active SNOWFG BFIELD4 b(0 /"Value of 1 indicates section PWATER is active PWATFG BFIELD5 b(0 /"Value of 1 indicates section SEDMNT is active SEDFG CFIELD6 c(0 /#Value of 1 indicates section PSTEMP is active PSTFG CFIELD7 c(0 /#Value of 1 indicates section PWTGAS is active PWGFG DFIELD8 d(0 .$Value of 1 indicates section PQUAL is active PQALFG DFIELD9 d(0 /$Value of 1 indicates section MSTLAY is active MSTLFG EFIELD10e(0 -%Value of 1 indicates section PEST is active PESTFG EFIELD11e(0 -%Value of 1 indicates section NITR is active NITRFG FFIELD12f(0 -&Value of 1 indicates section PHOS is active PHOSFG FFIELD13f(0 /&Value of 1 indicates section TRACER is active TRACFG Active sections of PERLND. (1X,12I10) AIRTFG SNOWFG PWATFG SEDFG PSTFG PWGFG PQALFG MSTLFG PESTFG NITRFG PHOSFG TRACFG Print-flags PIVL PYR x - x ATMP SNOW PWAT SED PST PWG PQAL MSTL PEST NITR PHOS TRAC PRINT-INFO @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 a(4 !!Printout level for section ATEMP AIRTPR AFIELD3 a(4 !Printout level for section SNOWSNOWPR BFIELD4 b(4 ""Printout level for section PWATER PWATPR BFIELD5 b(4 ""Printout level for section SEDMNT SEDPR CFIELD6 c(4 "#Printout level for section PSTEMP PSTPR CFIELD7 c(4 "#Printout level for section PWTGAS PWGPR DFIELD8 d(4 !$Printout level for section PQUAL PQALPR DFIELD9 d(4 "$Printout level for section MSTLAY MSTLPR EFIELD10e(4 %Printout level for section PESTPESTPR EFIELD11e(4 %Printout level for section NITRNITRPR FFIELD12f(4 &Printout level for section PHOSPHOSPR FFIELD13f(4 "&Printout level for section TRACER TRACPR GFIELD14g(1 "'A value need only be supplied for PIVL if one or moresections have a printout level of 2. For those sections,printout will occur every PIVL intervals (that is, everyPDELT=PIVL*DELT mins). PIVL must be chosen such that thereare an integer no. of PDELT periods in a day. PIVL GFIELD15g( 9 €'PYREND is the calendar month which will terminate the yearfor printout purposes. Thus, the annual summary can reflectthe situation over the past water year or the past calendaryear, etc. PYREND HSPF permits the user to vary the printout level (maximumfrequency) for the various active sections of an operation:2 means every PIVL intervals, 3 means every day, 4 meansevery month, 5 means every year, 6 means never. (1X,12I5,I10,I12) Printout level flags Print-ivl Print-yrendATEMP SNOW PWAT SED PSTMP PWTG RQAL MSTL PEST NITR PHOS TRAC PIVL PYREND Binary Output Flags PIVL PYR x - x ATMP SNOW PWAT SED PST PWG PQAL MSTL PEST NITR PHOS TRAC BINARY-INFO@@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 a(4 !Output level for section ATEMP AIRTPR AFIELD3 a(4 !Output level for section SNOW SNOWPR BFIELD4 b(4 "Output level for section PWATERPWATPR BFIELD5 b(4 "Output level for section SEDMNTSEDPR CFIELD6 c(4 #Output level for section PSTEMPPSTPR CFIELD7 c(4 #Output level for section PWTGASPWGPR DFIELD8 d(4 $Output level for section PQUAL PQALPR DFIELD9 d(4 $Output level for section MSTLAYMSTLPR EFIELD10e(4 %Output level for section PEST PESTPR EFIELD11e(4 %Output level for section NITR NITRPR FFIELD12f(4 &Output level for section PHOS PHOSPR FFIELD13f(4 &Output level for section TRACERTRACPR GFIELD14g(1 "'A value need only be supplied for PIVL if one or moresections have an output level of 2. For those sections,output will occur every PIVL intervals (that is, everyPDELT=PIVL*DELT mins). PIVL must be chosen such that thereare an integer no. of PDELT periods in a day. PIVL GFIELD15g( 9 'PYREND is the calendar month which will terminate the yearfor output purposes. Thus, the annual summary can reflectthe situation over the past water year or the past calendaryear, etc. PYREND HSPF permits the user to vary the output level (maximumfrequency) for the various active sections of an operation:2 means every PIVL intervals, 3 means every day, 4 meansevery month, 5 means every year, 6 means never. (1X,12I5,I10,I12) Binary Output level flags Print-ivl Print-yrendATEMP SNOW PWAT SED PSTMP PWTG RQAL MSTL PEST NITR PHOS TRAC PIVL PYREND Name Unit-systems Printer BinaryOut t-series Engl Metr Engl Metr x - x in out GEN-INFO @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 S!Any string of up to 20 characters may be supplied as theidentifier for a PLS. LSID aAFIELD3 a(1 v!IUNITS indicates the system of units for data in the inputtime series; 1 means English units, 2 means Metric units. IUNITS BFIELD4 b(1 w"OUNITS indicates the system of units for data in the outputtime series; 1 means English units, 2 means Metric units. OUNITS BFIELD5 b(c0 Ձ"PUNIT(1) indicates the destinations of printout in Englishunits. A value 0 means no printout is required in Englishunits. A non-zero value means printout is required inEnglish units and the value is the Fortran unit no. of thefile to which the printout is to be written. Note thatprintout for each Pervious Land Segment can be obtained ineither the English or Metric systems, or both (irrespectiveof the system used to supply the inputs). PUNIT1 CFIELD6 c(c0 #PUNIT(2) indicates the destinations of printout in Metricunits. A value of 0 means no printout is required in Metricunits. A non-zero value means printout is required inMetric units and the value is the Fortran unit no. of thefile to which the printout is to be written. Note thatprintout for each Pervious Land Segment can be obtained ineither the English or Metric systems, or both (irrespectiveof the system used to supply the inputs). PUNIT2 CFIELD7 c(c0 #BUNIT(1) is the destination of binary output in Englishunits. A value of 0 means no binary output is required inEnglish units. A non-zero value means binary output isrequired in English units and the value is the Fortran unitno. of the file to which the binary output is to be written.Note that binary output for each Pervious Land Segment canbe obtained in either the English or Metric systems, or both(irrespective of the system used to supply the inputs). BUNIT1 DFIELD8 d(c0 $BUNIT(2) is the destination of binary output in Metricunits. A value of 0 means no binary output is required inMetric units. A non-zero value means binary output isrequired in Metric units and the value is the Fortran unitno. of the file to which the binary output is to be written.Note that binary output for each Pervious Land Segment canbe obtained in either the English or Metric systems, or both(irrespective of the system used to supply the inputs). BUNIT2 /General information for pervious land segment. (1X,5A4,2I10,2I10,2I10)Perv Land-segment id Unit systems Print-file nos BinaryOutfileNos IUNITS OUNITS English Metric English Metric @ ELDAT AIRTEMP x - x (ft) (deg F) ATEMP-DAT @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPyy0. !ELDAT is the difference in elevation between thetemperature gage and the PLS; it is used to estimate thetemperature over the PLS by application of a lapse rate. Itis positive if the PLS is higher than the gage, and viceversa. ELDAT AFIELD3 aPp C60.F!AIRTMP is the air temperature over the PLS at the start ofthe RUN. AIRTMP Data for section ATEMP.: (1X,2(1PE10.3)) ELDAT AIRTEMP (ft) (deg F) @ ELDAT AIRTEMP x - x (m) (deg C) ATEMP-DAT @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPyy0. !ELDAT is the difference in elevation between thetemperature gage and the PLS; it is used to estimate thetemperature over the PLS by application of a lapse rate. Itis positive if the PLS is higher than the gage, and viceversa. ELDAT AFIELD3 aPHpB15.F!AIRTMP is the air temperature over the PLS at the start ofthe RUN. AIRTMP Data for section ATEMP.: (1X,2(1PE10.3)) ELDAT AIRTEMP (m) (deg C)  Ice- x - x flag ICE-FLAG @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 Y!A value of 0 means ice formation in snow pack will not besimulated; 1 means it will. ICEFG Flag to simulate ice formation. (1X,1I10) ICEFG  x - x SNOP VKM SNOW-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 !A value of 0 means that the atmospheric heat exchange portion ofsnowmelt will be based on the energy balance; 1 means it will bebased on a degree-day factor.SNOPFG AFIELD3 a(0 S!VKMFG:value of 1 means vary degree-day factor monthly;0 means use annual value. VKMFG Snow flags. (1X,2I10) SNOPFG VMKFG  LAT MELEV SHADE SNOWCF COVIND KMELT TBASE x - x degrees (ft) (in) (in/d.F) (F) SNOW-PARM1 @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aPB40.x!LAT is the latitude of the PLS. It is positive for thenorthern hemisphere, negative for the southern hemisphere.LATAFIELD3 aP`F0. )!MELEV is the mean elevation of the PLS. MELEV BFIELD4 bP?0. _"SHADE is the fraction of the PLS which is shaded from solarradiation by, for example, trees. SHADE BFIELD5 bP?B-999. À"SNOWCF is the factor by which recorded precipitation datawill be multiplied if the simulation indicates it issnowfall, to account for poor catch efficiency under snowconditions. SNOWCF CFIELD6 cP #<y-999. #COVIND is the maximum pack (water equivalent) at which theentire PLS will be covered with snow (see functionaldescription of SNOW section).COVIND CFIELD7 cPy0.06#KMELT is the degree-day snowmelt factor when SNOPFG=1 KMELT DFIELD8 dPpB32.T$TBASE is the base temperature for the degree-day snowmeltcalculation when SNOPFG=1TBASE First group of SNOW parameters. (1X,5(1PE10.3)) LAT MELEV SHADE SNOWCF COVIND KMELT TBASE degrees (ft) (in) (in/d.F) (F)  LAT MELEV SHADE SNOWCF COVIND KMELT TBASE x - x degrees (m) (mm) (mm/d.C) (C) SNOW-PARM1 @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aPB40.x!LAT is the latitude of the PLS. It is positive for thenorthern hemisphere, negative for the southern hemisphere.LATAFIELD3 aP@F0. )!MELEV is the mean elevation of the PLS. MELEV BFIELD4 bP?0. _"SHADE is the fraction of the PLS which is shaded from solarradiation by, for example, trees. SHADE BFIELD5 bP?B-999. À"SNOWCF is the factor by which recorded precipitation datawill be multiplied if the simulation indicates it issnowfall, to account for poor catch efficiency under snowconditions. SNOWCF CFIELD6 cP>y-999. #COVIND is the maximum pack (water equivalent) at which theentire PLS will be covered with snow (see functionaldescription of SNOW section).COVIND CFIELD7 cPy0.06#KMELT is the degree-day snowmelt factor when SNOPFG=1 KMELT DFIELD8 dPA0. T$TBASE is the base temperature for the degree-day snowmeltcalculation when SNOPFG=1TBASE First group of SNOW parameters. (1X,5(1PE10.3)) LAT MELEV SHADE SNOWCF COVIND KMELT TBASE degrees (m) (mm) (mm/d.C) (C)  RDCSN TSNOW SNOEVP CCFACT MWATER MGMELT x - x (deg F) (in/day) SNOW-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP #<?0.15 !RDCSN is the density of cold, new snow relative to water.This value applies to snow falling at air temps <= 0degF.At higher temperatures the density of snow is adjusted. RDCSN AFIELD3 aPA B32.!TSNOW is the air temperature below which precipitation willbe snow, under saturated conditions. Under non-saturatedconditions the temperature is adjusted slightly. TSNOW BFIELD4 bP?0.1i"SNOEVP is a parameter which adapts the snow evaporation(sublimation) equation to field conditions. SNOEVP BFIELD5 bP A1. x"CCFACT is a parameter which adapts the snowcondensation/convection melt equation to field conditions.CCFACT CFIELD6 cP?0.03 e#MWATER is the maximum water content of the snow pack, indepth water per depth water equivalent. MWATER CFIELD7 cP?0.01 #MGMELT is the maximum rate of snowmelt by ground heat, indepth of water equivalent per day. This is the value whichapplies when the pack temperature is at freezing point. MGMELT !Second group of SNOW parameters. (1X,6(1PE10.3)) RDCSN TSNOW SNOEVP CCFACT MWATER MGMELT (deg F) (in/day)  RDCSN TSNOW SNOEVP CCFACT MWATER MGMELT x - x (deg C) (mm/day) SNOW-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP #<?0.15 !RDCSN is the density of cold, new snow relative to water.This value applies to snow falling at air temps <= 0degF.At higher temperatures the density of snow is adjusted. RDCSN AFIELD3 aP@0. !TSNOW is the air temperature below which precipitation willbe snow, under saturated conditions. Under non-saturatedconditions the temperature is adjusted slightly. TSNOW BFIELD4 bP?0.1i"SNOEVP is a parameter which adapts the snow evaporation(sublimation) equation to field conditions. SNOEVP BFIELD5 bP A1. x"CCFACT is a parameter which adapts the snowcondensation/convection melt equation to field conditions.CCFACT CFIELD6 cP?0.03 e#MWATER is the maximum water content of the snow pack, indepth water per depth water equivalent. MWATER CFIELD7 cPA0.25 #MGMELT is the maximum rate of snowmelt by ground heat, indepth of water equivalent per day. This is the value whichapplies when the pack temperature is at freezing point. MGMELT !Second group of SNOW parameters. (1X,6(1PE10.3)) RDCSN TSNOW SNOEVP CCFACT MWATER MGMELT (deg C) (mm/day)  Degree-day snowmelt factor at start of each month (in/d.F) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-MELT-FAC @`KMELT @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. @!KMJAN is the degree-day snowmelt factor at the start of JanuaryKMJAN AFIELD3 a(y0. KMFEB BFIELD4 b(y0. KMMAR BFIELD5 b(y0. KMAPR CFIELD6 c(y0. KMMAY CFIELD7 c(y0. KMJUN DFIELD8 d(y0. KMJUL DFIELD9 d(y0. KMAUG EFIELD10e(y0. KMSEP EFIELD11e(y0. KMOCT FFIELD12f(y0. KMNOV FFIELD13f(y0. KMDEC Monthly values of degree-day snowmelt factor at start of each month.This table is only required if VKMFG in Table-type SNOW-FLAGS is 1. (1X,12(1PE10.3))Values of Degree-day snowmelt factor at start of each calendar month (in/d.F): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Degree-day snowmelt factor at start of each month (mm/d.C) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-MELT-FAC @`KMELT @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. @!KMJAN is the degree-day snowmelt factor at the start of JanuaryKMJAN AFIELD3 a(y0. KMFEB BFIELD4 b(y0. KMMAR BFIELD5 b(y0. KMAPR CFIELD6 c(y0. KMMAY CFIELD7 c(y0. KMJUN DFIELD8 d(y0. KMJUL DFIELD9 d(y0. KMAUG EFIELD10e(y0. KMSEP EFIELD11e(y0. KMOCT FFIELD12f(y0. KMNOV FFIELD13f(y0. KMDEC Monthly values of degree-day snowmelt factor at start of each month.This table is only required if VKMFG in Table-type SNOW-FLAGS is 1. (1X,12(1PE10.3))Values of Degree-day snowmelt factor at start of each calendar month (mm/d.C): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Pack-snow Pack-ice Pack-watr RDENPF DULL PAKTMP x - x (in) (in) (in) (deg F) SNOW-INIT1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. J!Pack-snow is the quantity of snow in the pack (waterequivalent). PKSNOW AFIELD3 aPy0. I!Pack-ice is the quantity of ice in the pack (waterequivalent) PKICE BFIELD4 bPy0. 8"Pack-watr is the quantity of liquid water in the pack.PKWATR BFIELD5 bP #<?0.2Z"RDENPF is the density of the frozen contents (snow+ice) ofthe pack, relative to water. RDENPF CFIELD6 cPHD400. X#DULL is an index to the dullness of the pack surface, fromwhich albedo is estimated.DULL CFIELD7 cPyB32.G#PAKTMP is the mean temperature of the frozen contents ofthe pack. PAKTMP 3First group of initial values for SNOW simulation. (1X,6(1PE10.3)) Pack-snow Pack-ice Pack-watr RDENPF DULL PAKTMP (in) (in) (in) (deg F)  Pack-snow Pack-ice Pack-watr RDENPF DULL PAKTMP x - x (mm) (mm) (mm) (deg C) SNOW-INIT1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. J!Pack-snow is the quantity of snow in the pack (waterequivalent). PKSNOW AFIELD3 aPy0. I!Pack-ice is the quantity of ice in the pack (waterequivalent) PKICE BFIELD4 bPy0. 8"Pack-watr is the quantity of liquid water in the pack.PKWATR BFIELD5 bP #<?0.2Z"RDENPF is the density of the frozen contents (snow+ice) ofthe pack, relative to water. RDENPF CFIELD6 cPHD400. X#DULL is an index to the dullness of the pack surface, fromwhich albedo is estimated.DULL CFIELD7 cPy0. G#PAKTMP is the mean temperature of the frozen contents ofthe pack. PAKTMP 3First group of initial values for SNOW simulation. (1X,6(1PE10.3)) Pack-snow Pack-ice Pack-watr RDENPF DULL PAKTMP (mm) (mm) (mm) (deg C) H COVINX XLNMLT SKYCLR x - x (in) (in) SNOW-INIT2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP #<y0.01 !COVINX is the current pack (water equivalent) required toobtain complete areal coverage of the PLS. If the pack isless than this amount, areal cover is prorated(PACKF/COVINX). COVINX AFIELD3 aPy0. À!XLNMLT is the current remaining possible increment to icestorage in the pack (see functional description). Thisvalue is only relevant if ice formation is being simulated(ICEFG= 1). XLNMLT BFIELD4 bP>?1. R"SKYCLR is the fraction of sky which is assumed to be clearat the present time. SKYCLR 4Second group of initial values for SNOW simulation.D (1X,3(1PE10.3)) COVINX XLNMLT SKYCLR (in) (in)H COVINX XLNMLT SKYCLR x - x (mm) (mm) SNOW-INIT2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP>y0.25 !COVINX is the current pack (water equivalent) required toobtain complete areal coverage of the PLS. If the pack isless than this amount, areal cover is prorated(PACKF/COVINX). COVINX AFIELD3 aPy0. À!XLNMLT is the current remaining possible increment to icestorage in the pack (see functional description). Thisvalue is only relevant if ice formation is being simulated(ICEFG= 1). XLNMLT BFIELD4 bP>?1. R"SKYCLR is the fraction of sky which is assumed to be clearat the present time. SKYCLR 4Second group of initial values for SNOW simulation.D (1X,3(1PE10.3)) COVINX XLNMLT SKYCLR (mm) (mm)o Flags x - x CSNO RTOP UZFG VCS VUZ VNN VIFW VIRC VLE IFFC HWT IRRG IFRD PWAT-PARM1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 !If CSNOFG is 1, section PWATER assumes that snowaccumulation and melt is being considered. It will,therefore, expect that the time series produced by sectionSNOW are available, either internally (produced in this RUN)or from external sources (produced in a previous RUN). IfCSNOFG is 0, no such time series are expected. See thefunctional description for further information. CSNOFG AFIELD3 a(0 !If RTOPFG is 1, routing of overland flow is done in exactlythe same way as in HSPX, ARM and NPS. A value of 0 resultsin a new algorithm being used. A value of 2 results in theuse of a simple power function method (and HWTFG must be 1).A value of 3 results in the use of a table in the FTABLEblock to determine surface outflow as a function of surfacestorage (HWTFG must be 1). RTOPFG BFIELD4 b(0 "If UZFG is 1, inflow to the upper zone is computed in thesame way as in HSPX, ARM and NPS. A value of zero resultsin the use of a new algorithm, which should be lesssensitive to changes in DELT. UZFG BFIELD5 b(0 `"VCSFG:value of 1 means vary interception storage capacitymonthly; 0 means use annual value.VCSFG CFIELD6 c(0 `#VUZFG:value of 1 means vary upper zone nominal storagemonthly; 0 means use annual value.VUZFG CFIELD7 c(0 k#VNNFG:value of 1 means vary Manning's n for the overlandflow plane monthly; 0 means use annual value. VNNFG DFIELD8 d(0 `$VIFWFG:value of 1 means vary interflow inflow parametermonthly; 0 means use annual value.VIFWFG DFIELD9 d(0 `$VIRCFG:value of 1 means vary interflow recession constantmonthly; 0 means use annual value.VIRCFG EFIELD10e(0 %VLEFG:value of 1 means vary lower zone E-T parametermonthly; value of 2 means constant E-T with optional IHM method;value of 3 means variable E-T with optional IHM method; 0 meansuse annual value.VLEFG EFIELD11e(1 5%Method for computing INFFAC, the effect of frozen ground on infiltration; 1means use original method based on amount of ice in the snow pack (as enhancedby the new parameters FZG and FZGL in table-type PWAT-PARM5); 2 means baseINFFAC on temperature of the lower soil layer (section PSTEMP must be active). IFFCFG FFIELD12f(0 &If HWTFG=1, then high water table conditions (wetland) are prevalent on theland segment, and different algorithms are used for some processes.HWTFG FFIELD13f(0 &Irrigation module flag; 0 means not used; 1 means demand is input timeseriesIRRDEM; 2 means demand is calculated based on allowable water depletion inthe crop root zone; 3 means demand is specified by schedule in table-typeIRRIG-SCHED. IRRGFG GFIELD14g(0 'Infiltration redistribution flag for use with IHM; 0 means not used; 3-7 isassigned as the exponent in infiltration equation. IFRDFG *First group of PWATER Parameters (flags). s (1X,13I8) CSNOFG RTOPFG UZFG VCSFG VUZFG VNNFG VIFWFG VIRCFG VLEFG IFFCFG HWTFG IRRGFG IFRDFG  FOREST LZSN INFILT LSUR SLSUR KVARY AGWRC x - x (in) (in/hr) (ft) (1/in) (1/day) PWAT-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aP?0. !FOREST is the fraction of the PLS which is covered byforest which will continue to transpire in winter. Inputonly if CSNOFG=1.FOREST AFIELD3 aP #<B-999. )!LZSN is the lower zone nominal storage. LZSN BFIELD4 bP8B-999. C"INFILT is an index to the infiltration capacity of thesoil. INFILT BFIELD5 bP?y-999. 8"LSUR is the length of the assumed overland flow plane.LSUR CFIELD6 cP75 A-999. 8#SLSUR is the slope of the assumed overland flow plane.SLSUR CFIELD7 cPy0. #KVARY is a parameter which affects the behavior ofgroundwater recession flow, enabling it to be nonexponential in its decay with time. KVARY DFIELD8 dPn:w?-999. $AGWRC is the basic groundwater recession rate if KVARY iszero and there is no inflow to groundwater (rate of flowtoday/rate yesterday). AGWRC #Second group of PWATER Parameters. (1X,7(1PE10.3)) FOREST LZSN INFILT LSUR SLSUR KVARY AGWRC (inches) (in/hr) (feet) (1/inches) (1/day)  FOREST LZSN INFILT LSUR SLSUR KVARY AGWRC x - x (mms) (mms/hr) (m) (1/mms) (1/day) PWAT-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aP?0. !FOREST is the fraction of the PLS which is covered byforest which will continue to transpire in winter. Inputonly if CSNOFG=1.FOREST AFIELD3 aP>@E-999. )!LZSN is the lower zone nominal storage. LZSN BFIELD4 bP #;@E-999. C"INFILT is an index to the infiltration capacity of thesoil. INFILT BFIELD5 bP>y-999. 8"LSUR is the length of the assumed overland flow plane.LSUR CFIELD6 cP75 A-999. 8#SLSUR is the slope of the assumed overland flow plane.SLSUR CFIELD7 cPy0. #KVARY is a parameter which affects the behavior ofgroundwater recession flow, enabling it to be nonexponential in its decay with time. KVARY DFIELD8 dPn:w?-999. $AGWRC is the basic groundwater recession rate if KVARY iszero and there is no inflow to groundwater (rate of flowtoday/rate yesterday). AGWRC #Second group of PWATER Parameters. (1X,7(1PE10.3)) FOREST LZSN INFILT LSUR SLSUR KVARY AGWRC (mms) (mms/hr) (meters) (1/mms) (1/day) l PETMAX PETMIN INFEXP INFILD DEEPFR BASETP AGWETP x - x (deg F) (deg F) PWAT-PARM3 @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aPyy40.!PETMAX is the air temperature below which E-T willarbitrarily be reduced below the value obtained from theinput time series. Input only if CSNOFG=1. PETMAX AFIELD3 aPyy35.!PETMIN is the temperature below which E-T will be zeroregardless of the value in the input time series. Inputonly if CSNOFG=1.PETMIN BFIELD4 bP A2. 6"INFEXP is the exponent in the infiltration equation. INFEXP BFIELD5 bP?@2. c"INFILD is the ratio between the maximum and meaninfiltration capacities over the PLS. INFILD CFIELD6 cP?0. #DEEPFR is the fraction of groundwater inflow which willenter deep (inactive) groundwater and, thus, be lost fromthe system as it is defined in HSPF. DEEPFR CFIELD7 cP?0. #BASETP is the fraction of remaining potential E-T which canbe satisfied from baseflow (groundwater outflow), if enoughis available.BASETP DFIELD8 dP?0. $AGWETP is the fraction of remaining potential E-T which canbe satisfied from active groundwater storage if enough isavailable. AGWETP "Third group of PWATER Parameters. l (1X,7(1PE10.3)) PETMAX PETMIN INFEXP INFILD DEEPFR BASETP AGWETP (degF) (degF)l PETMAX PETMIN INFEXP INFILD DEEPFR BASETP AGWETP x - x (deg C) (deg C) PWAT-PARM3 @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aPyy4.4!PETMAX is the air temperature below which E-T willarbitrarily be reduced below the value obtained from theinput time series. Input only if CSNOFG=1. PETMAX AFIELD3 aPyy1.7!PETMIN is the temperature below which E-T will be zeroregardless of the value in the input time series. Inputonly if CSNOFG=1.PETMIN BFIELD4 bP A2. 6"INFEXP is the exponent in the infiltration equation. INFEXP BFIELD5 bP?@2. c"INFILD is the ratio between the maximum and meaninfiltration capacities over the PLS. INFILD CFIELD6 cP?0. #DEEPFR is the fraction of groundwater inflow which willenter deep (inactive) groundwater and, thus, be lost fromthe system as it is defined in HSPF. DEEPFR CFIELD7 cP?0. #BASETP is the fraction of remaining potential E-T which canbe satisfied from baseflow (groundwater outflow), if enoughis available.BASETP DFIELD8 dP?0. $AGWETP is the fraction of remaining potential E-T which canbe satisfied from active groundwater storage if enough isavailable. AGWETP "Third group of PWATER Parameters. l (1X,7(1PE10.3)) PETMAX  PETMIN INFEXP INFILD DEEPFR BASETP AGWETP (degC) (degC) CEPSC UZSN NSUR INTFW IRC LZETP x - x (in) (in) (1/day) PWAT-PARM4 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP A0. -!CEPSC is the interception storage capacity. CEPSC AFIELD3 aP #< A-999. )!UZSN is the upper zone nominal storage. UZSN BFIELD4 bPn:?0.1:"NSUR is Manning's n for the assumed overland flow plane. NSUR BFIELD5 bPy-999. )"INTFW is the interflow inflow parameter INTFW CFIELD6 cP`B w?-999. #IRC is the interflow recession parameter. Under zeroinflow, this is the ratio of interflow outflow ratetoday/rate yesterday.IRCCFIELD7 cP?0. d#LZETP is the lower zone E-T parameter. It is an index tothe density of deep-rooted vegetation.LZETP #Fourth group of PWATER Parameters. (1X,6(1PE10.3)) CEPSC UZSN NSUR INTFW IRC LZETP (inches) (inches)(nManning) (1/day) CEPSC UZSN NSUR INTFW IRC LZETP x - x (mms) (mms) (1/day) PWAT-PARM4 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPzC0. -!CEPSC is the interception storage capacity. CEPSC AFIELD3 aP>zC-999. )!UZSN is the upper zone nominal storage. UZSN BFIELD4 bPn:?0.1:"NSUR is Manning's n for the assumed overland flow plane. NSUR BFIELD5 bPy-999. )"INTFW is the interflow inflow parameter INTFW CFIELD6 cP`B w?-999. #IRC is the interflow recession parameter. Under zeroinflow, this is the ratio of interflow outflow ratetoday/rate yesterday.IRCCFIELD7 cP?0. d#LZETP is the lower zone E-T parameter. It is an index tothe density of deep-rooted vegetation.LZETP #Fourth group of PWATER Parameters. (1X,6(1PE10.3)) CEPSC UZSN NSUR INTFW IRC LZETP (mms) (mms)(nManning) (1/day)* FZG FZGL x - x PWAT-PARM5 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP8y1.0!FZG is the parameter to adjust the effect of ice in the snow pack oninfiltration when IFFCFG is 1. It is not used if IFFCFG is 2.FZGAFIELD3 aP8?0.1ŀ!If IFFCFG is 1, FZGL is the lower limit of INFFAC as adjusted by ice in thesnow pack. If IFFCFG is 2, FZGL is the value of INFFAC to use when the lowerlayer temperature is at or below freezing. FZGL "Fifth group of PWATER Parameters. 0 (1X,2(1PE10.3)) FZG FZGL (/in)* FZG FZGL x - x PWAT-PARM5 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP8y0.0394 !FZG is the parameter to adjust the effect of ice in the snow pack oninfiltration when IFFCFG is 1. It is not used if IFFCFG is 2.FZGAFIELD3 aP8?0.1ŀ!If IFFCFG is 1, FZGL is the lower limit of INFFAC as adjusted by ice in thesnow pack. If IFFCFG is 2, FZGL is the value of INFFAC to use when the lowerlayer temperature is at or below freezing. FZGL "Fifth group of PWATER Parameters. 0 (1X,2(1PE10.3)) FZG FZGL (/mm)p MELEV BELV GWDATM PCW PGW UPGW x - x (ft) (ft) (ft) PWAT-PARM6 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP`F0. ! MELEV is the mean elevation of the ground surface of the PLS. If Section SNOW is active, this field is ignored, and the value from SNOW-PARM1 is used.MELEV AFIELD3 aPyy-999.0 ! BELV is the base elevation for AGWO. It corresponds to the bottom elevation of nearby channels; therefore, if the ground water elevation is above BELV, there is outflow to the channels. Ground water below BELV is considered inactive.BELV BFIELD4 bPyy-999.0 j" GWDATM is the datum for the groundwater elevation GWEL. Storage below this elevation is not simulated. GWDATM BFIELD5 bP # MELEV BELV GWDATM PCW PGW UPGW x - x (m) (m) (m) PWAT-PARM6 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP@F0. ! MELEV is the mean elevation of the ground surface of the PLS. If Section SNOW is active, this field is ignored, and the value from SNOW-PARM1 is used.MELEV AFIELD3 aPy-999.0 ! BELV is the base elevation for AGWO. It corresponds to the bottom elevation of nearby channels; therefore, if the ground water elevation is above BELV, there is outflow to the channels. Ground water below BELV is considered inactive.BELV BFIELD4 bPyy-999.0 j" GWDATM is the datum for the groundwater elevation GWEL. Storage below this elevation is not simulated. GWDATM BFIELD5 bP # STABNO SRRC SREXP IFWSC DELTA UELFAC LELFAC x - x (/hr) (in) (in) PWAT-PARM7 @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aPyD0.0! STABNO is the user's number for the F-Table in the FTABLES block which contains the outflow properties from the surface storage.STABNO AFIELD3 aP.w?-999.0 ! SRRC is the surface runoff recession constant, which is used to calculate surface runoff as a function of surface storage only. SRRC BFIELD4 bPy1.0'" SREXP is the surface runoff exponent. SREXP BFIELD5 bP #<A-999.0 }" IFWSC is the maximum interflow storage capacity if the groundwater elevation is higher than the Upper Influence Elevation. IFWSC CFIELD6 cP75L>0.001 5# DELTA is the groundwater elevation tolerance level. DELTA CFIELD7 cP?@4.0H# UELFAC is the multiplier on UZSN which gives the upper zone capacity.UELFAC DFIELD8 dP?@@2.5H$ LELFAC is the multiplier on LZSN which gives the lower zone capacity.LELFAC $Seventh group of PWATER Parameters. (1X,7(1PE10.3)) STABNO SRRC SREXP IFWSC DELTA UELFAC LELFAC (/hr) (in) (in)  STABNO SRRC SREXP IFWSC DELTA UELFAC LELFAC x - x (/hr) (mm) (mm) PWAT-PARM7 @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aPyD0.0! STABNO is the user's number for the F-Table in the FTABLES block which contains the outflow properties from the surface storage.STABNO AFIELD3 aP.w?-999.0 ! SRRC is the surface runoff recession constant, which is used to calculate surface runoff as a function of surface storage only. SRRC BFIELD4 bPy1.0'" SREXP is the surface runoff exponent. SREXP BFIELD5 bP>;D-999.0 }" IFWSC is the maximum interflow storage capacity if the groundwater elevation is higher than the Upper Influence Elevation. IFWSC CFIELD6 cP7@0.025 5# DELTA is the groundwater elevation tolerance level. DELTA CFIELD7 cP@@@4.0H# UELFAC is the multiplier on UZSN which gives the upper zone capacity.UELFAC DFIELD8 dP@@@2.5H$ LELFAC is the multiplier on LZSN which gives the lower zone capacity.LELFAC $Seventh group of PWATER Parameters. (1X,7(1PE10.3)) STABNO SRRC SREXP IFWSC DELTA UELFAC LELFAC (/hr) (mm) (mm) u PWATER state variables (in) x - x CEPS SURS UZS IFWS LZS AGWS GWVS PWAT-STATE1@@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aPB0. +!CEPS is the initial interception storage. CEPS AFIELD3 aPB0. 6!SURS is the initial surface (overland flow) storage. SURS BFIELD4 bPn:B0.001 ("UZS is the initial upper zone storage.UZSBFIELD5 bPB0. ("IFWS is the initial interflow storage.IFWS CFIELD6 cPn:B0.001 (#LZS is the initial lower zone storage.LZSCFIELD7 cPyB0. #AGWS is the initial active groundwater storage. If HTWFG is 1,then a negative value indicates a groundwater storage below thebase elevation BELV. AGWS DFIELD8 dPB0. c$GWVS is the index to groundwater slope; it is a measure ofantecedent active groundwater inflow. GWVS :This table is used to specify the initial water storages. w (1X,7(1PE10.3))Segment-wide storages (inches): CEPS SURS UZS IFWS LZS AGWS GWVS v PWATER state variables (mms) x - x CEPS SURS UZS IFWS LZS AGWS GWVS PWAT-STATE1@@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aP@E0. +!CEPS is the initial interception storage. CEPS AFIELD3 aP@E0. 6!SURS is the initial surface (overland flow) storage. SURS BFIELD4 bP<@E0.025 ("UZS is the initial upper zone storage.UZSBFIELD5 bP@E0. ("IFWS is the initial interflow storage.IFWS CFIELD6 cP<@E0.025 (#LZS is the initial lower zone storage.LZSCFIELD7 cP@E0. 1#AGWS is the initial active groundwater storage. AGWS DFIELD8 dP@E0. c$GWVS is the index to groundwater slope; it is a measure ofantecedent active groundwater inflow. GWVS :This table is used to specify the initial water storages. s (1X,7(1PE10.3))Segment-wide storages (mm): CEPS SURS UZS IFWS LZS AGWS GWVS  Interception storage capacity at start of each month (in) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-INTERCEP @`CEPSC @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a( A0. A!INTJAN is the interception storage capacity at the start of Janu INTJAN AFIELD3 a( A0. INTFEB BFIELD4 b( A0. INTMAR BFIELD5 b( A0. INTAPR CFIELD6 c( A0. INTMAY CFIELD7 c( A0. INTJUN DFIELD8 d( A0. INTJUL DFIELD9 d( A0. INTAUG EFIELD10e( A0. INTSEP EFIELD11e( A0. INTOCT FFIELD12f( A0. INTNOV FFIELD13f( A0. INTDEC Monthly values of interception storage capacity at start of eachThis table is only required if VCSFG in Table-type PWAT-PARM1 is (1X,12(1PE10.3))Values of Interception Storage at start of each calendar month (inches): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Interception storage capacity at start of each month (mm) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-INTERCEP @`CEPSC @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(zC0. A!INTJAN is the interception storage capacity at the start of Janu INTJAN AFIELD3 a(zC0. INTFEB BFIELD4 b(zC0. INTMAR BFIELD5 b(zC0. INTAPR CFIELD6 c(zC0. INTMAY CFIELD7 c(zC0. INTJUN DFIELD8 d(zC0. INTJUL DFIELD9 d(zC0. INTAUG EFIELD10e(zC0. INTSEP EFIELD11e(zC0. INTOCT FFIELD12f(zC0. INTNOV FFIELD13f(zC0. INTDEC Monthly values of interception storage capacity at start of eachThis table is only required if VCSFG in Table-type PWAT-PARM1 is (1X,12(1PE10.3))Values of Interception Storage at start of each calendar month (mm): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Upper zone storage at start of each month (inches) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-UZSN @`UZSN @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a( #< A-999. :!UZSJAN is the upper zone storage at the start of January. UZSJAN AFIELD3 a( #< A-999. UZSFEB BFIELD4 b( #< A-999. UZSMAR BFIELD5 b( #< A-999. UZSAPR CFIELD6 c( #< A-999. UZSMAY CFIELD7 c( #< A-999. UZSJUN DFIELD8 d( #< A-999. UZSJUL DFIELD9 d( #< A-999. UZSAUG EFIELD10e( #< A-999. UZSSEP EFIELD11e( #< A-999. UZSOCT FFIELD12f( #< A-999. UZSNOV FFIELD13f( #< A-999. UZSDEC Monthly values of upper zone nominal storage at start of each moThis table is only required if VUZFG in Table-type PWAT-PARM1 is (1X,12(1PE10.3))Values of Upper Zone Storage at start of each calendar month (inches): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Upper zone storage at start of each month (mm) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-UZSN @`UZSN @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(>zC-999. :!UZSJAN is the upper zone storage at the start of January. UZSJAN AFIELD3 a(>zC-999. UZSFEB BFIELD4 b(>zC-999. UZSMAR BFIELD5 b(>zC-999. UZSAPR CFIELD6 c(>zC-999. UZSMAY CFIELD7 c(>zC-999. UZSJUN DFIELD8 d(>zC-999. UZSJUL DFIELD9 d(>zC-999. UZSAUG EFIELD10e(>zC-999. UZSSEP EFIELD11e(>zC-999. UZSOCT FFIELD12f(>zC-999. UZSNOV FFIELD13f(>zC-999. UZSDEC Monthly values of upper zone nominal storage at start of each moThis table is only required if VUZFG in Table-type PWAT-PARM1 is (1X,12(1PE10.3))Values of Upper Zone Storage at start of each calendar month (mm): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC v Manning's n at start of each month x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-MANNING@`NSUR @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(n:?0.19!MANJAN is the Manning's n value at the start of January. MANJAN AFIELD3 a(n:?0.1MANFEB BFIELD4 b(n:?0.1MANMAR BFIELD5 b(n:?0.1MANAPR CFIELD6 c(n:?0.1MANMAY CFIELD7 c(n:?0.1MANJUN DFIELD8 d(n:?0.1MANJUL DFIELD9 d(n:?0.1MANAUG EFIELD10e(n:?0.1MANSEP EFIELD11e(n:?0.1MANOCT FFIELD12f(n:?0.1MANNOV FFIELD13f(n:?0.1MANDEC yMonthly values of Manning's n at start of each month.This table is only required if VNNFG in Table-type PWAT-PARM1 is 1 (1X,12(1PE10.3))Values of Manning's N at start of each calendar month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Interflow inflow parameter for start of each month x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-INTERFLW @`INTFW @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y-999. A!IFLJAN is the interflow inflow parameter at the start of January IFLJAN AFIELD3 a(y-999. IFLFEB BFIELD4 b(y-999. IFLMAR BFIELD5 b(y-999. IFLAPR CFIELD6 c(y-999. IFLMAY CFIELD7 c(y-999. IFLJUN DFIELD8 d(y-999. IFLJUL DFIELD9 d(y-999. IFLAUG EFIELD10e(y-999. IFLSEP EFIELD11e(y-999. IFLOCT FFIELD12f(y-999. IFLNOV FFIELD13f(y-999. IFLDEC Monthly values of interflow inflow parameter at start of each month.This table is only required if VIFWFG in Table-type PWAT-PARM1 is 1. (1X,12(1PE10.3))Values of interflow inflow parameter at start of each calendar month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Interflow recession constant at start of each month (/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  MON-IRC@`IRC@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(`B w?-999. D!IRCJAN is the interflow recession constant at the start of January.IRCJAN AFIELD3 a(`B w?-999. IRCFEB BFIELD4 b(`B w?-999. IRCMAR BFIELD5 b(`B w?-999. IRCAPR CFIELD6 c(`B w?-999. IRCMAY CFIELD7 c(`B w?-999. IRCJUN DFIELD8 d(`B w?-999. IRCJUL DFIELD9 d(`B w?-999. IRCAUG EFIELD10e(`B w?-999. IRCSEP EFIELD11e(`B w?-999. IRCOCT FFIELD12f(`B w?-999. IRCNOV FFIELD13f(`B w?-999. IRCDEC Monthly values of interflow recession constant at start of eachThis table is only required if VIRCFG in Table-type PWAT-PARM1 i (1X,12(1PE10.3))Values of Interflow Recession Const. at start of each calendar month (/day): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Lower zone evapotransp parm at start of each month x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-LZETPARM @`LZETP @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. @!LZEJAN is the lower zone E-T parameter at the start of January.LZEJAN AFIELD3 a(?0. LZEFEB BFIELD4 b(?0. LZEMAR BFIELD5 b(?0. LZEAPR CFIELD6 c(?0. LZEMAY CFIELD7 c(?0. LZEJUN DFIELD8 d(?0. LZEJUL DFIELD9 d(?0. LZEAUG EFIELD10e(?0. LZESEP EFIELD11e(?0. LZEOCT FFIELD12f(?0. LZENOV FFIELD13f(?0. LZEDEC Monthly values of lower zone E-T parameters at start of each mon.This table is only required if VLEFG in Table-type PWAT-PARM1 is 1 or 3. (1X,12(1PE10.3))Values of Lower Zone ET at start of each calendar month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  | Depths (in) | Bulk density (lb/ft3) | x - x|Surface Upper Lower Groundw|Surface Upper Lower Groundw| SOIL-DATA @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a@n:zD-999. q!Depth(1)-(4) are the depths (thicknesses) of the surface,upper, lower, and groundwater layers, respectively. DSURF AFIELD3 a@n:zD-999. DUPPER BFIELD4 b@n:zD-999. DLOWER BFIELD5 b@n:zD-999. DGRNDW CFIELD6 c@HBC103. z#Bulkden(1)-(4) are the bulk densities of the soil in thesurface, upper, lower, and groundwater layers, respectively. BDSURF CFIELD7 c@HBC103. BDUPPR DFIELD8 d@HBC103. BDLOWR DFIELD9 d@HBC103. BDGRDW 2Soil layer depths and bulk densities (SOIL-DATA). (1X,8(1PE10.3)) Soil depth (in) Bulk density (lb/ft3) Surface Upper Lower Grnd-wat Surface Upper Lower Grnd-wat | Depths (cm) | Bulk density (g/cc) | x - x|Surface Upper Lower Groundw|Surface Upper Lower Groundw| SOIL-DATA @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a@ #;@E-999. q!Depth(1)-(4) are the depths (thicknesses) of the surface,upper, lower, and groundwater layers, respectively. DSURF AFIELD3 a@ #;@E-999. DUPPER BFIELD4 b@ #;@E-999. DLOWER BFIELD5 b@ #;@E-999. DGRNDW CFIELD6 c@L?@1.65 z#Bulkden(1)-(4) are the bulk densities of the soil in thesurface, upper, lower, and groundwater layers, respectively. BDSURF CFIELD7 c@L?@1.65 BDUPPR DFIELD8 d@L?@1.65 BDLOWR DFIELD9 d@L?@1.65 BDGRDW 2Soil layer depths and bulk densities (SOIL-DATA). (1X,8(1PE10.3)) Soil depth (cm) Bulk density (g/cc) Surface Upper Lower Grnd-wat Surface Upper Lower Grnd-wat Wilting point for each soil layer SWILTP UWILTP LWILTP AWILTP x - x (in/in) (in/in) (in/in) (in/in) SOIL-DATA2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0.08!SWILTP is the wilting point for the surface soil layer.SWILTP AAFIELD3 aP?0.06!UWILTP is the wilting point for the upper soil layer. UWILTP ABFIELD4 bP?0.06"LWILTP is the wilting point for the lower soil layer. LWILTP BBFIELD5 bP?0.0>"AWILTP is the wilting point for the active groundwater layer. AWILTP B3The wilting point is the minimum moisture fraction (by volume)for plant uptake to occur from a soil layer when using yield-baseduptake (NUPTFG=1 in Table-type NIT-FLAGS and/or PUPTFG=1 in Table-typePHOS-PLAGS). It is also used to determine available water capacity ifIRRGFG=2 in Table-type PWAT-PARM1. (1X,4(1PE10.3)) Wilting point for each soil layer SWILTP UWILTP LWILTP AWILTP (in/in) (in/in) (in/in) (in/in)  Wilting point for each soil layer SWILTP UWILTP  LWILTP AWILTP x - x (cm/cm) (cm/cm) (cm/cm) (cm/cm) SOIL-DATA2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0.08!SWILTP is the wilting point for the surface soil layer.SWILTP AAFIELD3 aP?0.06!UWILTP is the wilting point for the upper soil layer. UWILTP ABFIELD4 bP?0.06"LWILTP is the wilting point for the lower soil layer. LWILTP BBFIELD5 bP?0.0>"AWILTP is the wilting point for the active groundwater layer. AWILTP B2The wilting point is the minimum moisture fraction (by volume)for plant uptake to occur from a soil layer when using yield-baseduptake (NUPTFG=1 in Table-type NIT-FLAGS and/or PUPTFG=1 in Table-typePHOS-PLAGS). It is also used to determine available water capacity ifIRRGFG=2 in Table-type PWAT-PARM1. (1X,4(1PE10.3)) Wilting point for each soil layer SWILTP UWILTP LWILTP AWILTP (cm/cm) (cm/cm) (cm/cm) (cm/cm)  Field capacity for each soil layer SFDCAP UFDCAP LFDCAP AFDCAP x - x (in/in) (in/in) (in/in) (in/in) SOIL-DATA3 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0.09!SFDCAP is the field capacity for the surface soil layer. SFDCAP AAFIELD3 aP?0.07!UFDCAP is the field capacity for the upper soil layer. UFDCAP ABFIELD4 bP?0.07"LFDCAP is the field capacity for the lower soil layer. LFDCAP BBFIELD5 bP?0.0?"AFDCAP is the field capacity for the active groundwater layer. AFDCAP BThe field capacity is the maximum moisture fraction (by volume)that can be stored in a soil layer without gravity drainage.It is used to determine available water capacity if IRRGFG=2 inTable-type PWAT-PARM1. (1X,4(1PE10.3)) Field capacity for each soil layer SFDCAP UFDCAP LFDCAP AFDCAP (in/in) (in/in) (in/in) (in/in)  Field capacity for each soil layer SFDCAP UFDCAP LFDCAP AFDCAP x - x (cm/cm) (cm/cm) (cm/cm) (cm/cm) SOIL-DATA3 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0.09!SFDCAP is the field capacity for the surface soil layer. SFDCAP AAFIELD3 aP?0.07!UFDCAP is the field capacity for the upper soil layer. UFDCAP ABFIELD4 bP?0.07"LFDCAP is the field capacity for the lower soil layer. LFDCAP BBFIELD5 bP?0.0?"AFDCAP is the field capacity for the active groundwater layer. AFDCAP BThe field capacity is the maximum moisture fraction (by volume)that can be stored in a soil layer without gravity drainage.It is used to determine available water capacity if IRRGFG=2 inTable-type PWAT-PARM1. (1X,4(1PE10.3)) Field capacity for each soil layer SFDCAP UFDCAP LFDCAP AFDCAP (cm/cm) (cm/cm) (cm/cm) (cm/cm)  Crop planting and harvesting dates PLANT1 HARV1 PLANT2 HARV2 PLANT3 HARV3 x - x NCRP M D M D M D M D M D M D CROP-DATES @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(1 b!NCRP is the number of crops per year for which planting andharvesting dates are being specified. NCRP AFIELD3 a 1 3!PMON1 is the month of planting for the first crop. PMON1 BFIELD4 b1 1"PDAY1 is the day of planting for the first crop. PDAY1 BFIELD5 b 12 5"HMON1 is the month of harvesting for the first crop. HMON1 CFIELD6 c31 3#HDAY1 is the day of harvesting for the first crop. HDAY1 CFIELD7 c 1 4#PMON2 is the month of planting for the second crop.PMON2 DFIELD8 d1 2$PDAY2 is the day of planting for the second crop. PDAY2 DFIELD9 d 12 6$HMON2 is the month of harvesting for the second crop. HMON2 EFIELD10e31 4%HDAY2 is the day of harvesting for the second crop.HDAY2 EFIELD11e 1 3%PMON3 is the month of planting for the third crop. PMON3 FFIELD12f1 1&PDAY3 is the day of planting for the third crop. PDAY3 FFIELD13f 12 5&HMON3 is the month of harvesting for the third crop. HMON3 GFIELD14g31 3'HDAY3 is the day of harvesting for the third crop. HDAY3 0These crop dates are used to determine daily plant uptake targetsfrom monthly fractions when the yield-based algorithm is being used(NUPTFG=1 in Table-type NIT-FLAGS and/or PUPTFG=1 in Table-typePHOS-PLAGS). They are also used to specify crop irrigation seasons ifIRRGFG=2 in Table-type PWAT-PARM1. (1X,I5,3(4X,2I3,2X,2I3)) Crop planting and harvesting dates PLANT1 HARV1 PLANT2 HARV2 PLANT3 HARV3 NCRP M D M D M D M D M D M D f Fractions of crop season for each stage x - x CRPST1 CRPST2 CRPST3 CRPST4 CROP-STAGES@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0.0^!CRPST1 is the fraction of the crop season duration for the firststage of the growing season. CRPST1 AAFIELD3 aP?0.0_!CRPST2 is the fraction of the crop season duration for the secondstage of the growing season. CRPST2 ABFIELD4 bP?0.0^"CRPST3 is the fraction of the crop season duration for the thirdstage of the growing season. CRPST3 BBFIELD5 bP?0.0_"CRPST4 is the fraction of the crop season duration for the fourthstage of the growing season. CRPST4 B3Each crop season specified in Table-type CROP-DATES is divided intofour stages for the purpose of determining irrigation demand whenIRRGFG=2 in Table-type PWAT-PARM2, and VAWDFG=2 and/or VCRDFG=2 inTable-type IRRIG-PARM1. These fractions, rounded to the nearest day,specify the duration of each stage. b (1X,4(1PE10.3)) Fractions of crop season for each stage CRPST1 CRPST2 CRPST3 CRPST4  CRAWD1 CRAWD2 CRAWD3 CRAWD4 CRRDPI CRRDPF x - x (in) (in) CROP-SEASPM@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0. S!CRAWD1 is the allowable water depletion during the first stage ofthe crop season. CRAWD1 AFIELD3 aP?0. T!CRAWD2 is the allowable water depletion during the second stage ofthe crop season.CRAWD2 BFIELD4 bP?0. S"CRAWD3 is the allowable water depletion during the third stage ofthe crop season. CRAWD3 BFIELD5 bP?0. T"CRAWD4 is the allowable water depletion during the fourth stage ofthe crop season.CRAWD4 CFIELD6 cPy0. I#CRRDPI is the crop root depth during the first stage of the cropseason. CRRDPI CFIELD7 cPy0. U#CRRDPF is the crop root depth during the third and fourth stages ofthe crop season. CRRDPF IEach crop season specified in Table-type CROP-DATES is divided intofour stages for the purpose of determining irrigation demand whenIRRGFG=2 in Table-type PWAT-PARM2, and VAWDFG=2 and/or VCRDFG=2 inTable-type IRRIG-PARM1. These values are specified for the twoparameters AWD and CRDEP as they change during the crop season. (1X,6(1PE10.3)) Parameters for crop seasonal stages Allowable water depletion Crop root depth CRAWD1 CRAWD2 CRAWD3 CRAWD4 CRRDPI CRRDPF (inches) (inches)  CRAWD1 CRAWD2 CRAWD3 CRAWD4 CRRDPI CRRDPF x - x (cm) (cm) CROP-SEASPM@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0. S!CRAWD1 is the allowable water depletion during the first stage ofthe crop season. CRAWD1 AFIELD3 aP?0. T!CRAWD2 is the allowable water depletion during the second stage ofthe crop season.CRAWD2 BFIELD4 bP?0. S"CRAWD3 is the allowable water depletion during the third stage ofthe crop season. CRAWD3 BFIELD5 bP?0. T"CRAWD4 is the allowable water depletion during the fourth stage ofthe crop season.CRAWD4 CFIELD6 cPy0. I#CRRDPI is the crop root depth during the first stage of the cropseason. CRRDPI CFIELD7 cPy0. U#CRRDPF is the crop root depth during the third and fourth stages ofthe crop season. CRRDPF IEach crop season specified in Table-type CROP-DATES is divided intofour stages for the purpose of determining irrigation demand whenIRRGFG=2 in Table-type PWAT-PARM2, and VAWDFG=2 and/or VCRDFG=2 inTable-type IRRIG-PARM1. These values are specified for the twoparameters AWD and CRDEP as they change during the crop season. (1X,6(1PE10.3)) Parameters for crop seasonal stages Allowable water depletion Crop root depth CRAWD1 CRAWD2 CRAWD3 CRAWD4 CRRDPI CRRDPF  (cm) (cm) C Counters and Flags x - x NSKD SZON VCRD VAWD IROP IRRIG-PARM1@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 !NSKED is the number of scheduled irrigation applications to bedefined in Table-type IRRIG-SCHED. Used only when IRRGFG=3 inTable-type PWAT-PARM1. NSKED AFIELD3 a(0 -!If SZONFG=0, then the wilting point and field capacity are thesame for all soil layers, input in Table-type IRRIG-PARM2. IfSZONFG=1, then these two parameters vary by soil layer, and areinput in Table-types SOIL-DATA2 and SOIl-DATA3 respectively.Used only when IRRGFG=2 in Table-type PWAT-PARM1. SZONFG BFIELD4 b(0 R"If VCRDFG=0, then the crop root depth is constant, input inTable-type IRRIG-PARM2. If VCRDFG=1, then it varies monthly,and is input in Table-type MON-IRR-CRDP. If VCRDFG=2, thenit varies by four stages of the crop season, requiring inputin Table-types CROP-STAGES and CROP-SEASPM. Used only whenIRRGFG=2 in Table-type PWAT-PARM1. VCRDFG BFIELD5 b(0 \"If VAWDFG=0, then the allowable water depletion is constant,input in Table-type IRRIG-PARM2. If VAWDFG=1, then it variesmonthly, and is input in Table-type MON-IRR-CRDP. If VAWDFG=2,then it varies by four stages of the crop season, requiringinput in Table-types CROP-STAGES and CROP-SEASPM. Used onlywhen IRRGFG=2 in Table-type PWAT-PARM1.VAWDFG CFIELD6 c(0 D#If IROPFG=0, then irrigation applications may occur regardlessof groundwater elevation. If IROPFG=1 (representing subsurfaceirrigation), then irrigation may only occur if the groundwaterelevation GWEL is within CAPRIS inches of the bottom of the croproot zone (SELV- CRDEP). CAPRIS is input in Table-Type IRRIG-PARM2.IROPFG 5First group of PWATER Irrigation Parameters (flags). 3 (1X,4I10)  NSKED SZONFG VCRDFG VAWDFG  IRAREA IREFF ARZI WILTP FLDCAP CRDEP IRAWD CAPRIS x - x (acres) (in/in) (in/in) (in) (in) IRRIG-PARM2@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a@y0. !IRAREA is the total area of the irrigated PLS. It is used toconvert depth of application to volume of withdrawal from aRCHRES if such withdrawals occur, i.e. if RPRIOR is non-zeroin Table-type IRRIG-SOURCE. IRAREA AFIELD3 a@?1.0I!IREFF is the irrigation efficiency if IRRGFG=2 in Table-typePWAT-PARM1. IREFF BFIELD4 b@?1.0e"ARZI is the fraction of area receiving irrigation applications ifIRRGFG=2 in Table-type PWAT-PARM1. ARZI BFIELD5 b@?0. |"WILTP is the wilting point for all soil layers if IRRGFG=2 inTable-type PWAT-PARM1 and SZONFG=0 in Table-type IRRIG-PARM1.WILTP CFIELD6 c@?0. ~#FLDCAP is the field capacity for all soil layers if IRRGFG=2 inTable-type PWAT-PARM1 and SZONFG=0 in Table-type IRRIG-PARM1. FLDCAP CFIELD7 c@y0. j#CRDEP is the crop root depth if IRRGFG=2 in Table-type PWAT-PARM1and VCRDFG=0 in Table-type IRRIG-PARM1. CRDEP DFIELD8 d@?0.9t$IRAWD is the allowable water depletion if IRRGFG=2 in Table-type PWAT-PARM1and VCRDFG=0 in Table-type IRRIG-PARM1.IRAWD DFIELD9 d@y6. $CAPRIS is the maximum capillary rise for subirrigation if IRRGFG=2 inTable-type PWAT-PARM1 and IROPFG=1 in Table-type IRRIG-PARM1.CAPRIS .Second group of PWATER Irrigation Parameters. (1X,8(1PE10.3)) IRAREA IREFF ARZI WILTP FLDCAP CRDEP IRAWD CAPRIS (acres) (in/in) (in/in) (in) (in)  IRAREA IREFF ARZI WILTP FLDCAP CRDEP IRAWD CAPRIS x - x (ha) (cm/cm) (cm/cm) (cm) (cm) IRRIG-PARM2@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a@y0. !IRAREA is the total area of the irrigated PLS. It is used toconvert depth of application to volume of withdrawal from aRCHRES if such withdrawals occur, i.e. if RPRIOR is non-zeroin Table-type IRRIG-SOURCE. IRAREA AFIELD3 a@?1.0I!IREFF is the irrigation efficiency if IRRGFG=2 in Table-typePWAT-PARM1. IREFF BFIELD4 b@?1.0e"ARZI is the fraction of area receiving irrigation applications ifIRRGFG=2 in Table-type PWAT-PARM1. ARZI BFIELD5 b@?0. |"WILTP is the wilting point for all soil layers if IRRGFG=2 inTable-type PWAT-PARM1 and SZONFG=0 in Table-type IRRIG-PARM1.WILTP CFIELD6 c@?0. ~#FLDCAP is the field capacity for all soil layers if IRRGFG=2 inTable-type PWAT-PARM1 and SZONFG=0 in Table-type IRRIG-PARM1. FLDCAP CFIELD7 c@y0. j#CRDEP is the crop root depth if IRRGFG=2 in Table-type PWAT-PARM1and VCRDFG=0 in Table-type IRRIG-PARM1. CRDEP DFIELD8 d@?0.9t$IRAWD is the allowable water depletion if IRRGFG=2 in Table-type PWAT-PARM1and VCRDFG=0 in Table-type IRRIG-PARM1.IRAWD DFIELD9 d@y15.25 $CAPRIS is the maximum capillary rise for subirrigation if IRRGFG=2 inTable-type PWAT-PARM1 and IROPFG=1 in Table-type IRRIG-PARM1.CAPRIS .Second group of PWATER Irrigation Parameters. (1X,8(1PE10.3)) IRAREA IREFF ARZI WILTP FLDCAP CRDEP IRAWD CAPRIS (ha) (cm/cm) (cm/cm) (cm) (cm)  <-----External-----><---Groundwater----><-----------RCHRES-----------> x - x XPRIOR XFRAC GPRIOR GFRAC RPRIOR RFRAC IRCHNO IRRIG-SOURCE @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aP@@0. [!XPRIOR is the irrigation source priority for imports into thebasin from external sources. XPRIOR AFIELD3 aP?1.0Z!XFRAC is the irrigation source fraction for imports into thebasin from external sources. XFRAC BFIELD4 bP@@0. H"GPRIOR is the irrigation source priority for local shallowgroundwater.GPRIOR BFIELD5 bP?1.0G"GFRAC is the irrigation source fraction for local shallowgroundwater. GFRAC CFIELD6 cP@@0. 7#RPRIOR is the irrigation source priority for a RCHRES. RPRIOR CFIELD7 cP?1.06#RFRAC is the irrigation source fraction for a RCHRES. RFRAC DFIELD8 dPyD0. g$IRCHNO is the RCHRES ID number for the reach that willbe used as a source for irrigation withdrawals. IRCHNO ,Irrigation source priorities and fractions. (1X,6(1PE10.3),F10.0) Irrigation source priorities and fractions<-----External-----><---Groundwater----><-----------RCHRES-----------> XPRIOR XFRAC GPRIOR GFRAC RPRIOR RFRAC IRCHNO u Irrigation Application Target Fractions x - x Intercep Surface Upper Lower Active GW IRRIG-TARGET @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0. h!IRCPFR is the fraction of the irrigation application that issubject to interception by the crop cover.IRCPFR AFIELD3 aP?0. c!IRSUFR is the fraction of the irrigation application that isapplied directly to the soil surface. IRSUFR BFIELD4 bP?0. f"IRUPFR is the fraction of the irrigation application that isapplied directly to the upper soil zone. IRUPFR BFIELD5 bP?0. f"IRLOFR is the fraction of the irrigation application that isapplied directly to the lower soil zone. IRLOFR CFIELD6 cP?0. n#IRGWFR is the fraction of the irrigation application that isapplied directly to the active groundwater zone. IRGWFR Irrigation target fractions. (1X,5(1PE10.3)) Irrigation target fractions Intercep Surface Upper Lower Active GW IRCPFR IRSUFR IRUPFR IRLOFR IRGWFR  <---------Application----------> <---------Application----------> <-----date------> IRDU IRRATE <-----date------> IRDU IRRATE x - x yyyy mm dd hh mm min in/hr yyyy mm dd hh mm hr in/hr IRRIG-SCHED@@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 a y0. q!IRYR1 is the year for the first application on the current line. Ifzero, then the application occurs annually. IRYR1 AFIELD3 a?@A1. B!IRMO1 is the month for the first application on the current line. IRMO1 BFIELD4 b?A1. @"IRDY1 is the day for the first application on the current line.IRDY1 BFIELD5 bA0. A"IRHR1 is the hour for the first application on the current line. IRHR1 CFIELD6 cpB0. C#IRMI1 is the minute for the first application on the current line. IRMI1 CFIELD7 c(y0. E#IRDUR1 is the duration of the first application on the current line. IRDUR1 DFIELD8 dPy0. I$IRRAT1 is the hourly rate for the first application on the current line. IRRAT1 DFIELD9 d y0. r$IRYR2 is the year for the second application on the current line. Ifzero, then the application occurs annually. IRYR2 EFIELD10e?@A1. C%IRMO2 is the month for the second application on the current line. IRMO2 EFIELD11e?A1. A%IRDY2 is the day for the second application on the current line. IRDY2 FFIELD12fA0. B&IRHR2 is the hour for the second application on the current line. IRHR2 FFIELD13fpB0. D&IRMI2 is the minute for the second application on the current line.IRMI2 GFIELD14g(y0. F'IRDUR2 is the duration of the second application on the current line. IRDUR2 GFIELD15gPy0. J'IRRAT2 is the hourly rate for the second application on the current line. IRRAT2 ASchedule of applications when IRRGFG=3 in Table-type PWAT-PARM1. (1X,2(F5.0,4F3.0,F5.0,F10.0,5X))<---------Application----------> <---------Application----------><-----date------> IRDU IRRATE <-----date------> IRDU IRRATE yyyy mm dd hh mm min in/hr yyyy mm dd hh mm hr in/hr  <---------Application----------> <---------Application----------> <-----date------> IRDU IRRATE <-----date------> IRDU IRRATE x - x yyyy mm dd hh mm min mm/hr yyyy mm dd hh mm hr mm/hr IRRIG-SCHED@@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 a y0. q!IRYR1 is the year for the first application on the current line. Ifzero, then the application occurs annually. IRYR1 AFIELD3 a?@A1. B!IRMO1 is the month for the first application on the current line. IRMO1 BFIELD4 b?A1. @"IRDY1 is the day for the first application on the current line.IRDY1 BFIELD5 bA0. A"IRHR1 is the hour for the first application on the current line. IRHR1 CFIELD6 cpB0. C#IRMI1 is the minute for the first application on the current line. IRMI1 CFIELD7 c(y0. E#IRDUR1 is the duration of the first application on the current line. IRDUR1 DFIELD8 dPy0. I$IRRAT1 is the hourly rate for the first application on the current line. IRRAT1 DFIELD9 d y0. r$IRYR2 is the year for the second application on the current line. Ifzero, then the application occurs annually. IRYR2 EFIELD10e?@A1. C%IRMO2 is the month for the second application on the current line. IRMO2 EFIELD11e?A1. A%IRDY2 is the day for the second application on the current line. IRDY2 FFIELD12fA0. B&IRHR2 is the hour for the second application on the current line. IRHR2 FFIELD13fpB0. D&IRMI2 is the minute for the second application on the current line.IRMI2 GFIELD14g(y0. F'IRDUR2 is the duration of the second application on the current line. IRDUR2 GFIELD15gPy0. J'IRRAT2 is the hourly rate for the second application on the current line. IRRAT2 ASchedule of applications when IRRGFG=3 in Table-type PWAT-PARM1. (1X,2(F5.0,4F3.0,F5.0,F10.0,5X))<---------Application----------> <---------Application----------><-----date------> IRDU IRRATE <-----date------> IRDU IRRATE yyyy mm dd hh mm min mm/hr yyyy mm dd hh mm hr mm/hr ~ Crop root depth at start of each month (in) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-IRR-CRDP @`CRDEP @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. 7!CRDJAN is the crop root depth at the start of January. CRDJAN AFIELD3 a(y0. CRDFEB BFIELD4 b(y0. CRDMAR BFIELD5 b(y0. CRDAPR CFIELD6 c(y0. CRDMAY CFIELD7 c(y0. CRDJUN DFIELD8 d(y0. CRDJUL DFIELD9 d(y0. CRDAUG EFIELD10e(y0. CRDSEP EFIELD11e(y0. CRDOCT FFIELD12f(y0. CRDNOV FFIELD13f(y0. CRDDEC ~Monthly values of crop root depth at start of each month. Thistable is only required if VCRDFG=1 in Table-type IRRIG-PARM1. (1X,12(1PE10.3))Values of Crop Root Depth at start of each calendar month (in): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC ~ Crop root depth at start of each month (mm) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-IRR-CRDP @`CRDEP @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. 7!CRDJAN is the crop root depth at the start of January. CRDJAN AFIELD3 a(y0. CRDFEB BFIELD4 b(y0. CRDMAR BFIELD5 b(y0. CRDAPR CFIELD6 c(y0. CRDMAY CFIELD7 c(y0. CRDJUN DFIELD8 d(y0. CRDJUL DFIELD9 d(y0. CRDAUG EFIELD10e(y0. CRDSEP EFIELD11e(y0. CRDOCT FFIELD12f(y0. CRDNOV FFIELD13f(y0. CRDDEC ~Monthly values of crop root depth at start of each month. Thistable is only required if VCRDFG=1 in Table-type IRRIG-PARM1. (1X,12(1PE10.3))Values of Crop Root Depth at start of each calendar month (cm): JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Allowable Water Depletion at start of each month x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-IRR-AWD@`IRAWD @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. A!AWDJAN is the allowable water depletion at the start of January. AWDJAN AFIELD3 a(y0. AWDFEB BFIELD4 b(y0. AWDMAR BFIELD5 b(y0. AWDAPR CFIELD6 c(y0. AWDMAY CFIELD7 c(y0. AWDJUN DFIELD8 d(y0. AWDJUL DFIELD9 d(y0. AWDAUG EFIELD10e(y0. AWDSEP EFIELD11e(y0. AWDOCT FFIELD12f(y0. AWDNOV FFIELD13f(y0. AWDDEC Monthly values of allowable water depletion at start of each month.This table is only required if VAWDFG=1 in Table-type IRRIG-PARM1. (1X,12(1PE10.3))Values of Allowable Water Depletion at start of each calendar month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC < Sediment parameters 1 x - x CRV VSIV SDOP SED-PARM1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 8!If CRVFG is 1, erosion-related cover may vary monthly.CRVFG AFIELD3 a(0 K!If VSIVFG is 1, the rate of net vertical sediment input mayvary monthly. VSIVFG BFIELD4 b(0 "If SDOPFG is 1, removal of sediment from the land surfacewill be simulated with the algorithm used in the ARM and NPSmodels. If it is 0, a new algorithm will be used. SDOPFG /First group of sediment simulation parameters. ) (1X,3I10) CRVFG VSIVFG SDOPFG   SMPF KRER JRER AFFIX COVER NVSI x - x (/day) lb/ac-day SED-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPn:?1. !SMPF is a "supporting management practice factor." It isused to simulate the reduction in erosion achieved by use oferosion control practices. SMPF AFIELD3 aPy0. :!KRER is the coefficient in the soil detachment equation. KRER BFIELD4 bPyy-999. 7"JRER is the exponent in the soil detachment equation. JRER BFIELD5 bP?0. q"AFFIX is the fraction by which detached sediment storagedecreases each day, as a result of soil compaction. AFFIX CFIELD6 cP?0. #COVER is the fraction of land surface which is shieldedfrom erosion by rainfall (not considering snow cover, whichcan be handled by simulation). COVER CFIELD7 cPyy0. #NVSI is the rate at which sediment enters detached storagefrom the atmosphere. A negative value can be supplied(e.g., to simulate removal by human activity or wind). NVSI Second group of sediment simulation parameters.If monthly values for COVER and NVSI are being supplied, valuessupplied for these variables in this table are not relevant. (1X,6(1PE10.3)) SMPF KRER JRER AFFIX COVER NVSI (/day) (lb/ac.dy)  SMPF KRER JRER AFFIX COVER NVSI x - x (/day) kg/ha-day SED-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPn:?1. !SMPF is a "supporting management practice factor." It isused to simulate the reduction in erosion achieved by use oferosion control practices. SMPF AFIELD3 aPy0. :!KRER is the coefficient in the soil detachment equation. KRER BFIELD4 bPyy-999. 7"JRER is the exponent in the soil detachment equation. JRER BFIELD5 bP?0. q"AFFIX is the fraction by which detached sediment storagedecreases each day, as a result of soil compaction. AFFIX CFIELD6 cP?0. #COVER is the fraction of land surface which is shieldedfrom erosion by rainfall (not considering snow cover, whichcan be handled by simulation). COVER CFIELD7 cPyy0. #NVSI is the rate at which sediment enters detached storagefrom the atmosphere. A negative value can be supplied(e.g., to simulate removal by human activity or wind). NVSI Second group of sediment simulation parameters.If monthly values for COVER and NVSI are being supplied, valuessupplied for these variables in this table are not relevant. (1X,6(1PE10.3)) SMPF KRER JRER AFFIX COVER NVSI (/day) (kg/ha.dy) T Sediment parameter 3 x - x KSER JSER KGER JGER SED-PARM3 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. G!KSER is the coefficient in the detached sediment washoffequation. KSER AFIELD3 aPyy-999. G!JSER is the exponent in the detached sediment washoffequation. JSER BFIELD4 bPy0. ^"KGER is the coefficient in the matrix soil scour equation(simulates gully erosion, etc.). KGER BFIELD5 bPyy-999. ^"JGER is the exponent in the matrix soil scour equation(simulates gully erosion, etc.). JGER /Third group of sediment simulation parameters. c (1X,4(1PE10.3))Washoff and scour parameters for sediment KSER JSER KGER JGER | Monthly values for erosion related cover x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-COVER @`COVER @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. 6!COVJAN is the erosion related cover value in January. COVJAN AFIELD3 a(?0. COVFEB BFIELD4 b(?0. COVMAR BFIELD5 b(?0. COVAPR CFIELD6 c(?0. COVMAY CFIELD7 c(?0. COVJUN DFIELD8 d(?0. COVJUL DFIELD9 d(?0. COVAUG EFIELD10e(?0. COVSEP EFIELD11e(?0. COVOCT FFIELD12f(?0. COVNOV FFIELD13f(?0. COVDEC iMonthly erosion related cover values.This table is only required if CRVFG in Table-type SED-PARM1 is 1. (1X,12(1PE10.3))Values for start of each calendar month for COVERM JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly net vertical sediment input (lb/ac.day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NVSI @`NVSI @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy0. 6!NVSJAN is the net vertical sediment input in January. NVSJAN AFIELD3 a(yy0. NVSFEB BFIELD4 b(yy0. NVSMAR BFIELD5 b(yy0. NVSAPR CFIELD6 c(yy0. NVSMAY CFIELD7 c(yy0. NVSJUN DFIELD8 d(yy0. NVSJUL DFIELD9 d(yy0. NVSAUG EFIELD10e(yy0. NVSSEP EFIELD11e(yy0. NVSOCT FFIELD12f(yy0. NVSNOV FFIELD13f(yy0. NVSDEC iMonthly net vertical sediment input.This table is only required if VSIVFG in Table-type SED-PARM1 is 1. (1X,12(1PE10.3))Values for start of each calendar month for net vertical sediment input (lbs/ac.day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly net vertical sediment input (kg/ha.day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NVSI @`NVSI @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy0. 6!NVSJAN is the net vertical sediment input in January. NVSJAN AFIELD3 a(yy0. NVSFEB BFIELD4 b(yy0. NVSMAR BFIELD5 b(yy0. NVSAPR CFIELD6 c(yy0. NVSMAY CFIELD7 c(yy0. NVSJUN DFIELD8 d(yy0. NVSJUL DFIELD9 d(yy0. NVSAUG EFIELD10e(yy0. NVSSEP EFIELD11e(yy0. NVSOCT FFIELD12f(yy0. NVSNOV FFIELD13f(yy0. NVSDEC iMonthly net vertical sediment input.This table is only required if VSIVFG in Table-type SED-PARM1 is 1. (1X,12(1PE10.3))Values for start of each calendar month for net vertical sediment input (kg/ha.day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC G Detached sediment storage (tons/acre) x - x DETS SED-STOR @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. DETS 6DETS is the initial storage of detached sediment. A (1X,5(1PE10.3))Detached sediment storage (tons/acre) DETS F Detached sediment storage (tonne/ha) x - x DETS SED-STOR @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. DETS 6DETS is the initial storage of detached sediment. @ (1X,5(1PE10.3))Detached sediment storage (tonne/ha) DETSD Flags for section PSTEMP x - x SLTV ULTV LGTV TSOP PSTEMP-PARM1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 [!If SLTVFG is 1, parameters for estimating surface layertemperature can vary monthly. SLTVFG AFIELD3 a(0 [!If ULTVFG is 1, parameters for estimating upper layertemperature can vary monthly. ULTVFG BFIELD4 b(0 "If LGTVFG is 1, parameters for estimating lower layer andactive groundwater layer temperature calculations can varymonthly. LGTVFG BFIELD5 b(0 "TSOPFG governs the methods used to estimate subsurface soiltemperatures. If it is 0, they are computed using a meandeparture from air temperature, together with smoothingfactors. If TSOPFG is 1, upper layer soil temperature isestimated by regression on air temperature (like surfacetemperature). The lower layer/groundwater layer temperatureis supplied directly by the user (a different value may bespecified for each month). If it is 2, the same method isused as for a value of 0, except that the upper layer temp-erature is used instead of the air temperature to computethe lower layer/groundwater layer temperature. TSOPFG 1Temperature simulation flags for section PSTEMP. S (1X,4I10) Flags for section PSTEMP SLTVFG ULTVFG LGTVFG TSOPFG  ASLT BSLT ULTP1 ULTP2 LGTP1 LGTP2 x - x (deg F) (deg F) (deg F) (deg F) PSTEMP-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPB32.!ASLT is the surface layer temperature when the airtemperature is 32 degrees F (0 degrees C). It is theintercept of the surface layer temperature regressionequation. ASLT AFIELD3 aPn:@1. R!BSLT is the slope of the surface layer temperatureregression equation. BSLT BFIELD4 bPyy-999. "ULTP1 is the smoothing factor in upper layer temperaturecalculation, if TSOPFG = 0 or 2. ULTP1 is the interceptin the upper layer soil temperature regression equation(like ASLT and BSLT for the surface layer), if TSOPFG = 1. ULTP1 BFIELD5 bPyy-999. "ULTP2 is the mean difference between upper layer soiltemperature and air temperature, if TSOPFG = 0 or 2.ULTP2 is the slope in the upper layer soil temperatureregression equation (like ASLT and BSLT for the surfacelayer), if TSOPFG = 1. ULTP2 CFIELD6 cPyy-999. #LGTP1 is the smoothing factor for calculating lowerlayer/groundwater soil temperature, if TSOPFG = 0 or 2.LGTP1 is the lower layer/groundwater layer soil temperature,if TOSPFG = 1. LGTP1 CFIELD7 cPyy-999. #LGTP2 is the mean departure from air temperature forcalculating lower layer/groundwater soil temperature, ifTSOPFG = 0 or 2. LGTP2 is not used, if TSOPFG = 1. LGTP2 <Second group of PSTEMP (temperature estimating) parameters.b (1X,7(1PE10.3)) ASLT BSLT ULTP1 ULTP2 LGTP1 LGTP2 (deg F) (deg F/F)  ASLT BSLT ULTP1 ULTP2 LGTP1 LGTP2 x - x (deg C) (deg C) (deg C) (deg C) PSTEMP-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPB0. !ASLT is the surface layer temperature when the airtemperature is 32 degrees F (0 degrees C). It is theintercept of the surface layer temperature regressionequation. ASLT AFIELD3 aPn:@1. R!BSLT is the slope of the surface layer temperatureregression equation. BSLT BFIELD4 bPyy-999. "ULTP1 is the smoothing factor in upper layer temperaturecalculation, if TSOPFG = 0 or 2. ULTP1 is the interceptin the upper layer soil temperature regression equation(like ASLT and BSLT for the surface layer), if TSOPFG = 1. ULTP1 BFIELD5 bPyy-999. "ULTP2 is the mean difference between upper layer soiltemperature and air temperature, if TSOPFG = 0 or 2.ULTP2 is the slope in the upper layer soil temperatureregression equation (like ASLT and BSLT for the surfacelayer), if TSOPFG = 1. ULTP2 CFIELD6 cPyy-999. #LGTP1 is the smoothing factor for calculating lowerlayer/groundwater soil temperature, if TSOPFG = 0 or 2.LGTP1 is the lower layer/groundwater layer soil temperature,if TOSPFG = 1. LGTP1 CFIELD7 cPyy-999. #LGTP2 is the mean departure from air temperature forcalculating lower layer/groundwater soil temperature, ifTSOPFG = 0 or 2. LGTP2 is not used, if TSOPFG = 1. LGTP2 <Second group of PSTEMP (temperature estimating) parameters.b (1X,7(1PE10.3)) ASLT BSLT ULTP1 ULTP2 LGTP1 LGTP2 (deg C) (deg C/C)  Value of ASLT at start of each month (deg F) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ASLT @`ASLT @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(B32.J!SLTJAN is the value of surface layer temperature at the start of January. SLTJAN AFIELD3 a(B32.SLTFEB BFIELD4 b(B32.SLTMAR BFIELD5 b(B32.SLTAPR CFIELD6 c(B32.SLTMAY CFIELD7 c(B32.SLTJUN DFIELD8 d(B32.SLTJUL DFIELD9 d(B32.SLTAUG EFIELD10e(B32.SLTSEP EFIELD11e(B32.SLTOCT FFIELD12f(B32.SLTNOV FFIELD13f(B32.SLTDEC Monthly values of surface layer temperature at start of each month.This table is only required if SLTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of ASLT at start of each calendar month (deg F) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value of ASLT at start of each month (deg C) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ASLT @`ASLT @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(B0. J!SLTJAN is the value of surface layer temperature at the start of January. SLTJAN AFIELD3 a(B0. SLTFEB BFIELD4 b(B0. SLTMAR BFIELD5 b(B0. SLTAPR CFIELD6 c(B0. SLTMAY CFIELD7 c(B0. SLTJUN DFIELD8 d(B0. SLTJUL DFIELD9 d(B0. SLTAUG EFIELD10e(B0. SLTSEP EFIELD11e(B0. SLTOCT FFIELD12f(B0. SLTNOV FFIELD13f(B0. SLTDEC Monthly values of surface layer temperature at start of each month.This table is only required if SLTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of ASLT at start of each calendar month (deg C) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value of BSLT at start of each month (deg F/F) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-BSLT @`BSLT @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(n:@1. b!BSTJAN is the slope of the surface layer temperature regressionequation at the start of January. BSTJAN AFIELD3 a(n:@1. BSTFEB BFIELD4 b(n:@1. BSTMAR BFIELD5 b(n:@1. BSTAPR CFIELD6 c(n:@1. BSTMAY CFIELD7 c(n:@1. BSTJUN DFIELD8 d(n:@1. BSTJUL DFIELD9 d(n:@1. BSTAUG EFIELD10e(n:@1. BSTSEP EFIELD11e(n:@1. BSTOCT FFIELD12f(n:@1. BSTNOV FFIELD13f(n:@1. BSTDEC Monthly values of the slope of the surface layer temperature regressionequation at the start of each month.This table is only required if SLTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of BSLT at start of each calendar month (deg F/F) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of BSLT at start of each month (deg C/C) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-BSLT @`BSLT @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(n:@1. b!BSTJAN is the slope of the surface layer temperature regressionequation at the start of January. BSTJAN AFIELD3 a(n:@1. BSTFEB BFIELD4 b(n:@1. BSTMAR BFIELD5 b(n:@1. BSTAPR CFIELD6 c(n:@1. BSTMAY CFIELD7 c(n:@1. BSTJUN DFIELD8 d(n:@1. BSTJUL DFIELD9 d(n:@1. BSTAUG EFIELD10e(n:@1. BSTSEP EFIELD11e(n:@1. BSTOCT FFIELD12f(n:@1. BSTNOV FFIELD13f(n:@1. BSTDEC Monthly values of the slope of the surface layer temperature regressionequation at the start of each month.This table is only required if SLTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of BSLT at start of each calendar month (deg C/C) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of ULTP1 at start of each month in deg F (TSOPFG=1) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ULTP1 @`ULTP1 @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy-999. _!UT1JAN is the smoothing factor in upper layer temperature calculationat the start of January. UT1JAN AFIELD3 a(yy-999. UT1FEB BFIELD4 b(yy-999. UT1MAR BFIELD5 b(yy-999. UT1APR CFIELD6 c(yy-999. UT1MAY CFIELD7 c(yy-999. UT1JUN DFIELD8 d(yy-999. UT1JUL DFIELD9 d(yy-999. UT1AUG EFIELD10e(yy-999. UT1SEP EFIELD11e(yy-999. UT1OCT FFIELD12f(yy-999. UT1NOV FFIELD13f(yy-999. UT1DEC Monthly values of the smoothing factor in upper layer temperaturecalculation at the start of each month.This table is only required if ULTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of ULTP1 at start of each calendar month JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of ULTP1 at start of each month in deg C (TSOPFG=1) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ULTP1 @`ULTP1 @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy-999. _!UT1JAN is the smoothing factor in upper layer temperature calculationat the start of January. UT1JAN AFIELD3 a(yy-999. UT1FEB BFIELD4 b(yy-999. UT1MAR BFIELD5 b(yy-999. UT1APR CFIELD6 c(yy-999. UT1MAY CFIELD7 c(yy-999. UT1JUN DFIELD8 d(yy-999. UT1JUL DFIELD9 d(yy-999. UT1AUG EFIELD10e(yy-999. UT1SEP EFIELD11e(yy-999. UT1OCT FFIELD12f(yy-999. UT1NOV FFIELD13f(yy-999. UT1DEC Monthly values of the smoothing factor in upper layer temperaturecalculation at the start of each month.This table is only required if ULTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of ULTP1 at start of each calendar month JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of ULTP2 at start of each month in Deg F/F (TSOPFG=1) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ULTP2 @`ULTP2 @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy-999. p!UT2JAN is the mean difference between upper layer soil temperatureand air temperature at the start of January.UT2JAN AFIELD3 a(yy-999. UT2FEB BFIELD4 b(yy-999. UT2MAR BFIELD5 b(yy-999. UT2APR CFIELD6 c(yy-999. UT2MAY CFIELD7 c(yy-999. UT2JUN DFIELD8 d(yy-999. UT2JUL DFIELD9 d(yy-999. UT2AUG EFIELD10e(yy-999. UT2SEP EFIELD11e(yy-999. UT2OCT FFIELD12f(yy-999. UT2NOV FFIELD13f(yy-999. UT2DEC Monthly values of the mean difference between upper layer soiltemperature and air temperature at the start of each month.This table is only required if ULTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of ULTP2 at start of each calendar month JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of ULTP2 at start of each month in Deg C/C (TSOPFG=1) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ULTP2 @`ULTP2 @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy-999. p!UT2JAN is the mean difference between upper layer soil temperatureand air temperature at the start of January.UT2JAN AFIELD3 a(yy-999. UT2FEB BFIELD4 b(yy-999. UT2MAR BFIELD5 b(yy-999. UT2APR CFIELD6 c(yy-999. UT2MAY CFIELD7 c(yy-999. UT2JUN DFIELD8 d(yy-999. UT2JUL DFIELD9 d(yy-999. UT2AUG EFIELD10e(yy-999. UT2SEP EFIELD11e(yy-999. UT2OCT FFIELD12f(yy-999. UT2NOV FFIELD13f(yy-999. UT2DEC Monthly values of the mean difference between upper layer soiltemperature and air temperature at the start of each month.This table is only required if ULTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of ULTP2 at start of each calendar month JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of LGTP1 at start of each month in Deg F (TSOPFG=1) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-LGTP1 @`LGTP1 @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy-999. p!LT1JAN is the smoothing factor in lower layer/groundwater soiltemperature calculation at the start of January.LT1JAN AFIELD3 a(yy-999. LT1FEB BFIELD4 b(yy-999. LT1MAR BFIELD5 b(yy-999. LT1APR CFIELD6 c(yy-999. LT1MAY CFIELD7 c(yy-999. LT1JUN DFIELD8 d(yy-999. LT1JUL DFIELD9 d(yy-999. LT1AUG EFIELD10e(yy-999. LT1SEP EFIELD11e(yy-999. LT1OCT FFIELD12f(yy-999. LT1NOV FFIELD13f(yy-999. LT1DEC Monthly values of the smoothing factor in lower layer/groundwatertemperature at the start of each month.This table is only required if LGTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of LGTP1 at start of each calendar month JAN FEB MAR APR MAY JUN JUL  AUG SEP OCT NOV DEC  Value of LGTP1 at start of each month in Deg C (TSOPFG=1) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-LGTP1 @`LGTP1 @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy-999. p!LT1JAN is the smoothing factor in lower layer/groundwater soiltemperature calculation at the start of January.LT1JAN AFIELD3 a(yy-999. LT1FEB BFIELD4 b(yy-999. LT1MAR BFIELD5 b(yy-999. LT1APR CFIELD6 c(yy-999. LT1MAY CFIELD7 c(yy-999. LT1JUN DFIELD8 d(yy-999. LT1JUL DFIELD9 d(yy-999. LT1AUG EFIELD10e(yy-999. LT1SEP EFIELD11e(yy-999. LT1OCT FFIELD12f(yy-999. LT1NOV FFIELD13f(yy-999. LT1DEC Monthly values of the smoothing factor in lower layer/groundwatertemperature at the start of each month.This table is only required if LGTVFG in Table-type PSTEMP-PARM1 is 1. (1X,12(1PE10.3))Value of LGTP1 at start of each calendar month JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of LGTP2 at start of each month (F deg) (TSOPFG=0) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-LGTP2 @`LGTP2 @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy-999. |!LT2JAN is the mean difference between lower layer/groundwater soiltemperature and air temperature at the start of January.LT2JAN AFIELD3 a(yy-999. LT2FEB BFIELD4 b(yy-999. LT2MAR BFIELD5 b(yy-999. LT2APR CFIELD6 c(yy-999. LT2MAY CFIELD7 c(yy-999. LT2JUN DFIELD8 d(yy-999. LT2JUL DFIELD9 d(yy-999. LT2AUG EFIELD10e(yy-999. LT2SEP EFIELD11e(yy-999. LT2OCT FFIELD12f(yy-999. LT2NOV FFIELD13f(yy-999. LT2DEC Monthly values of the mean difference between lower layer/groundsoil temperature and air temperature at the start of each month.This table is only required if LGTVFG in Table-type PSTEMP-PARM1 is 1and TSOPFG is 0. (1X,12(1PE10.3))Value of LGTP2 at start of each calendar month (deg F) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value of LGTP2 at start of each month (deg C) (TSOPFG=0) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-LGTP2 @`LGTP2 @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(yy-999. |!LT2JAN is the mean difference between lower layer/groundwater soiltemperature and air temperature at the start of January.LT2JAN AFIELD3 a(yy-999. LT2FEB BFIELD4 b(yy-999. LT2MAR BFIELD5 b(yy-999. LT2APR CFIELD6 c(yy-999. LT2MAY CFIELD7 c(yy-999. LT2JUN DFIELD8 d(yy-999. LT2JUL DFIELD9 d(yy-999. LT2AUG EFIELD10e(yy-999. LT2SEP EFIELD11e(yy-999. LT2OCT FFIELD12f(yy-999. LT2NOV FFIELD13f(yy-999. LT2DEC Monthly values of the mean difference between lower layer/groundsoil temperature and air temperature at the start of each month.This table is only required if LGTVFG in Table-type PSTEMP-PARM1 is 1and TSOPFG is 0. (1X,12(1PE10.3))Value of LGTP2 at start of each calendar month (deg C) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC \ Initial temperatures (deg F) x - x AIRTC SLTMP ULTMP LGTMP PSTEMP-TEMPS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPB60.'!AIRTC is the initial air temperature. AIRTC AFIELD3 aPB60.6!SLTMP is the initial surface layer soil temperature. SLTMP BFIELD4 bPB60.4"ULTMP is the initial upper layer soil temperature.ULTMP BFIELD5 bPB60.J"LGTMP is the initial lower layer/groundwater layer soiltemperature. LGTMP 'PSTEMP initial temperature parameters. y (1X,4(1PE10.3)) Initial temperatures AIRTC SLTMP ULTMP LGTMP (deg F) (deg F) (deg F) (deg F) \ Initial temperatures (deg C) x - x AIRTC SLTMP ULTMP LGTMP PSTEMP-TEMPS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPDB16.'!AIRTC is the initial air temperature. AIRTC AFIELD3 aPDB16.6!SLTMP is the initial surface layer soil temperature. SLTMP BFIELD4 bPDB16.4"ULTMP is the initial upper layer soil temperature.ULTMP BFIELD5 bPDB16.J"LGTMP is the initial lower layer/groundwater layer soiltemperature. LGTMP 'PSTEMP initial temperature parameters. y (1X,4(1PE10.3)) Initial temperatures AIRTC SLTMP ULTMP LGTMP (deg C) (deg C) (deg C) (deg C) D Flags for section PWTGAS x - x IDV ICV GDV GVC PWT-PARM1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 F!If IDVFG is 1, then interflow DO concentration may varymonthly. IDVFG AFIELD3 a(0 F!If ICVFG is 1, then interflow CO2 concentration may varymonthly. ICVFG BFIELD4 b(0 F"If GDVFG is 1, then groundwater DO concentration may varymonthly. GDVFG BFIELD5 b(0 F"If GCVFG is 1, then groundwater CO2 concentration may varymonthly. GCVFG Flags for section PWTGAS. These flags each indicate whether ornot a parameter is allowed to vary throughout the year and, thuswhether or not the corresponding table of monthly values will beprovided.S (1X,4I10) Flags for section PWTGAS IDVFG ICVFG GDVFG GVCFG  Second group of PWTGAS parms ELEV IDOXP ICO2P ADOXP ACO2P x - x (ft) (mg/l) (mg C/l) (mg/l) (mg C/l) PWT-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPz`F0. !ELEV is the elevation of the PLS above sea level (used toadjust saturation concentrations of dissolved gasses insurface outflow).ELEV AFIELD3 aPA0. F!IDOXP is the concentration of dissolved oxygen in interflowoutflow. IDOXP BFIELD4 bP?0. F"ICO2P is the concentration of dissolved CO2 in interflowoutflow. ICO2P BFIELD5 bPA0. R"ADOXP is the concentration of dissolved oxygen in activegroundwater outflow. ADOXP CFIELD6 cP?0. R#ACO2P is the concentration of dissolved CO2 in activegroundwater outflow. ACO2P cSecond group of PWTGAS parameters to estimate water temperatureconcentrations of dissolved gases. (1X,5(1PE10.3)) Second group of PWTGAS parms ELEV IDOXP ICO2P ADOXP ACO2P (ft) (mg/l) (mgC/l) (mg/l) (mgC/l)  Second group of PWTGAS parms ELEV IDOXP ICO2P ADOXP ACO2P x - x (m) (mg/l) (mg C/l) (mg/l) (mg C/l) PWT-PARM2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP0F0. !ELEV is the elevation of the PLS above sea level (used toadjust saturation concentrations of dissolved gasses insurface outflow).ELEV AFIELD3 aPA0. F!IDOXP is the concentration of dissolved oxygen in interflowoutflow. IDOXP BFIELD4 bP?0. F"ICO2P is the concentration of dissolved CO2 in interflowoutflow. ICO2P BFIELD5 bPA0. R"ADOXP is the concentration of dissolved oxygen in activegroundwater outflow. ADOXP CFIELD6 cP?0. R#ACO2P is the concentration of dissolved CO2 in activegroundwater outflow. ACO2P cSecond group of PWTGAS parameters to estimate water temperatureconcentrations of dissolved gases. (1X,5(1PE10.3)) Second group of PWTGAS parms ELEV IDOXP ICO2P ADOXP ACO2P (m) (mg/l) (mg C/l) (mg/l) (mg C/l) f Sediment Surface Interflow Active GW x - x SDLFAC SLIFAC ILIFAC ALIFAC LAT-FACTOR @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0.0! SDLFAC is the weighting factor which accounts for the influence of lateral inflow on the outflow concentration for sediment-associated constituents which do not maintain a mass balance (QUALSD) SDLFAC AFIELD3 aP?0.0! SLIFAC is the weighting factor which accounts for the influence of lateral inflow on the surface outflow concentration for constituents which do not maintain a mass balance (temp, DO, CO2)SLIFAC BFIELD4 bP?0.0" ILIFAC is the weighting factor which accounts for the influence of lateral inflow on the interflow outflow concentration for constituents which do not maintain a mass balance (temp, DO, CO2, QUALIF) ILIFAC BFIELD5 bP?0.0̀" ALIFAC is the weighting factor which accounts for the influence of lateral inflow on the groundwater outflow concentration for constituents which do not maintain a mass balance (temp, DO, CO2, QUALGW)ALIFAC 7 Lateral inflow weighting factors for PWGTAS and PQUAL p (1X,4(1PE10.3)) Lateral inflow weighting factors for PWGTAS and PQUAL SDLFAC SLIFAC ILIFAC ALIFAC Value at start of each month for interflow DO concentration (mg/l) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-IFWDOX @`IDOXP @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(A0. :!IDOJAN is the interflow DO conc. at the start of January. IDOJAN AFIELD3 a(A0. IDOFEB BFIELD4 b(A0. IDOMAR BFIELD5 b(A0. IDOAPR CFIELD6 c(A0. IDOMAY CFIELD7 c(A0. IDOJUN DFIELD8 d(A0. IDOJUL DFIELD9 d(A0. IDOAUG EFIELD10e(A0. IDOSEP EFIELD11e(A0. IDOOCT FFIELD12f(A0. IDONOV FFIELD13f(A0. IDODEC Monthly values of interflow DO concentration at start of each month.This table is only required if IDVFG in Table-type PWT-PARM1 is 1. (1X,12(1PE10.3))Values for IDOXP at start of each month (mg/l) JAN FEB MAR APR  MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of each month for interflow CO2 conc. (mg C/l) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-IFWCO2 @`ICO2P @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. ?!CO2JAN is the interflow CO2 conc. at the start of the January. CO2JAN AFIELD3 a(?0. CO2FEB BFIELD4 b(?0. CO2MAR BFIELD5 b(?0. CO2APR CFIELD6 c(?0. CO2MAY CFIELD7 c(?0. CO2JUN DFIELD8 d(?0. CO2JUL DFIELD9 d(?0. CO2AUG EFIELD10e(?0. CO2SEP EFIELD11e(?0. CO2OCT FFIELD12f(?0. CO2NOV FFIELD13f(?0. CO2DEC Monthly values of interflow CO2 concentration at start of each month.This table is only required if ICVFG in Table-type PWT-PARM1 is 1. (1X,12(1PE10.3))Values for ICO2P at start of each month (mgC/l) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of each month for groundwater DO concentration (mg/l) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-GRNDDOX@`ADOXP @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(A0. <!GDOJAN is the groundwater DO conc. at the start of January.GDOJAN AFIELD3 a(A0. GDOFEB BFIELD4 b(A0. GDOMAR BFIELD5 b(A0. GDOAPR CFIELD6 c(A0. GDOMAY CFIELD7 c(A0. GDOJUN DFIELD8 d(A0. GDOJUL DFIELD9 d(A0. GDOAUG EFIELD10e(A0. GDOSEP EFIELD11e(A0. GDOOCT FFIELD12f(A0. GDONOV FFIELD13f(A0. GDODEC Monthly values of groundwater DO concentration at start of each month.This table is only required if GDVFG in Table-type PWT-PARM1 is 1. (1X,12(1PE10.3))Values for ADOXP at start of each month (mg/l) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of each month for groundwater CO2 conc. (mg C/l) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-GRNDCO2@`ACO2P @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. =!GCOJAN is the groundwater CO2 conc. at the start of January. GCOJAN AFIELD3 a(?0. GCOFEB BFIELD4 b(?0. GCOMAR BFIELD5 b(?0. GCOAPR CFIELD6 c(?0. GCOMAY CFIELD7 c(?0. GCOJUN DFIELD8 d(?0. GCOJUL DFIELD9 d(?0. GCOAUG EFIELD10e(?0. GCOSEP EFIELD11e(?0. GCOOCT FFIELD12f(?0. GCONOV FFIELD13f(?0. GCODEC Monthly values of groundwater CO2 concentration at start of eachThis table is only required if GCVFG in Table-type PWT-PARM1 is 1. (1X,12(1PE10.3))Values for ACO2P at start of each month (mg/l) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Z Initial water temperatures (deg F) x - x SOTMP IOTMP AOTMP PWT-TEMPS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPBB60.3!SOTMP is the initial surface outflow temperature. SOTMP AFIELD3 aPBB60.5!IOTMP is the initial interflow outflow temperature. IOTMP BFIELD4 bPBB60.J"AOTMP is the initial active groundwater outflowtemperature. AOTMP 5Initial water temperature values for section PWTGAS. m (1X,3(1PE10.3)) Initial water temperatures SOTMP IOTMP AOTMP (deg F) (deg F) (deg F) Z Initial water temperatures (deg C) x - x SOTMP IOTMP AOTMP PWT-TEMPS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPB16.3!SOTMP is the initial surface outflow temperature. SOTMP AFIELD3 aPB16.5!IOTMP is the initial interflow outflow temperature. IOTMP BFIELD4 bPB16.J"AOTMP is the initial active groundwater outflowtemperature. AOTMP 5Initial water temperature values for section PWTGAS. m (1X,3(1PE10.3)) Initial water temperatures SOTMP IOTMP AOTMP (deg C) (deg C) (deg C)  Initial DO and CO2 concentrations SODOX SOCO2 IODOX IOCO2 AODOX AOCO2 x - x (mg/l) (mg C/l) (mg/l) (mg C/l) (mg/l) (mg C/l) PWT-GASES @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPA0. ;!SODOX is the initial DO concentration in surface outflow. SODOX AFIELD3 aP?0. x - xNQUAL  NQUALS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a( 1 3!NQUAL is the total number of quality constituents. NQUAL `The total number of quality constituents simulated in section PQUALis indicated in this table. (1X,1I10) NQUAL  Atmospheric Deposition Flags QUAL1 QUAL2 QUAL3 QUAL4 QUAL5 QUAL6 QUAL7 QUAL8 QUAL9 QUAL10 x - x PQL-AD-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 a0 (!Value of 0 indicates that atmospheric deposition flux of qualityconstituent #1 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(1) AAFIELD3 a0 +!Value of 0 indicates that concentration of quality constituent #1 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(2) ABFIELD4 b0 ("Value of 0 indicates that atmospheric deposition flux of qualityconstituent #2 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(3) BBFIELD5 b0 +"Value of 0 indicates that concentration of quality constituent #2 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(4) BCFIELD6 c0 (#Value of 0 indicates that atmospheric deposition flux of qualityconstituent #3 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(5) CCFIELD7 c0 +#Value of 0 indicates that concentration of quality constituent #3 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(6) CDFIELD8 d0 ($Value of 0 indicates that atmospheric deposition flux of qualityconstituent #4 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(7) DDFIELD9 d0 +$Value of 0 indicates that concentration of quality constituent #4 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(8) DEFIELD10e0 (%Value of 0 indicates that atmospheric deposition flux of qualityconstituent #5 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(9) EEFIELD11e0 +%Value of 0 indicates that concentration of quality constituent #5 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(10) EFFIELD12f0 (&Value of 0 indicates that atmospheric deposition flux of qualityconstituent #6 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(11) FFFIELD13f0 +&Value of 0 indicates that concentration of quality constituent #6 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(12) FGFIELD14g0 ('Value of 0 indicates that atmospheric deposition flux of qualityconstituent #7 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(13) GGFIELD15g0 +'Value of 0 indicates that concentration of quality constituent #7 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(14) GHFIELD16h0 ((Value of 0 indicates that atmospheric deposition flux of qualityconstituent #8 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(15) HHFIELD17h0 +(Value of 0 indicates that concentration of quality constituent #8 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(16) HIFIELD18i0 ()Value of 0 indicates that atmospheric deposition flux of qualityconstituent #9 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(17) IIFIELD19i0 +)Value of 0 indicates that concentration of quality constituent #9 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(18) IJFIELD20j0 )*Value of 0 indicates that atmospheric deposition flux of qualityconstituent #10 is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(19) JJFIELD21j0 ,*Value of 0 indicates that concentration of quality constituent #10 inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PQADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PQADFG(20) J2Quality constituent atmospheric deposition flags.  (1X,10(2X,2I4)) Atmospheric Deposition Flags QUAL1 QUAL2 QUAL3 QUAL4 QUAL5 QUAL6 QUAL7 QUAL8 QUAL9 QUAL10 FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON n Identifiers and Flags x - x QUALID QTID QSD VPFW VPFS QSO VQO QIFW VIQC QAGW VAQC QUAL-PROPS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 V!QUALID is a string of up to 10 characters which identifiesthe quality constituent. QUALID a `AFIELD3 !QTYID is a string of up to 4 characters which identifiesthe units associated with this constituent (e.g., kg, (forcoliforms)). These are the units refered to as "qty" insubsequent tables (eg. Table-type QUAL-INPUT).QTYID a BFIELD4 b(0 J"If QSDFG is 1, this constituent is a QUALSD (sedimentassociated). QSDFG BFIELD5 b(0 "If VPFWFG is 1, the washoff potency factor may varymonthly. If VPWFG is 2, the daily factors are not interpolatedbetween monthly values. VPFWFG CFIELD6 c(0 <#If VPFSFG is 1, the scour potency factor may vary monthly.VPFSFG CFIELD7 c(0 #If QSOFG is 1 or 2, this constituent is a QUALOF (directlyassociated with overland flow). If 1, then accumulation andremoval are performed daily, and the removal rate is dependentonly on the accumulation and storage limit parameters (ACQOPand SQOLIM). If 2, accumulation and removel are performedevery interval, and the removal rate also takes into accountatmospheric deposition plus lateral inflows. QSOFG DFIELD8 d(0 j$If VQOFG is 1 then the rate of accumulation and thelimiting storage of QUALOF may vary monthly. VQOFG DFIELD9 d(0 J$If QIFWFG is 1 this constituent is a QUALIF (interflowassociated). QIFWFG EFIELD10e(0 %If VIQCFG is 1 or greater, then the concentration of this constituentin interflow outflow may vary monthly. If 2 or 4, no interpolation isused. If 3 or 4, units are mg/L. This requires QTYID to be LB (English)or KG (Metric). VIQCFG EFIELD11e(0 J%If QAGWFG is 1, this constituent is a QUALGW (groundwater associated). QAGWFG FFIELD12f(0 &If VAQCFG is 1, the concentration of this constituent ingroundwater outflow may vary monthly. If 2 or 4, no interpolation isused. If 3 or 4, units are mg/L. This requires QTYID to be LB (English)or KG (Metric). VAQCFG mIdentifiers and flags for a quality constituent.This table should be repeated for each quality constituent. (1X,3A4,4X,A4,9I10) CON NAME QTYID QSDFP VPFWFG VPFSFG QSOFP VQOFG QIFWFP VIQCFG QAGWFP VAQCFG  Storage on surface and nonseasonal parameters SQO POTFW POTFS ACQOP SQOLIM WSQOP IOQC AOQC qty/ac qty/ton qty/ton qty/ qty/ac in/hr qty/ft3 qty/ft3 x - x ac.day QUAL-INPUT @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a@y0. B!SQO is the initial storage of QUALOF on the surface of thePLS. SQOAFIELD3 a@y0. !POTFW is the washoff potency factor for a QUALSD. A potencyfactor is the ratio of constituent yield to sediment(washoff or scour) outflow. POTFW BFIELD4 b@y0. "POTFS is the scour potency factor for a QUALSD. A potencyfactor is the ratio of constituent yield to sediment(washoff or scour) outflow. POTFS BFIELD5 b@y0. "ACQOP is the rate of accumulation of QUALOF if QSOFG is positive.If QSOFG is negative, then ACQOP is the concentration of QUALOFin the surface outflow in mg/l. ACQOP CFIELD6 c@75y 0.000001 ?#SQOLIM is the maximum storage of QUALOF if QSOFG is positive. SQOLIM CFIELD7 c@ #<y1.64 `#WSQOP is the rate of surface runoff which will remove 90percent of stored QUALOF per hour.WSQOP DFIELD8 d@y0. l$IOQC is the concentration of the constituent in interflowoutflow (meaningful only if this is a QUALIF).IOQC DFIELD9 d@y0. x$AOQC is the concentration of the constituent in activegroundwater outflow (meaningful only if this is a QUALGW).AOQC |Storage on surface and nonseasonal parameter values for sectionThis table should be repeated for each quality constituent.  (1X,8(1PE10.3)) Storage on surface and nonseasonal parameters SQO POTFW POTFS ACQOP SQOLIM WSQOP IOQC AOQC (qty/ac) (qty/ton) (qty/ton) (qty/ (qty/ac) (in/hr) (qty/ft3) (qty/ft3) ac.day)  Storage on surface and nonseasonal parameters SQO POTFW POTFS ACQOP SQOLIM WSQOP IOQC AOQC qty/ qty/ qty/ qty/ qty/ha mm/hr qty/l qty/l x - x ha tonne tonne ha.day QUAL-INPUT @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a@y0. B!SQO is the initial storage of QUALOF on the surface of thePLS. SQOAFIELD3 a@y0. !POTFW is the washoff potency factor for a QUALSD. A potencyfactor is the ratio of constituent yield to sediment(washoff or scour) outflow. POTFW BFIELD4 b@y0. "POTFS is the scour potency factor for a QUALSD. A potencyfactor is the ratio of constituent yield to sediment(washoff or scour) outflow. POTFS BFIELD5 b@y0. ."ACQOP is the rate of accumulation of QUALOF. ACQOP CFIELD6 c@76y 0.000002 *#SQOLIM is the maximum storage of QUALOF. SQOLIM CFIELD7 c@>y41.7 `#WSQOP is the rate of surface runoff which will remove 90percent of stored QUALOF per hour.WSQOP DFIELD8 d@y0. l$IOQC is the concentration of the constituent in interflowoutflow (meaningful only if this is a QUALIF).IOQC DFIELD9 d@y0. x$AOQC is the concentration of the constituent in activegroundwater outflow (meaningful only if this is a QUALGW).AOQC |Storage on surface and nonseasonal parameter values for sectionThis table should be repeated for each quality constituent.  (1X,8(1PE10.3)) Storage on surface and nonseasonal parameters SQO POTFW POTFS ACQOP SQOLIM WSQOP IOQC AOQC (qty/ha) (qty/ (qty/ (qty/ (qty/ha) (mm/hr) (qty/l) (qty/l) tonne) tonne) ha.day)  Value at start of each month for washoff potency factor (lb/ton) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-POTFW @`POTFW @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. >!WPFJAN is the washoff potency factor at the start of January. WPFJAN AFIELD3 a(y0. WPFFEB BFIELD4 b(y0. WPFMAR BFIELD5 b(y0. WPFAPR CFIELD6 c(y0. WPFMAY CFIELD7 c(y0. WPFJUN DFIELD8 d(y0. WPFJUL DFIELD9 d(y0. WPFAUG EFIELD10e(y0. WPFSEP EFIELD11e(y0. WPFOCT FFIELD12f(y0. WPFNOV FFIELD13f(y0. WPFDEC Monthly values of washoff potency factor at start of each month.This table is only required if VPFWFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for POTFW at start of each month (qty/ton) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value at start of each month for washoff potency factor (qty/tonn) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-POTFW @`POTFW @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. >!WPFJAN is the washoff potency factor at the start of January. WPFJAN AFIELD3 a(y0. WPFFEB BFIELD4 b(y0. WPFMAR BFIELD5 b(y0. WPFAPR CFIELD6 c(y0. WPFMAY CFIELD7 c(y0. WPFJUN DFIELD8 d(y0. WPFJUL DFIELD9 d(y0. WPFAUG EFIELD10e(y0. WPFSEP EFIELD11e(y0. WPFOCT FFIELD12f(y0. WPFNOV FFIELD13f(y0. WPFDEC Monthly values of washoff potency factor at start of each month.This table is only required if VPFWFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for POTFW at start of each month (qty/tonne) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of each month for scour potency factor (lb/ton) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-POTFS @`POTFS @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. <!SPFJAN is the scour potency factor at the start of January.SPFJAN AFIELD3 a(y0. SPFFEB BFIELD4 b(y0. SPFMAR BFIELD5 b(y0. SPFAPR CFIELD6 c(y0. SPFMAY CFIELD7 c(y0. SPFJUN DFIELD8 d(y0. SPFJUL DFIELD9 d(y0. SPFAUG EFIELD10e(y0. SPFSEP EFIELD11e(y0. SPFOCT FFIELD12f(y0. SPFNOV FFIELD13f(y0. SPFDEC Monthly values of scour potency factor at start of each month.This table is only required if VPFSFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for POTFS at start of each month (qty/ton) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value at start of each month for scour potency factor (qty/tonne) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-POTFS @`POTFS @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. <!SPFJAN is the scour potency factor at the start of January.SPFJAN AFIELD3 a(y0. SPFFEB BFIELD4 b(y0. SPFMAR BFIELD5 b(y0. SPFAPR CFIELD6 c(y0. SPFMAY CFIELD7 c(y0. SPFJUN DFIELD8 d(y0. SPFJUL DFIELD9 d(y0. SPFAUG EFIELD10e(y0. SPFSEP EFIELD11e(y0. SPFOCT FFIELD12f(y0. SPFNOV FFIELD13f(y0. SPFDEC Monthly values of scour potency factor at start of each month.This table is only required if VPFSFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for POTFS at start of each month (qty/tonne) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of each month for accum rate of QUALOF (lb/ac.day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ACCUM @`ACQOP @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. <!QUAJAN is the accum rate of QUALOF at the start of January.QUAJAN AFIELD3 a(y0. QUAFEB BFIELD4 b(y0. QUAMAR BFIELD5 b(y0. QUAAPR CFIELD6 c(y0. QUAMAY CFIELD7 c(y0. QUAJUN DFIELD8 d(y0. QUAJUL DFIELD9 d(y0. QUAAUG EFIELD10e(y0. QUASEP EFIELD11e(y0. QUAOCT FFIELD12f(y0. QUANOV FFIELD13f(y0. QUADEC Monthly values of accumulation rate of QUALOF at start of each month.This table is only required if VQOFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for ACCUM at start of each month (qty/ac.day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of each month for accum rate of QUALOF (qty/ha.day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-ACCUM @`ACQOP @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. <!QUAJAN is the accum rate of QUALOF at the start of January.QUAJAN AFIELD3 a(y0. QUAFEB BFIELD4 b(y0. QUAMAR BFIELD5 b(y0. QUAAPR CFIELD6 c(y0. QUAMAY CFIELD7 c(y0. QUAJUN DFIELD8 d(y0. QUAJUL DFIELD9 d(y0. QUAAUG EFIELD10e(y0. QUASEP EFIELD11e(y0. QUAOCT FFIELD12f(y0. QUANOV FFIELD13f(y0. QUADEC Monthly values of accumulation rate of QUALOF at start of each month.This table is only required if VQOFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for ACCUM at start of each month (qty/ha.d) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of month for limiting storage of QUALOF (lb/ac) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-SQOLIM @`SQOLIM @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(75y 0.000001 A!SQOJAN is the limiting storage of QUALOF at the start of January SQOJAN AFIELD3 a(75y 0.000001 SQOFEB BFIELD4 b(75y 0.000001 SQOMAR BFIELD5 b(75y 0.000001 SQOAPR CFIELD6 c(75y 0.000001 SQOMAY CFIELD7 c(75y 0.000001 SQOJUN DFIELD8 d(75y 0.000001 SQOJUL DFIELD9 d(75y 0.000001 SQOAUG EFIELD10e(75y 0.000001 SQOSEP EFIELD11e(75y 0.000001 SQOOCT FFIELD12f(75y 0.000001 SQONOV FFIELD13f(75y 0.000001 SQODEC Monthly values limiting storage of QUALOF at start of each month.This table is only required if VQOFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for SQOLIM at start of each month (qty/ac) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Value at start of month for limiting storage of QUALOF (qty/ha) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-SQOLIM @`SQOLIM @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(76y 0.000002 A!SQOJAN is the limiting storage of QUALOF at the start of January SQOJAN AFIELD3 a(76y 0.000002 SQOFEB BFIELD4 b(76y 0.000002 SQOMAR BFIELD5 b(76y 0.000002 SQOAPR CFIELD6 c(76y 0.000002 SQOMAY CFIELD7 c(76y 0.000002 SQOJUN DFIELD8 d(76y 0.000002 SQOJUL DFIELD9 d(76y 0.000002 SQOAUG EFIELD10e(76y 0.000002 SQOSEP EFIELD11e(76y 0.000002 SQOOCT FFIELD12f(76y 0.000002 SQONOV FFIELD13f(76y 0.000002 SQODEC Monthly values limiting storage of QUALOF at start of each month.This table is only required if VQOFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for SQOLIM at start of each month (qty/ha) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Conc of QUAL in interflow outflow for each month (qty/ft3) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  MON-IFLW-CONC @`IOQC @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. <!CONJAN is the conc of QUAL in interflow outflow in January.CONJAN AFIELD3 a(y0. CONFEB BFIELD4 b(y0. CONMAR BFIELD5 b(y0. CONAPR CFIELD6 c(y0. CONMAY CFIELD7 c(y0. CONJUN DFIELD8 d(y0. CONJUL DFIELD9 d(y0. CONAUG EFIELD10e(y0. CONSEP EFIELD11e(y0. CONOCT FFIELD12f(y0. CONNOV FFIELD13f(y0. CONDEC Monthly values of conc of QUAL in interflow outflow at start of month.This table is only required if VIQCFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for IOQC at start of each month (qty/ft3) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Conc of QUAL in interflow outflow for each month (qty/l) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-IFLW-CONC @`IOQC @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. <!CONJAN is the conc of QUAL in interflow outflow in January.CONJAN AFIELD3 a(y0. CONFEB BFIELD4 b(y0. CONMAR BFIELD5 b(y0. CONAPR CFIELD6 c(y0. CONMAY CFIELD7 c(y0. CONJUN DFIELD8 d(y0. CONJUL DFIELD9 d(y0. CONAUG EFIELD10e(y0. CONSEP EFIELD11e(y0. CONOCT FFIELD12f(y0. CONNOV FFIELD13f(y0. CONDEC Monthly values of conc of QUAL in interflow outflow at start of month.This table is only required if VIQCFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for IOQC at start of each month (qty/l) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of month for conc of QUAL in groundwater (qty/ft3) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  MON-GRND-CONC @`AOQC @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. C!GRCJAN is the conc of QUAL in groundwater at the start of January. GRCJAN AFIELD3 a(y0. GRCFEB BFIELD4 b(y0. GRCMAR BFIELD5 b(y0. GRCAPR CFIELD6 c(y0. GRCMAY CFIELD7 c(y0. GRCJUN DFIELD8 d(y0. GRCJUL DFIELD9 d(y0. GRCAUG EFIELD10e(y0. GRCSEP EFIELD11e(y0. GRCOCT FFIELD12f(y0. GRCNOV FFIELD13f(y0. GRCDEC Monthly values of conc of QUAL in groundwater at start of each month.This table is only required if VAQCFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for AOQC at start of each month (qty/ft3) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Value at start of month for conc of QUAL in groundwater (qty/l) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  MON-GRND-CONC @`AOQC @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. C!GRCJAN is the conc of QUAL in groundwater at the start of January. GRCJAN AFIELD3 a(y0. GRCFEB BFIELD4 b(y0. GRCMAR BFIELD5 b(y0. GRCAPR CFIELD6 c(y0. GRCMAY CFIELD7 c(y0. GRCJUN DFIELD8 d(y0. GRCJUL DFIELD9 d(y0. GRCAUG EFIELD10e(y0. GRCSEP EFIELD11e(y0. GRCOCT FFIELD12f(y0. GRCNOV FFIELD13f(y0. GRCDEC Monthly values of conc of QUAL in groundwater at start of each month.This table is only required if VAQCFG in Table-type QUAL-PROPS is 1.This table should be repeated for each quality constituent. (1X,12(1PE10.3))Values for AOQC at start of each month (qty/l) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  VUZFG x - x  VUZFG @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 !VUZFG is a flag which indicates whether or not the upper zone nominalstorage varies throughout the year or not. A value of zero means itdoes not vary, value 1 means it does. If it does vary, the systemwill expect a table of type MON-UZSN in the User's Control Input.Table VUZFG is only required if section PWATER is inactive. If thatsection is active VUZFG would have already been provided in the inputfor PWATER (Table-type PWAT-PARM1) VUZFG fVariable upper zone flag (section MSTLAY).This table is only required if section PWATER is inactive. U (1X,I10) VUZFG (This table should not be supplied if section PWATER is active) F UZSN LZSN SURS x - x (in) (in) (in) UZSN-LZSN @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a@ #< A-999. )!UZSN is the nominal upper zone storage. UZSN AFIELD3 a@ #<B-999. )!LZSN is the nominal lower zone storage. LZSN BFIELD4 b@n:B0.001 1"SURS is the initial surface detention storage. SURS ~Values of UZSN, LZSN and initial surface storage (section MSTLAY).This table is only required if section PWATER is inactive. N (1X,8(1PE10.3)) UZSN LZSN SURS (in) (in) (in) F UZSN LZSN SURS x - x (mm) (mm) (mm) UZSN-LZSN @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a@>zC-999. )!UZSN is the nominal upper zone storage. UZSN AFIELD3 a@>@E-999. )!LZSN is the nominal lower zone storage. LZSN BFIELD4 b@<@E0.025 1"SURS is the initial surface detention storage. SURS ~Values of UZSN, LZSN and initial surface storage (section MSTLAY).This table is only required if section PWATER is inactive. N (1X,8(1PE10.3)) UZSN LZSN SURS (mm) (mm) (mm) 4 SLMPF ULPF LLPF x - x MST-PARM @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPn:?1. !SLMPF is a factor used to adjust the solute percolation(leaching) rate from the surface layer storage to the upperlayer principal storage. SLMPF AFIELD3 aP? A1. !ULPF is a factor used to adjust the solute percolation(leaching) rate from the upper layer principal storage tothe lower layer storage. ULPF BFIELD4 bP? A1. "LLPF is a factor used to adjust the solute percolation(leaching) rate from the lower layer storage to the activeand inactive groundwater.LLPF ?Factors used to adjust solute leaching rates (section MSTLAY). / (1X,3(1PE10.3)) SLMPF ULPF LLPF R Topsoil storages (lb/ac) x - x SMSTM UMSTM IMSTM MST-TOPSTOR@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. F!SMSTM is the initial moisture content in the surfacestorage. SMSTM AFIELD3 aPy0. P!UMSTM is the initial moisture content in the upperprincipal storage.UMSTM BFIELD4 bPy0. ]"IMSTM is the initial moisture content in the uppertransitory (interflow) storage. IMSTM AInitial moisture storage in each topsoil layer (section MSTLAY). e (1X,3(1PE10.3)) Topsoil storages SMSTM UMSTM IMSTM (lb/ac) (lb/ac) (lb/ac) R Topsoil storages (kg/ha) x - x SMSTM UMSTM IMSTM MST-TOPSTOR@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. F!SMSTM is the initial moisture content in the surfacestorage. SMSTM AFIELD3 aPy0. P!UMSTM is the initial moisture content in the upperprincipal storage.UMSTM BFIELD4 bPy0. ]"IMSTM is the initial moisture content in the uppertransitory (interflow) storage. IMSTM AInitial moisture storage in each topsoil layer (section MSTLAY). e (1X,3(1PE10.3)) Topsoil storages SMSTM UMSTM IMSTM (kg/ha) (kg/ha) (kg/ha) u Fractional fluxes in topsoil layers (/ivl) x - x FSO FSP FII FUP FIO MST-TOPFLX @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0. f!FSO is the initial fraction of surface layer solutes instorage being removed by surface runoff. FSOAFIELD3 aP?0. !FSP is the initial fraction of surface layer solutes instorage being percolated to the upper layer principalstorage. FSPBFIELD4 bP?0. z"FII is the initial fraction of upper layer solutes instorage going to upper layer transitory (interflow) storage. FIIBFIELD5 bP?0. r"FUP is the initial fraction of upper layer solutes instorage being percolated to the lower layer storage. FUPCFIELD6 cP?0. #FIO is the initial fraction of upper layer solutes intransitory (interflow) moisture storage being removed byinterflow outflow. FIO>Initial fractional fluxes in topsoil layers (section MSTLAY). K (1X,5(1PE10.3)) FSO FSP FII FUP FIO (/ivl) D Subsoil moisture (lb/ac) x - x LMSTM AMSTM MST-SUBSTOR@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. ;!LMSTM is the initial moisture storage in the lower layer. LMSTM AFIELD3 aPy0. P!AMSTM is the initial moisture storage in the activegroundwater layer.AMSTM Initial moisture storage in subsurface layers (section MSTLAY).Usually, this table should be omitted and the default values taken.K (1X,2(1PE10.3))Subsoil moisture LMSTM AMSTM (lb/ac) (lb/ac) D Subsoil moisture (kg/ha) x - x LMSTM AMSTM MST-SUBSTOR@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. ;!LMSTM is the initial moisture storage in the lower layer. LMSTM AFIELD3 aPy0. P!AMSTM is the initial moisture storage in the activegroundwater layer.AMSTM Initial moisture storage in subsurface layers (section MSTLAY).Usually, this table should be omitted and the default values taken.K (1X,2(1PE10.3))Subsoil moisture LMSTM AMSTM (kg/ha) (kg/ha) Y Subsurface fractional fluxes (/ivl) x - x FLP FLDP FAO MST-SUBFLX @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0. m!FLP is the initial fraction of lower layer solutes instorage being percolated to active groundwater. FLPAFIELD3 aP?0. !FLDP is the initial fraction of lower layer solutes instorage being percolated to inactive groundwater by deeppercolation. FLDP BFIELD4 bP?0. n"FAO is the initial fraction of active groundwater solutesin storage being removed by groundwater outflow. FAOInitial fractional fluxes in subsurface layers (section MSTLAY).Usually, this table should be omitted and the default values taken. 8 (1X,3(1PE10.3)) FLP FLDP FAO (/ivl)[ NPST|Max iterations|Adsorp option x - x |Pst1 Pst2 Pst3|Pst1 Pst2 Pst3 PEST-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(1 H!NPST is the number of pesticides being simulated in theoperation.NPST AFIELD3 a(d30 A!ITMXPS(1)-(3) are the maximum number of iterations that willbe made in trying to solve for adsorbed and dissolvedequilibrium using the Freundlich isotherm. A separate valuemay be supplied for each pesticide being handled (up to 3).If the Freundlich method is not being used, these valueshave no effect. ITMXP1 BFIELD4 b(d30 ITMXP2 BFIELD5 b(d30 ITMXP3 CFIELD6 c(2 #ADOPFG(1) is the flag which indicates which method will beused to simulate adsorption/desorption, for pesticide 1;value of 1 means first-order kinetics, 2 means single-valueFreundlich method, and 3 means non-single value Freundlichmethod.ADOPF1 CFIELD7 c(2 #ADOPFG(2) is the flag which indicates which method will beused to simulate adsorption/desorption, for pesticide 2;value of 1 means first-order kinetics, 2 means single-valueFreundlich method, and 3 means non-single value Freundlichmethod.ADOPF2 DFIELD8 d(2 $ADOPFG(3) is the flag which indicates which method will beused to simulate adsorption/desorption, for pesticide 3;value of 1 means first-order kinetics, 2 means single-valueFreundlich method, and 3 means non-single value Freundlichmethod.ADOPF3 Flags for pesticide simulation. (1X,7I10) NPST ITMXPS for each pesticide ADOPFG for each pesticide 1 2 3 1 2 3  Atmospheric Deposition Flags <-------PEST1------> <-------PEST2------> <-------PEST3------> x - x  PEST-AD-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a0 2!Value of 0 indicates that atmospheric deposition flux of pesticide #1in crystalline form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(1) AAFIELD3 a0 5!Value of 0 indicates that concentration of pesticide #1 in crystallineform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(2) ABFIELD4 b0 /"Value of 0 indicates that atmospheric deposition flux of pesticide #1in adsorbed form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(3) BBFIELD5 b0 2"Value of 0 indicates that concentration of pesticide #1 in adsorbedform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(4) BCFIELD6 c0 /#Value of 0 indicates that atmospheric deposition flux of pesticide #1in solution form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(5) CCFIELD7 c0 2#Value of 0 indicates that concentration of pesticide #1 in solutionform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(6) CDFIELD8 d0 2$Value of 0 indicates that atmospheric deposition flux of pesticide #2in crystalline form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(7) DDFIELD9 d0 5$Value of 0 indicates that concentration of pesticide #2 in crystallineform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(8) DEFIELD10e0 /%Value of 0 indicates that atmospheric deposition flux of pesticide #2in adsorbed form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(9) EEFIELD11e0 2%Value of 0 indicates that concentration of pesticide #2 in adsorbedform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(10) EFFIELD12f0 /&Value of 0 indicates that atmospheric deposition flux of pesticide #2in solution form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(11) FFFIELD13f0 2&Value of 0 indicates that concentration of pesticide #2 in solutionform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(12) FGFIELD14g0 2'Value of 0 indicates that atmospheric deposition flux of pesticide #3in crystalline form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(13) GGFIELD15g0 5'Value of 0 indicates that concentration of pesticide #3 in crystallineform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(14) GHFIELD16h0 /(Value of 0 indicates that atmospheric deposition flux of pesticide #3in adsorbed form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(15) HHFIELD17h0 2(Value of 0 indicates that concentration of pesticide #3 in adsorbedform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(16) HIFIELD18i0 /)Value of 0 indicates that atmospheric deposition flux of pesticide #3in solution form is absent. A value of -1 indicates that it issupplied as a direct time series as PEADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(17) IIFIELD19i0 2)Value of 0 indicates that concentration of pesticide #3 in solutionform in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PEADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PEADFG(18) I(Pesticide atmospheric deposition flags. (1X,3(3(1X,2I4),1X)) Atmospheric Deposition Flags CRYS1 ADSB1 SOLN1 CRYS2 ADSB2 SOLN2 CRYS3 ADSB3 SOLN3 FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON FLX CON * Pesticide x - x  PEST-ID@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 [!PESTID(*) is a string of up to 20 characters whichspecifies the pesticide name. PESTID aEName of pesticide. This table should be repeated for each pesticide.  (1X,5A4)Name of pesticide:> Temperature parms x - x THDSPS THADPS PEST-THETA @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?@1.05 !THDSPS is used to adjust the desorption rate parameterusing a modified Arrhenius equation; only applicable iffirst-order kinetics are used to simulateadsorption/desorption. THDSPS AFIELD3 aP?@1.05 ΀!THADPS is used to adjust the adsorption rate parameterusing a modified Arrhenius equation; only applicable iffirst-order kinetics are used to simulateadsorption/desorption. THADPS Pesticide first-order reaction temperature correction parametersto adjust the desorption and adsorption rate parameters.This table is only required if ADOPFG=1 in Table-type PEST-FLAGSThis table should be repeated for each pesticide. : (1X,2(1PE10.3)) Temperature parms THDSPS THADPS B First-order parms (/day) x - x KDSPS KADPS PEST-FIRSTPM @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. 7!KDSPS is the first-order desorption rate at 35 deg C. KDSPS AFIELD3 aPy0. 7!KADPS is the first-order adsorption rate at 35 deg C. KADPS Pesticide first-order parameters.This table is only required if ADOPFG=1 for this pesticide. Thensystem expects it to appear four times for this pesticide; firstthe surface layer, second for the upper layer, etc.This table should be repeated for each pesticide. > (1X,2(1PE10.3))First-order parms (/day) KDSPS KADPS * CMAX x - x (ppm) PEST-CMAX @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. ;!CMAX is the maximum solubility of the pesticide in water. CMAX Maximum solubility of pesticide.This table is only required if ADOPFG=2 or 3 for this pesticide.This table should be repeated for each pesticide.& (1X,1(1PE10.3)) CMAX (ppm) > XFIX K1 N1 x - x (ppm) PEST-SVALPM@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. !XFIX is the maximum concentration (on the soil) ofpesticide which is permanently fixed to the soil. The systemexpects this table to appear four times for each pesticide:surface layer, upper layer, lower layer, groundwater layer. XFIX AFIELD3 aPy0. !K1 is the coefficient parameter for the single-valueFreundlich adsorption/desorption equation. The systemexpects this table to appear four times for each pesticide:surface layer, upper layer, lower layer, groundwater layer. K1 BFIELD4 bP?y-999. "N1 is the exponent parameter for the single-valueFreundlich adsorption/desorption equation. The systemexpects this table to appear four times for each pesticide:surface layer, upper layer, lower layer, groundwater layer. N1 !Pesticide parameters for single value Freundlich method.This table is only required if ADOPFG=2 for this pesticide. Thesystem expects it to appear four times for this pesticide; firstthe surface layer, second for the upper layer, etc.This table should be repeated for each pesticide. D (1X,3(1PE10.3)) XFIX K1 N1 (ppm) (complex)H XFIX K1 N1 N2 x - x (ppm) PEST-NONSVPM @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. o!XFIX is the maximum concentration (on the soil) ofpesticide which is permanently fixed in the soil. XFIX AFIELD3 aPy0. c!K1 is the coefficient parameter for the non-single-valueFreundlich curve used for adsorption. K1 BFIELD4 bP?y-999. c"N1 is the exponent parameter for the non-single-valueFreundlich curve used for adsorption. N1 BFIELD5 bP?y-999. "N2 is the exponent parameter for the auxiliary("desorption") curve for the non-single-value Freundlichmethod. N2 'Pesticide parameters for Non-single value Freundlich method.This table is only used if ADOPFG=3 for this pesticide. Then, thesystem expects it to appear four times for this pesticide; firstthe surface layer, second for the upper layer, etc.This table should be repeated for each pesticide. N (1X,4(1PE10.3)) XFIX K1 N1 N2 (ppm) (complex) d Pesticide degradation rates (/day) x - x Surface Upper Lower Groundw PEST-DEGRAD@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0. D!SDGCON is the degradation rate of pesticide in the surfacelayer.SDGCON AFIELD3 aP?0. D!UDGCON is the degradation rate of pesticide in the upperlayer.UDGCON BFIELD4 bP?0. D"LDGCON is the degradation rate of pesticide in the lowerlayer.LDGCON BFIELD5 bP?0. P"ADGCON is the degradation rate of pesticide in thegroundwater layer.ADGCON OPesticide degradation rates.This table should be repeated for each pesticide. R (1X,4(1PE10.3))Degradation rates (/day) Surface Upper Lower Grnd-wat ^ Initial pesticide in surface layer (lb/ac) x - x Cryst Ads Soln PEST-STOR1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. !PSCY is the initial pesticide storage in crystalline form.The values given in this table apply to one of the followingfour soil storages: surface, upper principal, lower orgroundwater.PSCY AFIELD3 aPy0. Ā!PSAD is the initial pesticide storage in adsorbed form.The values given in this table apply to one of the followingfour soil storages: surface, upper principal, lower orgroundwater.PSAD BFIELD4 bPy0. "PSSU is the initial pesticide storage in solution. Thevalues given in this table apply to one of the followingfour soil storages: surface, upper principal, lower orgroundwater.PSSU Initial pesticide storage. The values given in this table apply toone of the following four soil storages: surface, upper principal,lower or groundwater. This table should be repeated for each pesticide.: (1X,3(1PE10.3)) Cryst Ads Soln (lb/ac) ^ Initial pesticide in surface layer (kg/ha) x - x Cryst Ads Soln PEST-STOR1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. !PSCY is the initial pesticide storage in crystalline form.The values given in this table apply to one of the followingfour soil storages: surface, upper principal, lower orgroundwater.PSCY AFIELD3 aPy0. Ā!PSAD is the initial pesticide storage in adsorbed form.The values given in this table apply to one of the followingfour soil storages: surface, upper principal, lower orgroundwater.PSAD BFIELD4 bPy0. "PSSU is the initial pesticide storage in solution. Thevalues given in this table apply to one of the followingfour soil storages: surface, upper principal, lower orgroundwater.PSSU Initial pesticide storage. The values given in this table apply toone of the following four soil storages: surface, upper principal,lower or groundwater. This table should be repeated for each pesticide.: (1X,3(1PE10.3)) Cryst Ads Soln (kg/ha) 2 Interflow (lb/ac) x - x storage PEST-STOR2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. !IPS is the initial storage of pesticide in the upper layertransitory (interflow) storage. Since only dissolvedpesticide is modeled in that storage, only one value isneeded (no crystalline or adsorbed material). IPSzInitial pesticide stored in upper layer transitory (interflow) storage.This table should be repeated for each pesticide. $ (1X,1(1PE10.3)) Soln (lb/ac)2 Interflow (kg/ha) x - x storage PEST-STOR2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. !IPS is the initial storage of pesticide in the upper layertransitory (interflow) storage. Since only dissolvedpesticide is modeled in that storage, only one value isneeded (no crystalline or adsorbed material). IPSzInitial pesticide stored in upper layer transitory (interflow) storage.This table should be repeated for each pesticide. $ (1X,1(1PE10.3)) Soln (kg/ha)W Nitrogen flags x - x VNUT FORA ITMX BNUM CNUM NUPT FIXN AMVO ALPN VNPR NIT-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 c!If VNUTFG is 1 the first-order plant uptake parameters fornitrogen are allowed to vary monthly. VNUTFG AFIELD3 a(0 !FORAFG indicates which method is to be used to simulateadsorption and desorption of ammonium: 0 first-orderkinetics; 1 single-value Freundlich method. FORAFG BFIELD4 b(d30 "ITMAXA is the maximum number of iterations that will beattempted in solving the Freundlich equation; applicableonly if FORAFG= 1. ITMAXA BFIELD5 b(-999 "BNUMN is the number of time steps that will elapse betweenrecalculation of biochemical reaction fluxes. All reactionsexcept adsorption/desorption fall into this category.BNUMN CFIELD6 c(-999 z#CNUMN is the number of time steps that will elapse betweenrecalculation of chemical (adsorption/desorption) reactions. CNUMN CFIELD7 c(0 #NUPTFG is a flag indicating the method of simulating plantuptake and immobilization of nutrients. A value of zeroindicates first-order reactions. A value of 1 indicates ayield-based algorithm. A value of 2 indicates saturationkinetics with different parameter values for each soillayer. A value of -2 indicates the same algorithm with thesame parameters for each soil layer. NUPTFG DFIELD8 d(0 H$FIXNFG is a flag indicating whether nitrogen fixing is beingsimulated.FIXNFG DFIELD9 d(0 P$AMVOFG is a flag indicating whether ammonia volatilizationis being simulated.AMVOFG EFIELD10e(0 n%ALPNFG is a flag indicating whether to simulate the above-ground and litter compartments for plant nitrogen. ALPNFG EFIELD11e(0 a%If VNPRFG is 1, then the plant return parameters fornitrogen are allowed to vary monthly. VNPRFG 1Flags for nitrogen simulation in PERLND segment. (1X,10I10) Nitrogen flags VNUTFG FORAFG ITMAXA BNUMN CNUMN NUPTFG FIXNFG AMVOFG ALPNFG VNPRFG  Atmospheric Deposition Flags <----NO3----> <----NH3----> <---ORGN----> x - x NIT-AD-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a0 *!Value of 0 indicates that atmospheric deposition flux of NO3 to thesurface layer is absent. A value of -1 indicates that it is suppliedas a direct time series as NIADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(1) AAFIELD3 a0 -!Value of 0 indicates that concentration of NO3 to the surface layer inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as NIADCN. A value greater than 0 indi catesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(2) ABFIELD4 b0 ("Value of 0 indicates that atmospheric deposition flux of NO3 to theupper layer is absent. A value of -1 indicates that it is supplied asa direct time series as NIADFX. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. NIADFG(3) BBFIELD5 b0 +"Value of 0 indicates that concentration of NO3 to the upper layer inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as NIADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(4) BCFIELD6 c0 *#Value of 0 indicates that atmospheric deposition flux of NH3 to thesurface layer is absent. A value of -1 indicates that it is suppliedas a direct time series as NIADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(5) CCFIELD7 c0 -#Value of 0 indicates that concentration of NH3 to the surface layer inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as NIADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(6) CDFIELD8 d0 ($Value of 0 indicates that atmospheric deposition flux of NH3 to theupper layer is absent. A value of -1 indicates that it is supplied asa direct time series as NIADFX. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. NIADFG(7) DDFIELD9 d0 +$Value of 0 indicates that co ncentration of NH3 to the upper layer inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as NIADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(8) DEFIELD10e0 0%Value of 0 indicates that atmospheric deposition flux of organic N tothe surface layer is absent. A value of -1 indicates that it issupplied as a direct time series as NIADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(9) EEFIELD11e0 3%Value of 0 indicates that concentration of organic N to the surfacelayer in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as NIADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(10) EFFIELD12f0 .&Value of 0 indicates that atmospheric deposition flux of organic N tothe upper layer is absent. A value of -1 indicates that it is suppliedas a direct time series as NIADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(11) FFFIELD13f0 1&Value of 0 indicates that concentration of organic N to the upper layerin precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as NIADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. NIADFG(12) F'Nitrogen atmospheric deposition flags. (1X,3(2(1X,2I4),1X)) Atmospheric Deposition Flags NITRATE AMMONIA ORGANIC N SURF UPPER SURF UPPER SURF UPPER FLX CON FLX  CON FLX CON FLX CON FLX CON FLX CON ` Nitrogen plant uptake rates (/day) x - x Surface Upper Lower Groundw NIT-UPTAKE @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. T!SKPLN is the plant nitrogen uptake reaction rate parameterfor the surface layer.SKPLN AFIELD3 aPy0. R!UKPLN is the plant nitrogen uptake reaction rate parameterfor the upper layer. UKPLN BFIELD4 bPy0. R"LKPLN is the plant nitrogen uptake reaction rate parameterfor the lower layer. LKPLN BFIELD5 bPy0. _"AKPLN is the plant nitrogen uptake reaction rate parameterfor the active groundwater layer. AKPLN ]Nitrogen plant uptake rate parameters. This table is only requiredif VNUTFG=0 and NUPTFG=0. \ (1X,4(1PE10.3))Nitrogen plant uptake rates (/day) SKPLN UKPLN LKPLN AKPLN Plant uptake parm for nitrogen in soil layer (/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NITUPT @`KPLN @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. >!KPLJAN is the plant uptake parameter for nitrogen in January. KPLJAN AFIELD3 a(y0. KPLFEB BFIELD4 b(y0. KPLMAR BFIELD5 b(y0. KPLAPR CFIELD6 c(y0. KPLMAY CFIELD7 c(y0. KPLJUN DFIELD8 d(y0. KPLJUL DFIELD9 d(y0. KPLAUG EFIELD10e(y0. KPLSEP EFIELD11e(y0. KPLOCT FFIELD12f(y0. KPLNOV FFIELD13f(y0. KPLDEC Monthly values of plant uptake reaction rate parameters for nitrogenThis en  tire table is supplied four times; first for the surface layer,second for the upper layer, third for the lower layer and fourth forthe active groundwater layer. If omitted default values will besupplied. This table is required if the plant uptake parameters varythroughout the year (VNUTFG=1 in Table-type NIT-FLAGS) and first-orderreaction rates are being used (NUPTFG=0 in Table-type NIT-FLAGS). (1X,12(1PE10.3))Plant uptake parameter for nitrogen in soil layer (/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC z Upt-facts<--------- Temp-parms (theta) ---------> x - x NO3 NH4 PLN KDSA KADA KIMN KAM KDNI KNI KIMA NIT-FSTGEN @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(n:?1. x!NO3UTF designates which fraction of nitrogen uptake comesfrom nitrate. The sum of NO3UTF and NH4UTF should be 1.0.NO3UTF AFIELD3 a(?0. y!NH4UTF designates which fraction of nitrogen uptake comesfrom ammonium. The sum of NO3UTF and NH4UTF should be 1.0. NH4UTF BFIELD4 b(?@1.07 c"THPLN is the temperature coefficient (theta) for plantuptake (Only relevant if NUPTFG= 0). THPLN BFIELD5 b(?@1.05 g"THKDSA is the temperature coefficient (theta) for ammoniumdesorption (only relevant if FORAFG= 0). THKDSA CFIELD6 c(?@1.05 g#THKADA is the temperature coefficient (theta) for ammoniumadsorption (only relevant if FORAFG= 0). THKADA CFIELD7 c(?@1.07 M#THKIMN is the temperature coefficient (theta) for nitrateimmobilization. THKIMN DFIELD8 d(?@1.07 M$THKAM is the temperature coefficient (theta) for organic Nammonification. THKAM DFIELD9 d(?@1.07 N$THKDNI is the temper  ature coefficient for NO3denitrification. THKDNI EFIELD10e(?@1.05 L%THKNI is the temperature coefficient (theta) fornitrification.THKNI EFIELD11e(?@1.07 M%THKIMA is the temperature coefficient (theta) for ammoniumimmobilization. THKIMA dNitrogen first-order general parameters. If this table is omitteddefault values will be supplied. (1X,10(1PE10.3)) Upt-facts <----------------------------- Temp-parms (theta) -----------------------------> NO3UTF NH4UTF THPLN THKDSA THKADA THKIMN THKAM THKDNI THKNI THKIMA  Nitrogen first-order parameters (/day) x - x KDSAM KADAM KIMNI KAM KDNI KNI KIM NIT-FSTPM @@FIELD1 PLSs to which these data apply.OPNID `AAFIELD2 aPy0. l!KDSAM is the first-order reaction rate parameter forammonium desorption (irrelevant if FORAFG= 1)KDSAM AFIELD3 aPy0. m!KADAM is the first-order reaction rate parameter forammonium adsorption (irrelevant if FORAFG= 1). KADAM BFIELD4 bPy0. p"KIMNI is the first-order reaction rate parameter fornitrate immobilization (irrelevant if NUPFTG= 2).KIMNI BFIELD5 bPy0. O"KAM is the first-order reaction rate parameter for organicN ammonification. KAMCFIELD6 cPy0. N#KDNI is the first-order reaction rate parameter fordenitrification. KDNI CFIELD7 cPy0. L#KNI is the first-order reaction rate parameter fornitrification.KNIDFIELD8 dPy0. V$KIMAM is the first-order reaction rate parameter forammonium immobilization. KIMAM tNitrogen first-order reaction parameters.HSPF expects this table to appear four times i n the User's ControlInput; first for the surface layer, second for the upper layer, thirdfor the lower layer, fourth for the active groundwater layer. Ifone or more occurrences of the table are missing, all reactionparameters for the affected layer(s) will be defaulted to zero. (1X,7(1PE10.3)) Nitrogen first-order parameters (/day) KDSAM KADAM KIMNI KAM KDNI KNI KIMAM * CMAX x - x (ppm) NIT-CMAX @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. 6!CMAX is the maximum solubility of ammonium in water. CMAX _Maximum solubility of ammonium.This table only appears once and is only required if FORAFG=1. & (1X,1(1PE10.3)) CMAX (ppm) > XFIX K1 N1 x - x (ppm) NIT-SVALPM @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. !XFIX is the maximum concentration (on the soil) of ammoniumwhich is permanently fixed to the soil. The system expectsthis table to appear four times: surface layer, upper layer,lower layer, groundwater layer. XFIX AFIELD3 aPy0. !K1 is the coefficient parameter for the single-valueFreundlich adsorption/desorption equation. The systemexpects this table to appear four times: surface layer,upper layer, lower layer, groundwater layer.K1 BFIELD4 bP?y-999. "N1 is the exponent parameter for the single-valueFreundlich adsorption/desorption equation. The systemexpects this table to appear four times: surface layer,upper layer, lower layer, groundwater layer.N1 Nitrogen single value Freundlich adsorption/desorption parameterHSPF expects this table to appear four times in the User's ControlInput; first for the surface layer, second for the upper layer, thir dfor the lower layer, fourth for the active groundwater layer. Ifone or more occurrences of the table are missing, all reactionparameters for the affected layer(s) will be defaulted to zero.This table is only required if FORAFG=1.D (1X,3(1PE10.3)) XFIX K1 N1 (ppm) (complex)w Maximum plant uptake and immobilization rates (mg/l/day) x - x KUPNI KUPAM KIMNI KIMAM NIT-UPIMKMAX @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.04!KUPNI is the maximum plant uptake rate for nitrate.KUPNI AAFIELD3 aPy0.04!KUPAM is the maximum plant uptake rate for ammonia.KUPAM ABFIELD4 bPy0.06"KIMNI is the maximum immobilization rate for nitrate. KIMNI BBFIELD5 bPy0.06"KIMAM is the maximum immobilization rate for ammonia. KIMAM BThese are the maximum rate constants for nitrogen uptake andimmobilization when using saturation kinetics (NUPTFG= 2 or -2in Table-type NIT-FLAGS) and rate constants do not vary monthly(VNUTFG=0 in Table-type NIT-FLAGS). If NUPTFG is 2, the tablerepeats for each soil layer. (1X,4(1PE10.3))Maximum rate constants for nitrogen uptake and immobilization (mg/l/day) KUPNI KUPAM KIMNI KIMAM f CSUNI CSUAM CSINI CSIAM x - x (ug/l) (ug/l) (ug/l) (ug/l) NIT-UPIMCSAT @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.0@!CSUNI is the nitrate half saturation constant for plant uptake.CSUNI AAFIELD3 aPy0.0@!CSUAM is the ammonia half saturation constant for plant uptake.CSUAM ABFIELD4 bPy0.0B"CSINI is the nitrate half saturation constant for immobilization. CSINI BBFIELD5 bPy0.0B"CSIAM is the ammonia half saturation constant for immobilization. CSIAM BThese are the half saturation constants for nitrogen uptake andimmobilization when using saturation kinetics (NUPTFG= 2 or -2in Table-type NIT-FLAGS). If NUPTFG is 2, the table repeats foreach soil layer. (1X,4(1PE10.3))Half saturation constants for nitrogen uptake and immobilization CSUNI CSUAM CSINI CSIAM (ug/l) (ug/l) (ug/l) (ug/l)  Maximum plant uptake rate for nitrate (mg/l/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NITUPNI@`KUPNI @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. @!KUNJAN is the maximum plant uptake rate for nitrate in January.KUNJAN AFIELD3 a(y0. KUNFEB BFIELD4 b(y0. KUNMAR BFIELD5 b(y0. KUNAPR CFIELD6 c(y0. KUNMAY CFIELD7 c(y0. KUNJUN DFIELD8 d(y0. KUNJUL DFIELD9 d(y0. KUNAUG EFIELD10e(y0. KUNSEP EFIELD11e(y0. KUNOCT FFIELD12f(y0. KUNNOV FFIELD13f(y0. KUNDEC 6Monthly values of maximum plant uptake rate for nitrate. This tableis required if the plant uptake parameters vary throughout the year(VNUTFG=1 in Table-type NIT-FLAGS) and saturation kinetics are beingused (NUPTFG= 2 or -2 in Table-type NIT-FLAGS). If NUPTFG is 2, thetable repeats for each soil layer. (1X,12(1PE10.3))Maximum plant uptake rate for nitrate (mg/l/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Maximum plant uptake rate for ammonia (mg/l/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NITUPAM@`KUPAM @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. @!KUAJAN is the maximum plant uptake rate for ammonia in January.KUAJAN AFIELD3 a(y0. KUAFEB BFIELD4 b(y0. KUAMAR BFIELD5 b(y0. KUAAPR CFIELD6 c(y0. KUAMAY CFIELD7 c(y0. KUAJUN DFIELD8 d(y0. KUAJUL DFIELD9 d(y0. KUAAUG EFIELD10e(y0. KUASEP EFIELD11e(y0. KUAOCT FFIELD12f(y0. KUANOV FFIELD13f(y0. KUADEC 6Monthly values of maximum plant uptake rate for ammonia. This tableis required if the plant uptake parameters vary throughout the year(VNUTFG=1 in Table-type NIT-FLAGS) and saturation kinetics are beingused (NUPTFG= 2 or -2 in Table-type NIT-FLAGS). If NUPTFG is 2, thetable repeats for each soil layer. (1X,12(1PE10.3))Maximum plant uptake rate for ammonia (mg/l/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Maximum immobilization rate for nitrate (mg/l/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NITIMNI@`KIMNI @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. B!KINJAN is the maximum immobilization rate for nitrate in January. KINJAN AFIELD3 a(y0. KINFEB BFIELD4 b(y0. KINMAR BFIELD5 b(y0. KINAPR CFIELD6 c(y0. KINMAY CFIELD7 c(y0. KINJUN DFIELD8 d(y0. KINJUL DFIELD9 d(y0. KINAUG EFIELD10e(y0. KINSEP EFIELD11e(y0. KINOCT FFIELD12f(y0. KINNOV FFIELD13f(y0. KINDEC 8Monthly values of maximum immobilization rate for nitrate. This tableis required if the plant uptake parameters vary throughout the year(VNUTFG=1 in Table-type NIT-FLAGS) and saturation kinetics are beingused (NUPTFG= 2 or -2 in Table-type NIT-FLAGS). If NUPTFG is 2, thetable repeats for each soil layer. (1X,12(1PE10.3))Maximum immobilization rate for nitrate (mg/l/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Maximum immobilization rate for ammonia (mg/l/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NITIMAM@`KIMAM @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. B!KIAJAN is the maximum immobilization rate for ammonia in January. KIAJAN AFIELD3 a(y0. KIAFEB BFIELD4 b(y0. KIAMAR BFIELD5 b(y0. KIAAPR CFIELD6 c(y0. KIAMAY CFIELD7 c(y0. KIAJUN DFIELD8 d(y0. KIAJUL DFIELD9 d(y0. KIAAUG EFIELD10e(y0. KIASEP EFIELD11e(y0. KIAOCT FFIELD12f(y0. KIANOV FFIELD13f(y0. KIADEC 8Monthly values of maximum immobilization rate for ammonia. This tableis required if the plant uptake parameters vary throughout the year(VNUTFG=1 in Table-type NIT-FLAGS) and saturation kinetics are beingused (NUPTFG= 2 or -2 in Table-type NIT-FLAGS). If NUPTFG is 2, thetable repeats for each soil layer. (1X,12(1PE10.3))Maximum immobilization rate for ammonia (mg/l/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  SKVOL UKVOL LKVOL AKVOL THVOL TRFVOL x - x (/day) (/day) (/day) (/day) (-) (deg C) NIT-AMVOLAT@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.0Z!SKVOL is the ammonia volatilization rate at 20 degrees Celsius inthe surface soil layer. SKVOL AAFIELD3 aPy0.0X!UKVOL is the ammonia volatilization rate at 20 degrees Celsius inthe upper soil layer.UKVOL ABFIELD4 bPy0.0X"LKVOL is the ammonia volatilization rate at 20 degrees Celsius inthe lower soil layer.LKVOL BBFIELD5 bPy0.0`"AKVOL is the ammonia volatilization rate at 20 degrees Celsius inthe active groundwater layer.AKVOL BCFIELD6 cP?@1.07 L#THVOL is the temperature correction coefficient for ammoniavolatilization.THVOL CCFIELD7 cP B20.0 ^#TRFVOL is the reference temperature for the temperature correctionof ammonia volatilization. TRFVOL CrThese are the parameters for ammonia volatilization. This table isrequired if AMVOFG=1 in Table-type NIT-FLAGS. (1X,6(1PE10.3))Ammonia volatilization parameters SKVOL UKVOL LKVOL AKVOL THVOL TRFVOL (/day) (/day) (/day) (/day) (deg C) > NUPTGT NMXRAT x - x (lb/ac) (-) NIT-YIELD @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.07!NUPTGT is the total annual uptake target for nitrogen. NUPTGT AAFIELD3 aP?y1.0I!NMXRAT is the ratio of maximum possible N uptake tooptimum uptake rate. NMXRAT AlThis table is required when yield-based plant uptake isbeing simulated (NUPTFG=1 in Table-type NIT-FLAGS).X (1X,2(1PE10.3)) Yield-based nitrogen uptake parameters NUPTGT NMXRAT (lb/ac)> NUPTGT NMXRAT x - x (kg/ha) (-) NIT-YIELD @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.07!NUPTGT is the total annual uptake target for nitrogen. NUPTGT AAFIELD3 aP?y1.0I!NMXRAT is the ratio of maximum possible N uptake tooptimum uptake rate. NMXRAT AlThis table is required when yield-based plant uptake isbeing simulated (NUPTFG=1 in Table-type NIT-FLAGS).W (1X,2(1PE10.3))Yield-based nitrogen uptake parameters NUPTGT NMXRAT (kg/ha) ~ Monthly fractions of total annual N uptake x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NUPT-FR1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. @!TNUJAN is the fraction of the total annual N uptake in January.TNUJAN AFIELD3 a(?0. TNUFEB BFIELD4 b(?0. TNUMAR BFIELD5 b(?0. TNUAPR CFIELD6 c(?0. TNUMAY CFIELD7 c(?0. TNUJUN DFIELD8 d(?0. TNUJUL DFIELD9 d(?0. TNUAUG EFIELD10e(?0. TNUSEP EFIELD11e(?0. TNUOCT FFIELD12f(?0. TNUNOV FFIELD13f(?0. TNUDEC Fractions of the total annual nitrogen uptake target applied toeach month. This table is required when yield-based plantuptake is being used (NUPTFG=1 in Table-type NIT-FLAGS). (1X,12(1PE10.3))Monthly fractions of total annual N uptake JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly fractions of N uptake from soil layer x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NUPT-FR2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. U!LNUJAN is the fraction of the monthly N uptake taken from thesoil layer in January. LNUJAN AFIELD3 a(?0. LNUFEB BFIELD4 b(?0. LNUMAR BFIELD5 b(?0. LNUAPR CFIELD6 c(?0. LNUMAY CFIELD7 c(?0. LNUJUN DFIELD8 d(?0. LNUJUL DFIELD9 d(?0. LNUAUG EFIELD10e(?0. LNUSEP EFIELD11e(?0. LNUOCT FFIELD12f(?0. LNUNOV FFIELD13f(?0. LNUDEC Fractions of the monthly nitrogen uptake target taken from eachsoil layer. This table appears four times (once each for thesurface, upper, lower, and active groundwater layers) and isrequired when yield-based plant uptake is being used (NUPTFG=1in Table-type NIT-FLAGS). The sum of the four fractions for amonth must be unity. The actual monthly N uptake target for asoil layer is the total annual target (NUPTGT in Table-typeNIT-YIELD) times the monthly fraction (in Table-type MON-NUPT-FR1)times the layer fraction for the month. (1X,12(1PE10.3))Monthly fractions of N uptake from soil layer JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC\ KLON KRON KONLR THNLR x - x (/day) NIT-ORGPM @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPx`1.0E20 8!KLON is the partition coefficient for labile organic N.KLON AAFIELD3 aPx`1.0E20 SKPRBN UKPRBN LKPRBN AKPRBN BGNPRF x - x (/day) (/day) (/day) (/day) NIT-BGPLRET@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.0h!SKPRBN is the first-order rate of return of plant N to particulateorganic N in the surface soil layer.SKPRBN AAFIELD3 aPy0.0f!UKPRBN is the first-order rate of return of plant N to particulateorganic N in the upper soil layer. UKPRBN ABFIELD4 bPy0.0f"LKPRBN is the first-order rate of return of plant N to particulateorganic N in the lower soil layer. LKPRBN BBFIELD5 bPy0.0n"AKPRBN is the first-order rate of return of plant N to particulateorganic N in the active groundwater layer. AKPRBN BCFIELD6 cP?0.0R#BGNPRF is the fraction of below-ground plant nitrogen return whichis refractory. BGPRFR CyThis table is used to specify first-order rates of return of below-ground plant nitrogen. Rates are given for the four soil layers,plus the fraction returning as particulate refractory organic Ninstead of particulate labile organic N. These rates are notadjusted for temperature. This table is used if plant returnrates are constant (VPLRFG=0 in Table-type NIT-FLAGS). (1X,7(1PE10.3)) Below-ground plant nitrogen return rates and refractory fraction SKPRBN UKPRBN LKPRBN AKPRBN BGNPRF (/day) (/day) (/day) (/day)  Above-ground plant return rates and refractory fraction AGKPRN SKPRLN UKPRLN LINPRF x - x (/day) (/day) (/day) NIT-AGPLRET@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.0N!AGKPRN is the first-order rate of return of above-ground plant Nto litter N. AGKPRN AAFIELD3 aPy0.0]!SKPRLN is the first-order rate of return of litter N to organic N inthe surface soil layer. SKPRLN ABFIELD4 bPy0.0["UKPRLN is the first-order rate of return of litter N to organic N inthe upper soil layer. UKPRLN BBFIELD5 bP?0.0F"LINPRF is the fraction of litter nitrogen return which is refractory. LINPRF BThis table is used to specify first-order rates of return of above-ground plant and litter nitrogen. Litter rates are given for the toptwo soil layers, plus the fraction returning as particulate refractoryorganic N instead of particulate labile organic N. These rates are notadjusted for temperature. This table is only input if the above-groundcompartments are being simulated (ALPNFG=1 in Table-type NIT-FLAGS) andplant return rates are constant (VPLRFG=0 in Table-type NIT-FLAGS). (1X,7(1PE10.3)) Above-ground plant and litter nitrogen return rates and refractory fraction AGKPRN SKPRLN UKPRLN LINPRF (/day) (/day) (/day)  Monthly return rates for below-ground plant nitrogen (/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NPRETBG@`KPRBN @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. ]!BNRJAN is the first-order return rate for below-ground plant Nto the soil layer in January. BNRJAN AFIELD3 a(y0. BNRFEB BFIELD4 b(y0. BNRMAR BFIELD5 b(y0. BNRAPR CFIELD6 c(y0. BNRMAY CFIELD7 c(y0. BNRJUN DFIELD8 d(y0. BNRJUL DFIELD9 d(y0. BNRAUG EFIELD10e(y0. BNRSEP EFIELD11e(y0. BNROCT FFIELD12f(y0. BNRNOV FFIELD13f(y0. BNRDEC This table specifies monthly first-order return rates forbelow-ground plant nitrogen to each soil layer in the formof particulate organic N. The table is used if VNPRFG=1 inTable-type NIT-FLAGS. It is repeated four times, once foreach soil layer. (1X,12(1PE10.3))Monthly first-order return rates for below-ground plant N (/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly return rates for above-ground plant nitrogen (/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NPRETAG@`AGKPRN @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. e!ANRJAN is the first-order return rate for above-ground plant Nto the litter compartment in January. ANRJAN AFIELD3 a(y0. ANRFEB BFIELD4 b(y0. ANRMAR BFIELD5 b(y0. ANRAPR CFIELD6 c(y0. ANRMAY CFIELD7 c(y0. ANRJUN DFIELD8 d(y0. ANRJUL DFIELD9 d(y0. ANRAUG EFIELD10e(y0. ANRSEP EFIELD11e(y0. ANROCT FFIELD12f(y0. ANRNOV FFIELD13f(y0. ANRDEC This table specifies monthly first-order return rates forabove-ground plant nitrogen to the litter layer. The tableis used if ALPNFG= 1 and VNPRFG=1 in Table-type NIT-FLAGS. (1X,12(1PE10.3))Monthly first-order return rates for above-ground plant N (/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly return rates for litter compartment nitrogen (/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NPRETLI@`KPRLN @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. d!LNRJAN is the first-order return rate for litter compartmentnitrogen to the soil layer in January.LNRJAN AFIELD3 a(y0. LNRFEB BFIELD4 b(y0. LNRMAR BFIELD5 b(y0. LNRAPR CFIELD6 c(y0. LNRMAY CFIELD7 c(y0. LNRJUN DFIELD8 d(y0. LNRJUL DFIELD9 d(y0. LNRAUG EFIELD10e(y0. LNRSEP EFIELD11e(y0. LNROCT FFIELD12f(y0. LNRNOV FFIELD13f(y0. LNRDEC This table specifies monthly first-order return rates forlitter layer nitrogen to the soil layer. The table is usedif ALPNFG= 1 and VNPRFG=1 in Table-type NIT-FLAGS. It isrepeated twice, for the surface and upper soil layers only. (1X,12(1PE10.3))Monthly first-order return rates for litter compartment N (/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly refractory fractions for below-ground plant N return x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NPRETFBG @`BGNPRF @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. !BNFJAN is the fraction of below-ground plant N returnwhich returns as particulate refractory organic N insteadof particulate labile organic N in January.BNFJAN AFIELD3 a(?0. BNFFEB BFIELD4 b(?0. BNFMAR BFIELD5 b(?0. BNFAPR CFIELD6 c(?0. BNFMAY CFIELD7 c(?0. BNFJUN DFIELD8 d(?0. BNFJUL DFIELD9 d(?0. BNFAUG EFIELD10e(?0. BNFSEP EFIELD11e(?0. BNFOCT FFIELD12f(?0. BNFNOV FFIELD13f(?0. BNFDEC This table specifies monthly refractory fractions for below-groundplant nitrogen return. The table is used if plant return ratesvary monthly (VNPRFG=1 in Table-type NIT-FLAGS). (1X,12(1PE10.3))Monthly refractory fractions for below-ground plant nitrogen return JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly refractory fractions for litter N return x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NPRETFLI @`LINPRF @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. !LNFJAN is the fraction of litter N return which returns asparticulate refractory organic N instead of particulatelabile organic N in January.LNFJAN AFIELD3 a(?0. LNFFEB BFIELD4 b(?0. LNFMAR BFIELD5 b(?0. LNFAPR CFIELD6 c(?0. LNFMAY CFIELD7 c(?0. LNFJUN DFIELD8 d(?0. LNFJUL DFIELD9 d(?0. LNFAUG EFIELD10e(?0. LNFSEP EFIELD11e(?0. LNFOCT FFIELD12f(?0. LNFNOV FFIELD13f(?0. LNFDEC This table specifies monthly refractory fractions for litter nitrogenreturn. The table is used if plant return rates vary monthly (VNPRFG=1in Table-type NIT-FLAGS) and above-ground compartments are being simulated(ALPNFG=1 in Table-type NIT-FLAGS). (1X,12(1PE10.3))Monthly refractory fractions for litter nitrogen return JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC > SANUTF UANUTF LANUTF AANUTF x - x NIT-AGUTF @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?0.0v!SANUTF is the fraction of plant nitrogen uptake from the surfacesoil layer which goes to above-ground plant storage. SANUTF AAFIELD3 aP?0.0t!UANUTF is the fraction of plant nitrogen uptake from the uppersoil layer which goes to above-ground plant storage.UANUTF ABFIELD4 bP?0.0t"LANUTF is the fraction of plant nitrogen uptake from the lowersoil layer which goes to above-ground plant storage.LANUTF BBFIELD5 bP?0.0|"AANUTF is the fraction of plant nitrogen uptake from the activegroundwater layer which goes to above-ground plant storage.AANUTF BThis table is used only when the above-ground and litter compartmentsare being used (ALPNFG=1 in Table-type NIT-FLAGS) and plant uptake isconstant (VNUTFG=0 in Table-type NIT-FLAGS). ] (1X,4(1PE10.3)) Aboveground plant uptake fractions SANUTF UANUTF LANUTF AANUTF  Monthly above-ground fractions for plant uptake x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-NITAGUTF @`ANUTF @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. o!AGFJAN is the fraction of plant uptake from the soil layer thatgoes to above-ground plant storage in January. AGFJAN AFIELD3 a(?0. AGFFEB BFIELD4 b(?0. AGFMAR BFIELD5 b(?0. AGFAPR CFIELD6 c(?0. AGFMAY CFIELD7 c(?0. AGFJUN DFIELD8 d(?0. AGFJUL DFIELD9 d(?0. AGFAUG EFIELD10e(?0. AGFSEP EFIELD11e(?0. AGFOCT FFIELD12f(?0. AGFNOV FFIELD13f(?0. AGFDEC This table specifies monthly fractions of plant uptake from thesoil layer that goes to above-ground plant storage. The tableis used if plant uptake varies monthly (VNUTFG=1 in Table-typeNIT-FLAGS) and above-ground compartments are being simulated(ALPNFG=1 in Table-type NIT-FLAGS). (1X,12(1PE10.3))Monthly above-ground plant uptake fractions JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC n Initial storage of N (lb/ac) x - x LORGN AMAD AMSU NO3 PLTN RORGN NIT-STOR1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. X!LORGN is the initial total labile organic N storage(solution plus particulate).LORGN AFIELD3 aPy0. 0!AMAD is the initial adsorbed ammonium storage.AMAD BFIELD4 bPy0. 1"AMSU is the initial solution ammonium storage. AMSU BFIELD5 bPy0. %"NO3 is the initial nitrate storage. NO3CFIELD6 cPy0. )#PLTN is the initial N stored in plants. PLTN CFIELD7 cPy0. X#RORGN is the initial total refractory organic N storage(solution plus particulate).RORGN Initial storage of nitrogen. The values given in this table apply toone of the following four soil storages: surface, upper principal,lower or groundwater. V (1X,6(1PE10.3)) LORGN AMAD AMSU NO3 PLTN RORGN (lb/ac) n Initial storage of N (kg/ha) x - x LORGN AMAD AMSU NO3 PLTN RORGN NIT-STOR1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. X!LORGN is the initial total labile organic N storage(solution plus particulate).LORGN AFIELD3 aPy0. 0!AMAD is the initial adsorbed ammonium storage.AMAD BFIELD4 bPy0. 1"AMSU is the initial solution ammonium storage. AMSU BFIELD5 bPy0. %"NO3 is the initial nitrate storage. NO3CFIELD6 cPy0. )#PLTN is the initial N stored in plants. PLTN CFIELD7 cPy0. X#RORGN is the initial total refractory organic N storage(solution plus particulate).RORGN Initial storage of nitrogen. The values given in this table apply toone of the following four soil storages: surface, upper principal,lower or groundwater. V (1X,6(1PE10.3)) LORGN AMAD AMSU NO3 PLTN RORGN (kg/ha)  Initial N in interflow, above-ground, and litter storage (lb/ac) x - x IAMSU INO3 ISLON ISRON AGPLTN LITTRN NIT-STOR2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. i!IAMSU specifies the initial storage of ammonium in theupper layer transitory (interflow) storage. IAMSU AFIELD3 aPy0. c!INO3 specifies the initial storage of nitrate in the upperlayer transitory (interflow) storage. INO3 BFIELD4 bPy0. z"ISLON specifies the initial storage of solution labileorganic N in the upper layer transitory (interflow) storage. ISLON BFIELD5 bPy0. z"ISRON specifies the initial storage of solution refractoryorganic N in the upper layer transitory (interflow) storage. ISRON CFIELD6 cPy0. Q#AGPLTN specifies the initial storage of N in the above-groundplant compartment. AGPLTN CFIELD7 cPy0. E#LITTRN specifies the initial storage of N in the littercompartment. LITTRN Initial storage of nitrogen in upper layer transitory(interflow) and above-ground plant and litter compartments.It specifies the initial storage of ammonium, nitrate andorganic N in the interflow storage, and the nitrogen inthe two plant N compartments. (1X,6(1PE10.3)) Initial N in interflow, above-ground, and litter storage (lb/ac) IAMSU INO3 ISLON ISRON AGPLTN LITTRN Initial N in interflow, above-ground, and litter storage (kg/ha) x - x IAMSU INO3 ISLON ISRON AGPLTN LITTRN NIT-STOR2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. i!IAMSU specifies the initial storage of ammonium in theupper layer transitory (interflow) storage. IAMSU AFIELD3 aPy0. c!INO3 specifies the initial storage of nitrate in the upperlayer transitory (interflow) storage. INO3 BFIELD4 bPy0. z"ISLON specifies the initial storage of solution labileorganic N in the upper layer transitory (interflow) storage. ISLON BFIELD5 bPy0. z"ISRON specifies the initial storage of solution refractoryorganic N in the upper layer transitory (interflow) storage. ISRON CFIELD6 cPy0. Q#AGPLTN specifies the initial storage of N in the above-groundplant compartment. AGPLTN CFIELD7 cPy0. E#LITTRN specifies the initial storage of N in the littercompartment. LITTRN Initial storage of nitrogen in upper layer transitory(interflow) and above-ground plant and litter compartments.It specifies the initial storage of ammonium, nitrate andorganic N in the interflow storage, and the nitrogen inthe two plant N compartments. (1X,6(1PE10.3)) Initial N in interflow, above-ground, and litter storage (kg/ha) IAMSU INO3 ISLON ISRON AGPLTN LITTRNF Phosphorus flags. x - x VPUT FORP ITMX BNUM CNUM PUPT PHOS-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(0 e!If VPUTFG is 1 the first-order plant uptake parameters forphosphorus are allowed to vary monthly. VPUTFG AFIELD3 a(0 !FORPFG indicates which method is to be used to simulateadsorption and desorption of phosphorus: 0 first-orderkinetics; 1 single-value Freundlich method. FORPFG BFIELD4 b(d30 "ITMAXP is the maximum number of iterations that will beattempted in solving the Freu ndlich equation; applicableonly if FORAFG= 1. ITMAXP BFIELD5 b(-999 "BNUMP is the number of time steps that will elapse betweenrecalculation of biochemical reaction fluxes. All reactionsexcept adsorption/desorption fall into this category.BNUMP CFIELD6 c(-999 z#CNUMP is the number of time steps that will elapse betweenrecalculation of chemical (adsorption/desorption) reactions. CNUMP CFIELD7 c(0 π#PUPTFG is a flag indicating the method of simulating plantuptake and immobilization of nutrients. A value of zeroindicates first-order reactions. A value of 1 indicates ayield-based algorithm. PUPTFG *Flags governing simulation of phosphorus. G (1X,6I10) VPUTFG FORPFG ITMAXP BNUMP CNUMP PUPTFG  Atmospheric Deposition Flags <----PO4----> <---ORGP----> x - x  PHOS-AD-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a0 *!Value of 0 indicates that atmospheric deposition flux of PO4 to thesurface layer is absent. A value of -1 indicates that it is suppliedas a direct time series as PHADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PHADFG(1) AAFIELD3 a0 -!Value of 0 indicates that concentration of PO4 to the surface layer inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PHADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PHADFG(2) ABFIELD4 b0 ("Value of 0 indicates that atmospheric deposition flux of PO4 to theupper layer is absent. A value of -1 in!dicates that it is supplied asa direct time series as PHADFX. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. PHADFG(3) BBFIELD5 b0 +"Value of 0 indicates that concentration of PO4 to the upper layer inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as PHADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PHADFG(4) BCFIELD6 c0 0#Value of 0 indicates that atmospheric deposition flux of organic P tothe surface layer is absent. A value of -1 indicates that it issupplied as a direct time series as PHADFX. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PHADFG(5) CCFIELD7 c0 3#Value of 0 indicates that concentration of organic P to the surfacelayer in precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PHADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PHADFG(6) CDFIELD8 d0 .$Value of 0 indicates that atmospheric deposition flux of organic P tothe upper layer is absent. A value of -1 indicates that it is suppliedas a direct time series as PHADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. PHADFG(7) DDFIELD9 d0 1$Value of 0 indicates that concentration of organic P to the upper layerin precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as PHADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric "deposition data. PHADFG(8) D)Phosphorus atmospheric deposition flags. (1X,2(2(1X,2I4),1X)) Atmospheric Deposition Flags PHOSPHATE ORGANIC P SURF UPPER SURF UPPER FLX CON FLX CON FLX CON FLX CONc Phosphorus plant uptake parms (/day) x - x SKPLP UKPLP LKPLP AKPLP PHOS-UPTAKE@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. ^!SKPLP is the plant phosphorus uptake reaction rateparameter for the surface layer. SKPLP AFIELD3 aPy0. \!UKPLP is the plant phosphorus uptake reaction rateparameter for the upper layer.UKPLP BFIELD4 bPy0. \"LKPLP is the plant phosphorus uptake reaction rateparameter for the lower layer.LKPLP BFIELD5 bPy0. i"AKPLP is the plant phosphorus uptake reaction rateparameter for the active groundwater layer. AKPLP gPhosphorus first-order plant uptake parameters. This table is onlyrequired if VPUTFG=0 and PUPTFG=0. _ (1X,4(1PE10.3)) Phosphorus plant uptake parms (/day) SKPLP UKPLP LKPLP AKPLP  Monthly phosphorus uptake parameters for soil layer (/day) x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-PHOSUPT@`KPLP @FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(y0. 6!PLPJAN is the phosphorus uptake parameter in January. PLPJAN AFIELD3 a(y0. PLPFEB BFIELD4 b(y0. PLPMAR BFIELD5 b(y0. PLPAPR CFIELD6 c(y0. PLPMAY CFIELD7 c(y0. PLPJUN DFIELD8 d(y0. PLPJUL DFIELD9 d(y0. PLPAUG EFIELD10!#e(y0. PLPSEP EFIELD11e(y0. PLPOCT FFIELD12f(y0. PLPNOV FFIELD13f(y0. PLPDEC sMonthly values of first-order plant phosphorus uptake reaction rateparameters. This table is required if VPUTFG=1 and PUPTFG=0 inTable-type PHOS-FLAGS. The entire table is supplied four times;first for the surface layer, second for the upper layer, third forthe lower layer and fourth for the active groundwater layer. Ifomitted, default values will be supplied. (1X,12(1PE10.3))Monthly phosphorus uptake parameters for soil layer (/day) JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC q Temperature corection parameters (theta) x - x THPLP THKDSP THKADP THKIMP THKMP PHOS-FSTGEN@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aP?@1.07 a!THPLP is the temperature coefficient (theta) for plantuptake (only relevant if PUPTFG=0). THPLP AFIELD3 aP?@1.05 e!THKDSP is the temperature coefficient (theta) for phosphatedesorption (only relevant if FORPFG=0). THKDSP BFIELD4 bP?@1.05 e"THKADP is the temperature coefficient (theta) for phosphateadsorption (only relevant if FORAFG=0). THKADP BFIELD5 bP?@1.07 M"THKIMP is the temperature coefficient (theta) for phosphateimmobilization. THKIMP CFIELD6 cP?@1.07 M#THKMP is the temperature coefficient (theta) for organic Pmineralization. THKMP <Temperature correction parameters for phosphorus reactions.m (1X,5(1PE10.3)) Temperature corection parameters (theta) THPLP THKDSP THKADP THKIMP THKMP h Phosphorus first-order parameters (/day) x - x KDSP "$ KADP KIMP KMP PHOS-FSTPM @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. k!KDSP is the first-order reaction rate parameter forphosphate desorption (only used if FORPFG=0). KDSP AFIELD3 aPy0. k!KADP is the first-order reaction rate parameter forphosphate adsorption (only used if FORAFG=0). KADP BFIELD4 bPy0. W"KIMP is the first-order reaction rate parameter forphosphate immobilization. KIMP BFIELD5 bPy0. O"KMP is the first-order reaction rate parameter for organicP mineralization. KMPbPhosphorus first-order reaction parameters. The entire tablehas to be supplied four times; first for the surface layer,second for the upper layer, third for the lower layer and fourthfor the active groundwater layer. If one or more occurrences ofthe table are missing, all reaction parameters for the affectedlayer(s) will be defaulted to zero. d (1X,4(1PE10.3)) Phosphorus first-order parameters (/day) KDSP KADP KIMP KMP* CMAX x - x (ppm) PHOS-CMAX @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. 7!CMAX is the maximum solubility of phosphate in water. CMAX `Maximum solubility of phosphate. This table only appears onceand is only required if FORPFG=1.& (1X,1(1PE10.3)) CMAX (ppm) t Parameters for Freundlich method XFIX K1 N1 x - x (ppm) (complex) PHOS-SVALPM@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. !XFIX is the maximum concentration (on the soil) ofphosphorus which is permanently fixed to the soil. Thesystem expects this table to appear four times: s#%urfacelayer, upper layer, lower layer, groundwater layer. XFIX AFIELD3 aPy0. !K1 is the coefficient parameter for the single-valueFreundlich adsorption/desorption equation. The systemexpects this table to appear four times: surface layer,upper layer, lower layer, groundwater layer.K1 BFIELD4 bP?y-999. "N1 is the exponent parameter for the single-valueFreundlich adsorption/desorption equation. The systemexpects this table to appear four times: surface layer,upper layer, lower layer, groundwater layer.N1 6Phosphorus single value Freundlich adsorption/desorption parameterThis table is only used if FORPFG=1 in Table-type PHOS-FLAGS. Thesystem expects this table to appear four times; first for the surfacelayer, second for the upper layer, third for the lower layer andfourth for the active groundwater layer. f (1X,3(1PE10.3)) Parameters for Freundlich method XFIX K1 N1 (ppm) (complex) > PUPTGT PMXRAT x - x (lb/ac) (-) PHOS-YIELD @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.09!PUPTGT is the total annual uptake target for phosphorus. PUPTGT AAFIELD3 aP?y1.0I!PMXRAT is the ratio of maximum possible P uptake tooptimum uptake rate. PMXRAT AmThis table is required when yield-based plant uptake isbeing simulated (PUPTFG=1 in Table-type PHOS-FLAGS). Z (1X,2(1PE10.3)) Yield-based phosphorus uptake parameters PUPTGT PMXRAT (lb/ac) > PUPTGT PMXRAT x - x (kg/ha) (-) PHOS-YIELD @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0.09!PUPTGT is the total annual uptake target for phosphorus. PUPTGT AAFIELD3 aP?y$&1.0I!PMXRAT is the ratio of maximum possible P uptake tooptimum uptake rate. PMXRAT AmThis table is required when yield-based plant uptake isbeing simulated (PUPTFG=1 in Table-type PHOS-FLAGS). Y (1X,2(1PE10.3))Yield-based phosphorus uptake parameters PUPTGT PMXRAT (kg/ha) ~ Monthly fractions of total annual P uptake x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-PUPT-FR1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. @!TPUJAN is the fraction of the total annual P uptake in January.TPUJAN AFIELD3 a(?0. TPUFEB BFIELD4 b(?0. TPUMAR BFIELD5 b(?0. TPUAPR CFIELD6 c(?0. TPUMAY CFIELD7 c(?0. TPUJUN DFIELD8 d(?0. TPUJUL DFIELD9 d(?0. TPUAUG EFIELD10e(?0. TPUSEP EFIELD11e(?0. TPUOCT FFIELD12f(?0. TPUNOV FFIELD13f(?0. TPUDEC Fractions of the total annual phosphorus uptake target applied toeach month. This table is required when yield-based plantuptake is being used (PUPTFG=1 in Table-type PHOS-FLAGS). (1X,12(1PE10.3))Monthly fractions of total annual P uptake JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  Monthly fractions of P uptake from soil layer x - x JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC MON-PUPT-FR2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a(?0. U!LPUJAN is the fraction of the monthly P uptake taken from thesoil layer in January. LPUJAN AFIELD3 a(%'?0. LPUFEB BFIELD4 b(?0. LPUMAR BFIELD5 b(?0. LPUAPR CFIELD6 c(?0. LPUMAY CFIELD7 c(?0. LPUJUN DFIELD8 d(?0. LPUJUL DFIELD9 d(?0. LPUAUG EFIELD10e(?0. LPUSEP EFIELD11e(?0. LPUOCT FFIELD12f(?0. LPUNOV FFIELD13f(?0. LPUDEC #Fractions of the monthly phosphorus uptake target taken from eachsoil layer. This table appears four times (once each for thesurface, upper, lower, and active groundwater layers) and isrequired when yield-based plant uptake is being used (PUPTFG=1in Table-type PHOS-FLAGS). The sum of the four fractions for amonth must be unity. The actual monthly P uptake target for asoil layer is the total annual target (PUPTGT in Table-typePHOS-YIELD) times the monthly fraction (in Table-type MON-PUPT-FR1)times the layer fraction for the month. (1X,12(1PE10.3))Monthly fractions of P uptake from soil layer JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DECh Initial phosphorus in soil layer (lb/ac) x - x ORGP P4AD P4SU PLTP PHOS-STOR1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. (!ORGP is the initial organic P storage.ORGP AFIELD3 aPy0. 1!P4AD is the initial adsorbed phosphate storage. P4AD BFIELD4 bPy0. 1"P4SU is the initial solution phosphate storage. P4SU BFIELD5 bPy0. )"PLTP is the initial P stored in plants. PLTP Initial phosphorus storage in a specified layer.The values given in this table apply to one of the following soilstorages:&( surface, upper principal, lower or groundwater. C (1X,4(1PE10.3)) ORGP P4AD P4SU PLTP (lb/ac) h Initial phosphorus in soil layer (kg/ha) x - x ORGP P4AD P4SU PLTP PHOS-STOR1 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. (!ORGP is the initial organic P storage.ORGP AFIELD3 aPy0. 1!P4AD is the initial adsorbed phosphate storage. P4AD BFIELD4 bPy0. 1"P4SU is the initial solution phosphate storage. P4SU BFIELD5 bPy0. )"PLTP is the initial P stored in plants. PLTP Initial phosphorus storage in a specified layer.The values given in this table apply to one of the following soilstorages: surface, upper principal, lower or groundwater. C (1X,4(1PE10.3)) ORGP P4AD P4SU PLTP (kg/ha) @ Phosphate in interflow (lb/ac) x - x IP4SU PHOS-STOR2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. i!IP4SU specifies the initial storage of phosphate in theupper layer transitory (interflow) storage. IP4SU eThis table specifies the initial storage of phosphate in upper layertransitory (interflow) storage. = (1X,1(1PE10.3))Phosphate in interflow IP4SU (lb/ac) @ Phosphate in interflow (kg/ha) x - x IP4SU PHOS-STOR2 @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. i!IP4SU specifies the initial storage of phosphate in theupper layer transitory (interflow) storage. IP4SU eThis table specifies the initial storage of phosphate in upper layertransitory (interflow) storage. = (1X,1(1PE10.3))Phosphate in interflow IP4SU (kg/ha) OAtmosphe')ric Deposition Flags x - x  TRAC-AD-FLAGS @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 a0 -!Value of 0 indicates that atmospheric deposition flux of tracer to thesurface layer is absent. A value of -1 indicates that it is suppliedas a direct time series as TRADFX. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. TRADFG(1) AAFIELD3 a0 0!Value of 0 indicates that concentration of tracer to the surface layerin precipitation is absent. A value of -1 indicates that it issupplied as a direct time series as TRADCN. A value greater than 0indicates the index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. TRADFG(2) ABFIELD4 b0 +"Value of 0 indicates that atmospheric deposition flux of tracer to theupper layer is absent. A value of -1 indicates that it is supplied asa direct time series as TRADFX. A value greater than 0 indicates theindex number of the MONTH-DATA block to be used to supply atmosphericdeposition data. TRADFG(3) BBFIELD5 b0 ."Value of 0 indicates that concentration of tracer to the upper layer inprecipitation is absent. A value of -1 indicates that it is suppliedas a direct time series as TRADCN. A value greater than 0 indicatesthe index number of the MONTH-DATA block to be used to supplyatmospheric deposition data. TRADFG(4) B%Tracer atmospheric deposition flags. Q (1X,2(1X,2I4))Atmospheric Deposition Flags SURF UPPER FLX CON FLX CON > Name of tracer x - x TRACID  TRAC-ID@@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 O!Any 20 character string can be supplied as the name of thetracer (*substance. TRACID a)Name of conservative (tracer) substance.  (1X,5A4)Tracer Name: j Initial storage of tracer material in topsoil (lb/ac) x - x STRSU UTRSU ITRSU TRAC-TOPSTOR @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. d!STRSU specifies the initial storage of tracer(conservative) in the surface storage.STRSU AFIELD3 aPy0. l!UTRSU specifies the initial storage of tracer(conservative) in the upper principal storage.UTRSU BFIELD4 bPy0. m"ITRSU specifies the initial storage of tracer(conservative) in the upper transitory storage. ITRSU This table specifies the initial storage of tracer (conservativein the surface, upper principal and upper transitory storages.| (1X,3(1PE10.3))Initial storage of tracer material in topsoil STRSU UTRSU ITRSU (lb/ac) (lb/ac) (lb/ac)j Initial storage of tracer material in topsoil (kg/ha) x - x STRSU UTRSU ITRSU TRAC-TOPSTOR @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. d!STRSU specifies the initial storage of tracer(conservative) in the surface storage.STRSU AFIELD3 aPy0. l!UTRSU specifies the initial storage of tracer(conservative) in the upper principal storage.UTRSU BFIELD4 bPy0. m"ITRSU specifies the initial storage of tracer(conservative) in the upper transitory storage. ITRSU This table specifies the initial storage of tracer (conservativein the surface, upper principal and upper transitory storages.| (1X,3(1PE10.3))Initial storage of tracer material in topsoil STRSU UTRSU ITRSU (kg/ha) (kg/ha) )(kg/ha)f Initial storage of tracer material in subsoil layers (lb/ac) x - x LTRSU ATRSU TRAC-SUBSTOR @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. o!LTRSU specifies the initial storage of conservative(tracer) material in the lower groundwater layer. LTRSU AFIELD3 aPy0. p!ATRSU specifies the initial storage of conservative(tracer) material in the active groundwater layer.ATRSU cThis table specifies the initial storage of tracer (conservativethe lower and groundwater layers. x (1X,2(1PE10.3)) Initial storage of tracer material in subsoil layers (lb/ac) LTRSU ATRSU (lb/ac) (lb/ac)f Initial storage of tracer material in subsoil layers (kg/ha) x - x LTRSU ATRSU TRAC-SUBSTOR @@FIELD1 PLSs to which these data apply.OPNID `QAFIELD2 aPy0. o!LTRSU specifies the initial storage of conservative(tracer) material in the lower groundwater layer. LTRSU AFIELD3 aPy0. p!ATRSU specifies the initial storage of conservative(tracer) material in the active groundwater layer.ATRSU cThis table specifies the initial storage of tracer (conservativethe lower and groundwater layers. x (1X,2(1PE10.3)) Initial storage of tracer material in subsoil layers (kg/ha) LTRSU ATRSU (kg/ha) (kg/ha)u $!20000309112938 20000309112938 COPYTS HWVVVVVVW INPUT 10OUTPUT 20 POINTMEAN POINTMEAN POINT 20 1 -2 1 1 0 2 0 30 ENG any 0 1 0 1 Point-valued input time series MET any 0 1 0 1 MEAN 20 1 -3 1 2 0 2 0 50 ENG any 0 1 0 1 Mean-valued input time series MET any 0 1 0 1 POINT 20 1 -2 1 1 0 0 0 70 ENG any 0 1 0 1 Point-valued output time series MET any 0 1 0 1 MEAN 20 1 -3 1 2 0 0 0 90 ENG any 0 1 0 1 Mean-valued output time series MET any 0 1 0 1 |u $!20000309112938 20000309112938 HBMPGEN XX  10 1 1 5 u.| $!20000309112938 20000309112938 COPY \[\Q\\f  2 - 1 1TIMESERIES 101 101 301 301 0 0 0END COPY 000 000 000 000 4  Select COPY table to modify. @ TIMESERIES @@ Tn Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the COPY TIMESERIES table. ` 1  Copy-opn x - x NPT NMN TIMESERIES @@FIELD1 + COPY operations to which these data apply. OPNID `QAFIELD3 a(0 =!NPT is the number of point-valued time series to be copied. NPTAFIELD4 a(0 ry atmospheric deposition to reach MET kg/iv 0 4.537E2 0 1000. PLADWT 3 1 3 1 2 9 0 18030 ENG lb/iv 0 1.602E4 0 3.531E4 Wet atmospheric deposition to reach MET kg/iv 0 4.537E2 0 1000. PLADEP 3 1 3 1 2 9 0 18033 ENG lb/iv 0 1.602E4 0 3.531E4 Total atmospheric deposition to reach MET kg/iv 0 4.537E2 0 1000. PKCF5 5 1 5 1 2 9 0 18036 ENG lb/iv 0 1.602E4 0 3.531E4 Phytoplankton reaction fluxes MET kg/iv 0 4.537E2 0 1000. PKCF6 3 1 3 1 2 9 0 18041 ENG lb/iv 0 1.602E4 0 3.531E4 Zooplankton reaction fluxes MET kg/iv 0 4.537E2 0 1000. PKCF7 3 4 3-17174 2 9 0 18044 ENG mg/m2.iv 0 1 0 1 Benthic algae reaction fluxes MET mg/m2.iv 0 1 0 1 TPKCF7 3 1 3 1 2 9 0 18056 ENG mg/m2.iv 0 1 0 1 Benthic algae reaction fluxes MET mg/m2.iv 0 1 0 1 PKCF8 5 1 5 1 2 9 0 18059 ENG lb/iv 0 1.602E4 0 3.531E4 Dead refractory organic N fluxes MET kg/iv 0 4.537E2 0 1000. PKCF9 5 1 5 1 2 9 0 18064 ENG lb/iv 0 1.602E4 0 3.531E4 Dead refractory organic P fluxes MET kg/iv 0 4.537E2 0 1000. PKCF10 5 1 5 1 2 9 0 18069 ENG lb/iv 0 1.602E4 0 3.531E4 Dead refractory organic C fluxes MET kg/iv 0 4.537E2 0 1000. PHIF 2 1 2 1 2 10 0 18086 ENG lb/iv 0 1.602E4 0 3.531E4 Inflows of TIC and CO2 to RCHRES MET kg/iv 0 4.537E2 0 1000. PHST 3 1 3 1 1 10 0 18098 ENG mg/l;pH 0 1 0 1 TIC and CO2 concs, and pH, MET mg/l;pH 0 1 0 1 SATCO2 1 1 3 1 1 10 0 18102 ENG mg/l=? 0 1 0 1 Saturation CO2 concentration MET mg/l 0 1 0 1 PHCF1 2 1 2 1 2 10 0 18113 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows of TIC and CO2 from RCHRES MET kg/iv 0 4.537E2 0 1000. PHCF2 5 2 -75 2 2 10 0 18165 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows of TIC and CO2 thru indiv exits MET kg/iv 0 4.537E2 0 1000. PHCF3 7 2 -75 2 2 10 0 18210 ENG lb/iv 0 1.602E4 0 3.531E4 Inorganic carbon reaction fluxes MET kg/iv 0 4.537E2 0 1000. ACINFL 7 1-18238 1 2 11 0 18375 ENG lb/iv 0 1.602E1 0 3.531E1 Inflows of acid chemicals (Group ACIDPH) MET kg/iv 0 0.4537 0 1. ACCONC 7 1-18238 1 1 11 0 18284 ENG mol/l 0 1 0 1 Concentrations (Group ACIDPH) MET mol/l 0 1 0 1 ACSTOR 7 1-18238 1 1 11 0 18326 ENG lb 0 1.602E1 0 3.531E1 Storages (Group ACIDPH) MET kg 0 0.4537 0 1 ACFLX1 7 1-18238 1 2 11 0 18417 ENG lb/iv 0 1.602E1 0 3.531E1 Total outflows (Group ACIDPH) MET kg/iv 0 0.4537 0 1 ACFLX2 5 7 -75-18238 2 11 0 18599 ENG lb/iv 0 1.602E1 0 3.531E1 Outflows thru indiv exits (Group ACIDPH) MET kg/iv 0 0.4537 0 1 ACFLXC 10 1 -9694 1 2 11 0 18684 ENG qty/iv 0 1 0 1 Net fluxes of conservatives (ACIDPH) MET qty/iv 0 1 0 1 ACFLXG 3 1-11651 1 2 11 0 18729 ENG qty/iv 0 1 0 1 Net fluxes of GQUALS (Group ACIDPH) MET qty/iv 0 1 0 1 ACPH 1 1 1 1 1 11 0 18772 ENG pH units 0 1 0 1 pH (Group ACIDPH) MET pH units 0 1 0 1 ROVOL 1 1 1 >@ 1 2 1 0 6448 ENG acft/iv 0 43560. 0 35.31E6 Total outflow of water from RCHRES MET Mm3/iv 0 1233.6 0 1.00E6 CROVOL100 1 -2347 1 2 1 0 6449 ENG acft/iv 0 43560. 0 35.31E6 Total outflow of water from RCHRES by com MET Mm3/iv 0 1233.6 0 1.00E6 ROCON 10 1 -9694 1 2 3 0 10245 ENG qty/iv 0 1 0 1 Outflow of conservatives from RCHRES MET qty/iv 0 1 0 1 ROHEAT 1 1 1 1 2 4 0 10996 ENG BTU/iv 0 .0089 0 .0353 Outflow of heat through active exits MET kcl/iv 0252.E-06 0 .001 ROSED 4 1 3 1 2 5 0 11243 ENG tn/iv 0 3.204E7 0 3.531E7 Total outflows of sediment from RCHRES MET tne/iv 0 9.074E5 0 1.000E6 RODQAL 3 1-11651 1 2 6 0 15383 ENG qty/iv 0 1 0 1 Outflow of dissolved qual from RCHRES MET qty/iv 0 1 0 1 ROSQAL 4 3 3-11651 2 6 0 15418 ENG qty/iv 0 1 0 1 Outflow of sed-assoc qual from RCHRES MET qty/iv 0 1 0 1 OXCF1 2 1 2 1 2 7 0 15849 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows of DO and BOD from the RCHRES MET kg/iv 0 4.537E2 0 1000. NUCF1 4 1 4 1 2 8 0 16945 ENG lb/iv 0 1.602E4 0 3.531E4 Total outflows of dissolved nutrients MET kg/iv 0 4.537E2 0 1000. NUCF2 4 2 3 2 2 8 0 16949 ENG lb/iv 0 1.602E4 0 3.531E4 Total outflows of adsorbed NH4 and PO4 MET kg/iv 0 4.537E2 0 1000. PKCF1 5 1 5 1 2 9 0 17967 ENG lb/iv 0 1.602E4 0 3.531E4 Total outflows from RCHRES (Group PLANK) MET kg/iv 0 4.537E2 0 1000. PHCF1 2 1 2 1 2 10 0 18113 ENG lb/iv 0 1.602E4 0 3.531E4 PHCARB TIC, CO2 MET kg/iv 0 4.537E2 0 1000?A. ACFLX1 7 1-18238 1 2 11 0 18417 ENG lb/iv 0 1.602E1 0 3.531E1 Total outflows (Group ACIDPH) MET kg/iv 0 0.4537 0 1. IVOL 1 1 1 1 2 1 2 0 623 ENG acft/iv 0 43560. 0 35.31E6 Inflow of water to the RCHRES MET Mm3/iv 0 1233.6 0 1.00E6 CIVOL 100 1 -2347 1 2 0 2 0 625 ENG acft/iv 0 43560. 0 35.31E6 Inflow of water to the RCHRES by comp. MET Mm3/iv 0 1233.6 0 1.00E6 ICON 10 1 -9694 1 2 3 2 0 9654 ENG qty/iv 0 1 0 1 Inflow of conservative constits. MET qty/iv 0 1 0 1 IHEAT 1 1 1 1 2 4 2 0 10706 ENG BTU/iv 0 .0089 0 .0353 Inflow of heat to RCHRES MET kcl/iv 0252.E-06 0 .001 ISED 3 1 3 1 2 5 2 0 11089 ENG tn/iv 0 3.204E7 0 3.531E7 Inflows of sediments to RCHRES MET tne/iv 0 9.074E5 0 1.000E6 IDQAL 3 1-11651 1 2 6 2 0 11558 ENG qty/iv 0 1 0 1 Inflow of dissolved qual to RCHRES MET qty/iv 0 1 0 1 ISQAL 3 3 3-11651 2 6 2 0 11572 ENG qty/iv 0 1 0 1 Inflows of sed-assoc qual to RCHRES MET qty/iv 0 1 0 1 OXIF 2 1 2 1 2 7 2 0 15801 ENG lb/iv 0 1.602E4 0 3.531E4 Inflows of DO and BOD to RCHRES MET kg/iv 0 4.537E2 0 1000. NUIF1 4 1 4 1 2 8 2 0 16073 ENG lb/iv 0 1.602E4 0 3.531E4 Inflows of dissolved nutrients MET kg/iv 0 4.537E2 0 1000. NUIF2 3 2 3 2 2 8 2 0 16081 ENG lb/iv 0 1.602E4 0 3.531E4 Inflows of adsorbed NH4 and PO4 MET kg/iv 0 4.537E2 0 1000. PKIF 5 1 5 1 2 9 2 0 17113 ENG lb/iv 0 1.602E4 0 3.531E4 Inflows of plankton related constituents MET@} kg/iv 0 4.537E2 0 1000. PHIF 2 1 2 1 2 10 2 0 18084 ENG lb/iv 0 1.602E4 0 3.531E4 Inflows of TIC and CO2 to RCHRES MET kg/iv 0 4.537E2 0 1000. ACINFL 7 1-18238 1 2 11 2 0 18368 ENG lb/iv 0 1.602E1 0 3.531E1 Inflows of acid chemicals (Group ACIDPH) MET kg/iv 0 0.4537 0 1. OVOL 5 1 -75 1 2 1 0 9074 ENG acft/iv 0 43560. 0 35.31E6 Outflow of water through indiv exits MET Mm3/iv 0 1233.6 0 1.00E6 COVOL 5100 -75 -2347 2 1 0 9079 ENG acft/iv 0 43560. 0 35.31E6 Outflow of water through indiv exits by c MET Mm3/iv 0 1233.6 0 1.00E6 OCON 5 10 -75 -9694 2 3 0 10505 ENG qty/iv 0 1 0 1 Outflow of conserv through indiv exits MET qty/iv 0 1 0 1 OHEAT 5 1 -75 1 2 4 0 11022 ENG BTU/iv 0 .0089 0 .0353 Outflow of heat through individual exits MET kcl/iv 0252.E-06 0 .001 OSED 5 4 -75 3 2 5 0 11347 ENG tn/iv 0 3.204E7 0 3.531E7 Outflows of sediment through indiv exits MET tne/iv 0 9.074E5 0 1.000E6 ODQAL 5 3 -75-11651 2 6 0 15551 ENG qty/iv 0 1 0 1 Outflow of diss qual through indiv exits MET qty/iv 0 1 0 1 OSQAL 5 9 -75-11798 2 6 0 15586 ENG qty/iv 0 1 0 1 Sed-assoc qual outflow thru indiv exits MET qty/iv 0 1 0 1 OXCF2 5 2 -75 2 2 7 0 15903 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows of DO and BOD thru indiv exits MET kg/iv 0 4.537E2 0 1000. NUCF9 5 4 -75 4 2 8 0 16999 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows of dissolved nutrients via exits MET kg/iv 0 4.537E2 0 1000. OSNH4 5 4 -75 3 2 8 0 17019 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows of aC 1 1MUTSINFO 101 101 301 301 0 0 0END MUTSIN 000 000 000 000 4  Select MUTSIN table to modify. @ MUTSINFO @@ Mn Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the MUTSIN MUTSINFO table. ` 1/ MUTSIN MFL NPT NMN NLI MSFG x - x MUTSINFO @@FIELD1 - MUTSIN operations to which these data apply. OPNID `QAFIELD3 a(c30 ;!MUTFL is the Fortran unit number of the file being input. MUTFL AFIELD4 a(0 STRN <--tim-sum-header--> TTRN STTR REPORT-SUMM@@FIELD1 - REPORT operations to which these data apply. OPNID `QAFIELD3 @!SRCHED is the header used to mark the summary over all sources.SRCHED a AFIELD4 a SUM ,AVER,MAX ,MIN ,LAST,PCT SUM!SRCTRN is the "transformation code" used to aggregate data across allsources.Valid values are: SUM, AVER, MAX, MIN, LAST, and PCT. SRCTRN BFIELD5 N"TIMHED is the header used to mark the summary over the REPORT timeintervals. TIMHED b%BFIELD6 b SUM ,AVER,MAX ,MIN ,LAST SUM"TIMTRN is the "transformation code" used to aggregate data from theREPORT intervals to their summary. This value is independent ofTRAN in REPORT-CON, which is used to aggregate from the run intervalto the REPORT interval.Valid values are: SUM, AVER, MAX, MIN, and LAST.TIMTRN CFIELD7 c(2 STTRFG #STTRFG indicates how to compute the double-summary value (overall sources and over all REPORT intervals). If 1, then SRCTRNis applied to the time summaries for each source. If 2, thenTIMTRN is applied to the source summaries for each REPORTinterval.qThese parameters describe how the reported values are summarizedwhen aggregated across time and across sources. V (1X,2(5A4,1X,A4,1X)I10) Source header SRGEMFG). FORMFG CFIELD8 c(10 #CWID is the column width for the reported tables: 8-20. -1 means writetab-delimited file. -2 means write comma-delimited file. CWID CFIELD9 c(80 ^#PWID is the page width in characters, used only for the general fluxtable format (FORMFG=3). PWID DFIELD10d(40 S$PLIN is the page length in lines. Not used for user-defined format(FORMFG >= 4). PLIN DFIELD11d(5 U$PCODE is the print interval code for the report: 3 - daily;4 - monthly; 5 - annual. PCODE EFIELD12e( 9 :%PYREND is the month ending the print year for the report. PYREND Flags for REPORT Operation.f (1X,9I10) REPT NCON NSRC FORM CWID PWID PLIN PCOD PYR R Rept-opn x - x<--------------------------title---------------------------> REPORT-TITLE @@FIELD1 - REPORT operations to which these data apply. OPNID `QAFIELD3 E!TITLE is the title of the report, to appear at the top of each page. TITLE a ETITLE is the title of the report, to appear at the top of each page.  (1X,15A4) TITLE * Rept-opn x - x<---source-name----> REPORT-SRC @@FIELD1 - REPORT operations to which these data apply. OPNID `QAFIELD3 -!SRCID is the 20-character name for a source. SRCID1 a YSRCID is an 20-character name for each source. NSRC lines are inputfor each operation.  (1X,5A4) SRCID 9 Rept-opn x - x<-----con-name-----> TRAN SIGD DECP REPORT-CON @@FIELD1 - REPORT operations to which these data apply. OPNID `QAFIELD3 3!CONID is a 20-character name for each constituent. CONID a AFIELD4 a SUM ,AVER,MAX ,MIN ,LAST SUM!TRANHF 1 1REPORT-FLAGS 101 101 301 301 15 1 1REPORT-TITLE 102 102 302 302 11 1 1REPORT-SRC 103 103 303 303 11 1 1REPORT-CON 104 104 304 304 13 1 1REPORT-SUMM 105 105 305 305 0 0 0END REPORT 000 000 000 000 f  Select REPORT table(s) to modify. @AREPORT-FLAGS @BREPORT-TITLE @CREPORT-SRC @DREPORT-CON @@A r Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the REPORT REPORT-FLAGS table. ` ;A@B r! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the REPORT REPORT-TITLE table. a ;A@C p! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the REPORT REPORT-SRC table.a 3 B@D p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the REPORT REPORT-CON table.b 3C Rept-opn x - x REPT NCON NSRC FORM CWID PWID PLIN PCOD PYR REPORT-FLAGS @@FIELD1 - REPORT operations to which these data apply. OPNID `QAFIELD3 a( c30 :!REPTFL is the file unit number for the report output file REPTFL AFIELD4 a(21 ׀!NCON is the number of constituents (i.e. timeseries per source) to beentered in report. Note that, for example, the concentration and loadingof the same substance count as separate constituents for this purpose. NCON BFIELD5 b(c1 |"NSRC is the number of sources (e.g. land segments, point sources,atmospheric deposition to reach) to be entered in report.NSRC BFIELD6 b(c1 "FORMFG specifies the format for the report: 0 - database records;1 - unit-area loading table; 2 - total loading table; 3 - generalsummary table; 10+ - user-defined format (requires input format filewhose unit number in the FILES block equals FOR5G $!20000919092609 20000919092609 REPORT  RQ̌I2  10 | $!20000309112939 20000309112939 GENERTS Œ INPUT 10OUTPUT 20  ONETWO TIMSER ONE 1 1 1 1 2 0 2 0 42 ENG any 0 1 0 1 First input time series MET any 0 1 0 1 TWO 1 1 1 1 2 0 2 0 43 ENG any 0 1 0 1 Second input time series MET any 0 1 0 1 TIMSER 1 1 1 1 2 0 0 0 44 ENG any 0 1 0 1 Output time series (mean-valued) MET any 0 1 0 1 X9F $!20030814161451 20030814161451 HIMPQUA IŔ  50 1 1 5 There are too many sediment-associated quality constituents specified in the input to module section pqual or iqual (the limit is &I). The problem arose when processing the constituent '&CCCCCCCCCCC'.  50 1 1 5 There are too many overland-flow-associated quality constituents specified in the input to module section pqual or iqual (the limit is &I). The problem arose when processing the constituent '&CCCCCCCCCCC'.   50 1 1 5 A constituent must be associated with overland flow in order to receive atmospheric deposition inputs. However, atmospheric deposition was specified in table type IQL-AD-FLAGS for constituent '&CCCCCCCCCCC', which is not overland-flow-associated. r $!20000309112939 20000309112939 REPORTTS INPUT 10  TIMSER TIMSER 50 99 -17 -18 2 0 2 0 12476 ENG any 0 1 0 1 Input time series MET any 0 1 0 1 Mr $!20000309112939 20000309112939 HUTOP  ٘ td2  20 1 1 5 MUTSIN: &I Sequential input file unit: &I The date on the multiple timeseries sequential input file (seqdat) does not correspond to the date in HSPF (exdate). Time from input file: &I &I &I &I &I Time from HSPF: &I &I &I &I &I   1 1 1 5 MUTSIN: &I Sequential input file unit: &I The end of the multiple timeseries sequential input file was reached before any data was found. Is the name correct in the FILES block? Are MUTFL and NLINES correct in Table-type MUTSINFO? F  20 1 1 5 MUTSIN: &I Sequential input file unit: &I An error occurred reading the first data line in the multiple timeseries sequential input file. See the MUTSIN/PLTGEN format in the HSPF Manual. The input was: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC   1 1 1 5 MUTSIN: &I Sequential input file unit: &I The end of the multiple timeseries sequential input file was reached reading the first data line in the multiple timeseries sequential input file. Is NLINES correct in Table-type MUTSINFO?x  20 1 1 5 MUTSIN: &I Sequential input file unit: &I An error occurred reading a data line in the multiple timeseries sequential input file. See the MUTSIN/PLTGEN format in the HSPF Manual. Time from HSPF: &I &I &I &I &I ThLe input was: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC  1 1 1 5 MUTSIN: &I Sequential input file unit: &I The end of the multiple timeseries sequential input file was reached reading data from the multiple timeseries sequential input file. Time from HSPF: &I &I &I &I &I 8  10 11 0 5 PLTGEN: &I The PLOTINFO table for this PLTGEN specifies that &I point-valued timeseries should be supplied. However, POINT &I was not supplied in the EXT SOURCES, NETWORK, or SCHEMATIC blocks. Is the source time series specified in one of these blocks? Has it been commented out? If the intended source of this time series is an operation - is that operation commented out in the OPN SEQUENCE block? If the intended source is a PERLND, IMPLND, or RCHRES - is the appropriate module section turned on in the ACTIVITY table?6  10 11 0 5 PLTGEN: &I The PLOTINFO table for this PLTGEN specifies that &I mean-valued timeseries should be supplied. However, MEAN &I was not supplied in the EXT SOURCES, NETWORK, or SCHEMATIC blocks. Is the source time series specified in one of these blocks? Has it been commented out? If the intended source of this time series is an operation - is that operation commented out in the OPN SEQUENCE block? If the intended source is a PERLND, IMPLND, or RCHRES - is the appropriate module section turned on in the ACTIVITY table?  1 1 1 5 PLTGEN: &I One or more input time series for this PLTGEN are missing. Refer to previous error messages for more help. r $!20000309112939 20000309112939 HWDMUT q  1 1 1 5 WDMS routines not successfully initialized; processing must terminate. Return code = &I @T $!20011211123154 20011211123154 HRCH ^Ȟ~E  20 1 1 5 RCHRES operation &I has no active sections.  20 1 1 5 Section ADCALC of the RCHRES application module must be active if any "quality" sections are active. This condition has been violated.  20 1 1 5 If any of the RQUAL sections of the RCHRES application module are active, then all preceding RQUAL sections must also be active. This condition has been violated.   20 1 1 5 The printout level for the operation listed below is 2; that is, some printout should occur more frequently than daily. In this case, the value of PIVL (specified by the user or by default) must imply a minimum printout interval of one day or an integer fraction thereof. However, this condition has been violated. Operation PDELT (Mins) RCHRES &I &I o@ The remedy is to adjust PIVL (table-type print-info) so that PDELT (=DELT*PIVL) meets the above requirement.   20 1 1 5 The binary output level for the operation listed below is 2; that is, some output should occur more frequently than daily. In this case, the value of BIVL (specified by the user or by default) must imply a minimum printout interval of one day or an integer fraction thereof. However, this condition has been violated. Operation BDELT (Mins) RCHRES &I &Ip@ The remedy is to adjust BIVL (table-type binary-info) so that BDELT (=DELT*BIVL) meets the above requireme $!20000309112939 20000309112939 HRUNTSGDȠ_  20 1 1 5 An error has ocurred converting a WDM-style date to a DSS-style character date. Relevant data are listed below. (Subr. GETDSS) INPTIM RETCOD &I &I &I &I &I &I &I   1 1 1 5An error occurred retrieving &I data points from DSS file number &I .The starting date and time were &CCC &CCCCCCCCCCCCCCCCCCC, and the pathname was &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCThe return code was &I . 9  20 11 0 5A possible problem occurred retrieving &I data points from DSS filenumber &I because missing data was found. The starting date and timewere &CCC &CCCCCCCCCCCCCCCCCCC, and the pathname was: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCThe return code was &I .  1 1 1 5&D A fatal error occurred calculating a position in the INPAD. Relevant data are listed below. (Subr. GETDSS) VOPADR NPTS PLACE SCRSIZ &I &I &I &IjR $!20000309112939 20000309112939 DURANL  R!SF2  16 QS 1 1GEN-DURDATA 101 101 301 301 10 1 1SEASON 102 102 302 302 10 1 1DURATIONS 103 103 303 303 14 1 2LEVELS 104 104 304 304 7 5 2LCONC 105 105 305 305 0 0 0END DURANL 000 000 000 000 d  Select DURANL table(s) to modify. @ GEN-DURDATA @ SEASON @ DURATIONS @ LEVELS @ LCONC@@ Gq Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the DURANL GEN-DURDATA table. ` 1A@ Sl! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the DURANL SEASON table.a 1A@ Do! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the DURANL DURATIONS table. a 1 B@ LE l" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the DURANL LEVELS table.b 1B@ LC k" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the DURANL LCONC table. b 1 DURANL<-----------------title----------------> NDUR NLEV PRFG P- LCNU LCOU x - x UNIT GEN-DURDATA@@FIELD1 " DURANL to which these data apply. OPNID `AAFIELD3 Q!TITLE is the title which the user gives to the durationanalysis operation. TITLE a@AFIELD4 a( 1 J!NDUR is the no. of durations for which the time series willbe analyzed. NDUR BFIELD5 b(1 N"NLEV is the no. of "levels" which will be used in analyzingthe time series. NLEV BFIELD6 b(1 ހ"PRFG is a flag which governs the quantity of informationprinted out. A value of 1 results in minimal (basic)output. Increasing the value (up to the maximum of 7)results in increased detail of output. PRFG RTCFIELD7 c(c6 p#PUNIT is the Fortran unit no. to which the (printed) outputof the duration analysis operation will be routed.PUNIT CFIELD8 c(0 #LCNUM indicates the number of lethal concentration curvesto be used in the analysis. A zero means no LC analysis isto be performed. LCNUM DFIELD9 d(0 ^$LCOUT is a flag which governs the printout of intermediatelethal event information (1-on). LCOUT -General information for durational analysis. t (1X,10A4,6I10)Title of display NDUR NLEV PRFG PUNIT LCNUM LCOUT^ DURANL Start End x - x mo da hr mn mo da hr mn  SEASON @@FIELD1 " DURANL to which these data apply. OPNID `QAFIELD3 a 1 !Allow this value to default. SESON1 AFIELD4 a 1 6!SMON is the starting month for the "analysis season". SESON2 BFIELD5 b1 4"SDAY is the starting day for the "analysis season".SESON3 BFIELD6 b0 6"SHOUR is the starting hour for the "analysis season". SESON4 CFIELD7 c;0 7#SMIN is the starting minute for the "analysis season". SESON5 CFIELD8 c 1 #Allow this value to default. SESOE1 DFIELD9 d 12 4$EMON is the ending month for the "analysis season".SESOE2 DFIELD10d31 2$EDAY is the ending day for the "analysis season". SESOE3 EFIELD11e24 ^%EHOUR is the ending hour for the "analysis season".Default value is 24 only if EMIN is zero. SESOE4 EFIELD12e;0 5%EMIN is the ending minute for the "analysis season". SESOE5 ,Information for seasonal duration analysSUis.^ (1X,2(4X,I4,2('/',I2),I3,':',I2)) Analysis season Start date/time End date/time H DURANL <---Durations--------> x - x 1 2 3 4 5 DURATIONS @@FIELD1 " DURANL to which these data apply. OPNID `QAFIELD3 a(1 !DURAT(*) is an array which contains the NDUR differentdurations for which the time series will be analyzed (NDURwas specified in Table-type GEN-DURDATA). The durations areexpressed in multiples of the internal time step specifiedin the OPN SEQUENCE Block (Section 4.3). The analysisalgorithm requires that the first duration be 1 time step,but the others can have any value. DURAT1 AFIELD4 a(2 DURAT2 BFIELD5 b(2 DURAT3 BFIELD6 b(2 DURAT4 CFIELD7 c(2 DURAT5 CFIELD8 c(2 DURAT6 DFIELD9 d(2 DURAT7 DDFIELD10d(2 DURAT8 EFIELD11e(2 DURAT9 EFIELD12e(2 DURA10 8Table of durations to be used in the duration analysis.+ (1X,10I10)Durations, in multiples of DELT  DURANL x - x 2 3 4 5 6 7 8 9 10 11 12 13 14 15 x - x 16 17 18 19 20 21  LEVELS @@FIELD1 " DURANL to which these data apply. OPNID `QAFIELD3 a(yy0. I!LEVEL(2thru21) contains the 20 possible "levels" for whichthe input time series will be analyzed. (LEVEL(1) andLEVEL(22) are reserved for system use and this does notaffect the user since he can only specify LEVEL(2thru21)).The actual no. of levels (NLEV) was specified by the user inTable-type GEN-DURDATA. LEVEL2 AFIELD4 a(yy0. LEVEL3 BFIELD5 b(yyT0. LEVEL4 BFIELD6 b(yy0. LEVEL5 CFIELD7 c(yy0. LEVEL6 CFIELD8 c(yy0. LEVEL7 DFIELD9 d(yy0. LEVEL8 DFIELD10d(yy0. LEVEL9 EFIELD11e(yy0. LEVE10 EFIELD12e(yy0. LEVE11 FFIELD13f(yy0. LEVE12 FFIELD14f(yy0. LEVE13 GFIELD15g(yy0. LEVE14 GFIELD16g(yy0. LEVE15 ,Levels to be used in the duration analysis.: (1X,10(1PE10.3),/,1X,10(1PE10.3))Levels for the analysis  DURANL x - x LC1 LC2 LC3 LC4 LC5 LC6 LC7 x - x LC8 LC9 LC10  LCONC @@FIELD1 " DURANL to which these data apply. OPNID `AAFIELD3 aPyy0. !LCONC(1-10) is an array which contains the NDUR differentlethal levels which are used in a lethal concentrationanalysis. LCONC1 AFIELD4 aPyy0. LCONC2 BFIELD5 bPyy0. LCONC3 BFIELD6 bPyy0. LCONC4 CFIELD7 cPyy0. LCONC5 CFIELD8 cPyy0. LCONC6 DFIELD9 dPyy0. LCONC7 Lethal concentrations to be used in the duration analysis.Repeats for each lethal concentration curve-LCNUM times.If no lethal analysis is being done, this table may be omitted. (1X,10(1PE10.3))Lethal levels W YMIN YMAX IVLIN THRESH (ivl/in)f Plot-opn Curve label Line Intg Col Tran x - x type eqv code code CURV-DATA @@FIELD1 " PLTGEN to which these data apply. OPNID `QAFIELD3 e!LABEL is the label (descriptor) for this particular curve. It is alsoused in the FEQ DTSF header. LABEL aAFIELD4 a(0 J!LINTYP describes the type of line to be drawn for thiscurve. It also determines the frequency of plotted symbols:A zero value means points are connected by straight lines;no symbols are drawn at individual data points. A positivevalue means points are connected by straight lines; themagnitude determines the frequency of plotted symbols (eg. 4means plot a symbol at every 4th point obtained from theplot file). A negative value means no connecting lines aredrawn. Only symbols are plotted; the absolute valuedetermines the frequency (as above). LINTYP BFIELD5 b( 0 "INTEQ is the "integer equivalent" of the symbols to beplotted for this curve (ie. indicates which symbol to use).It is only meaningful if LINTYP is not zero. INTEQ BFIELD6 b( 0 "COLCOD is the color code for this curve. The meaningdepends on how the stand-alone plot program is set up; eg. 1might mean red pen, 2 blue pen, etc. COLCOD CFIELD7 c SUM ,AVER,MAX ,MIN ,LAST SUM#TRAN is the "transformation code" used to aggregate datafrom the basic interval (internal time step) to the PLOTFLInterval. Valid values are: SUM, AVER, MAX, MIN, and LAST. TRAN GData for each curve on the plot. Repeats for each curveon the plot. T (1X,4A4,4X,3I10,6X,A4)Curve label: LINTYP INTEQ COLCOD TRANXVh) to be aggregated to get to the interval of the datawritten to the PLOTFL. A PIVL of -1 causes a monthly file tobe written. A PIVL of -2 causes an annual file to be written. PIVL DFIELD9 d(1 A$TYPEFG specifies the type of output file created. 1 means a formattedtext file containing up to 10 timeseries (PLTGEN/MUTSIN format).2 means an unformatted file containing up to 99 mean-valued timeseries(FEQ DTSF format). 3 means an unformatted file containing exactly onepoint-valued timeseries (FEQ PTSF format). TYPEFG General plot information. Q (1X,7I10) PLOTFL NPT NMN LABLFG PYREND PIVL TYPEFG PPlot-opn x - x General title Y-axis label GEN-LABELS @@FIELD1 " PLTGEN to which these data apply. OPNID `AAFIELD3 K!TITLE is the general plot title. It is also used in the FEQ DTSF header. TITLE a@AFIELD4 0!YLABL is the label to be placed on the Y-axis.YLABL aGeneral plot labels. \ (1X,10A4,20X,5A4)General plot title: Y-axis label:\ Plot-opn YMIN YMAX IVLIN THRESH x - x ivl/in SCALING@@FIELD1 " PLTGEN to which these data apply. OPNID `QAFIELD3 aPyy0. .!YMIN is the minimum ordinate (Y axis) value. YMIN AFIELD4 aPyy-999. %!YMAX is the maximum ordinate value. YMAX BFIELD5 bPy-999. i"IVLIN is the horizontal (time) scale; that is, number ofintervals (in plot file) per inch on graph. IVLIN BFIELD6 bPyy-1.0E30"THRESH is the write threshhold value. If the value for anycurve is greater than the threshhold, a record is written tothe plotfile.THRESH Scaling information for plots. X (1X,4(1PE10.3)) YW 1 1PLOTINFO 101 101 301 301 15 1 1GEN-LABELS 102 102 302 302 4 1 2SCALING 103 103 303 303 8 99 1CURV-DATA 104 104 304 304 0 0 0END PLTGEN 000 000 000 000 \  Select PLTGEN table(s) to modify. @ PLOTINFO @ GEN-LABELS @ SCALING @ CURV-DATA@@ Pn Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PLTGEN PLOTINFO table. ` 1A@ Gp! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PLTGEN GEN-LABELS table.a 1A@ Sm! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PLTGEN SCALING table. a 1 B@ Co" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the PLTGEN CURV-DATA table. b 19 Plot-opn x - x FILE NPT NMN LABL PYR PIVL TYPE PLOTINFO @@FIELD1 " PLTGEN to which these data apply. OPNID `QAFIELD3 a(c30 Q!PLOTFL is the Fortran unit number of the plot file (outputof this operation). PLOTFL AFIELD4 a(0 F!NPT is the number of point-valued time series to beplotted. NPTBFIELD5 b(c0 ="NMN is the number of mean-valued time series to be plotted. NMNBFIELD6 b(0 "LABLFG indicates how the plot will be labeled: -1 means nolabels, 0 means one set of X and Y axes and associatedlabels will be drawn for entire plot, and 1 means separate Xand Y axes and labels will be drawn for each "frame" of theplot (eg. each water year).LABLFG CFIELD7 c( 9 R#PYREND is the calendar month which terminates a plot frame(eg. a water year). PYREND CFIELD8 c(1 #PIVL is the number of basic time intervals (DELT minuteseacX} $!20000607144923 20000607144923 PLTGEN  E4ѭ  6 ~[j -SWW[_20000309112939 20000309112939 BCATTR S  1 AREA 11 DAREA x 2 CONTDA 43 CONTDA x 3 SLOPE 24 SLOPE x 4 BSLOPE 86 BSLOPE x 5 LENGTH 26 LENGTH x 6 BLENGTH 87 BLNGTH x 7 VALLGH 88 VALLGH x 8 ELEV 7 ELEV x 9 ELV10,85 89 EL1085 x 10 EL5000 90 EL5000 x 11 EL6000 91 EL6000 x 12 STORAGE 59 STORAG x 13 LAKEAREA 92 LAKE x 14 FOREST 61 FOREST x 15 GLACIER 93 GLACER x 16 SOIL INF 62 SOILIN x 17 LOESS 94 LOESS x 18 AZIMUTH 95 AZMUTH x 19 LAT 96 LATCTR x 20 LONG 97 LNGCTR x 21 TIMETOPK 98 TMTOPK x 22 LAT GAGE 8 LATDEG x 23 LNG GAGE 9 LNGDEG x 24 220 UBC024 x 25 221 UBC025 x 26 222Z\ UBC026 x 27 223 UBC027 x 28 224 UBC028 x 29 225 UBC029 x 30 226 UBC030 x 31 227 UBC031 x 32 PRECIP 58 PRECIP x 33 I24,2 63 I24-2. x 34 I24,10 99 I24010 x 35 I24,25 100 I24025 x 36 I24,50 101 I24050 x 37 I24,100 102 I24100 x 38 228 UBC038 x 39 229 UBC039 x 40 230 UBC040 x 41 PRC10 103 PRCOCT x 42 PRC11 104 PRCNOV x 43 PRC12 105 PRCDEC x 44 PRC1 106 PRCJAN x 45 PRC2 107 PRCFEB x 46 PRC3 108 PRCMAR x 47 PRC4 109 PRCAPR x 48 PRC5 110 PRCMAY x 49 PRC6 111 PRCJUN x 50 PRC7 112 PRCJUL x 51 PRC8 113 PRCAUG x 52 PRC9 114 PRCSEP x 53 SNOFALL 115 SNOFAL x 54 SNOMAR 116 SNOMAR x 55 SNOAPR 117 SNOAPR x 56 SN2 118 SN002 x 57 SN10 119 SN010 x 58 SN25 120 SN025 x 59 SN100 121 SN100 x 60 JANMIN 64 JANMIN x 61 JANAV 122 JANAVE x 62 MARMAX 123 MARMAX x 63 JULYMAX 124 JULMAX x 64 JULYAV 125 JULAVE x 65 WE MAR2 126 WEMAR2 x 66 231 UBC066 x 67 232 UBC067 x 68 233 UBC068 x 69 234 UBC069 x 70 EVAP 127 LKEVAP x 71 EVAPAN 128 PNEVAP x 72 FROST 129 FROST x 73 235 UBC073 x 74 236 UBC074 x 75 P1,25 65 P1.25 x 76 P2 66 P2. x 77 P5 67 P5. x 78 P10 68 P10. x 79 P25 69 P25. x 80 P50 70 P50. x 81 P100 71 P100. x 82 P200 72 P200. x 83 MEANPK 74 MEANPK x 84 SDPK 75 SDPK x 85 SKEWPK 76 SKWPK x 86 QA 130 QANN x 87 SDQA 131 QSDANN x 88 Q10 132 QOCT x 89 Q11 133 QNOV x 90 Q12 134 QDEC x 91 Q1 135 QJAN x 92 Q2 136 QFEB x 93 Q3 137 QMAR x 94 Q4 138 QAPR x 95 Q5 139 QMAY x 96 Q6 140 QJUN x 97 Q7 141 QJUL x 98 Q8 142 QAUG x 99 Q9 143 QSEP x 100 SDQ10 144 QSDOCT x 101 SDQ11 145 QSDNOV[] x 102 SDQ12 146 QSDDEC x 103 SDQ1 147 QSCJAN x 104 SDQ2 148 QSDFEB x 105 SDQ3 149 QSDMAR x 106 SDQ4 150 QSDAPR x 107 SDQ5 151 QSDMAY x 108 SDQ6 152 QSDJUN x 109 SDQ7 153 QSDJUL x 110 SDQ8 154 QSDAUG x 111 SDQ9 155 QSDSEP x 112 M1,2 156 L01002 x 113 M1,10 157 L01010 x 114 M1,20 158 L01020 x 115 M3,2 159 L03002 x 116 M3,10 160 L03010 x 117 M3,20 161 L03020 x 118 M7,2 162 L07002 x 119 M7,5 163 L07005 x 120 M7,10 164 L07010 x 121 M7,20 165 L07020 x 122 M14,2 166 L14002 x 123 M14,10 167 L14010 x 124 M14,20 168 L14020 x 125 M30,2 169 L30002 x 126 M30,10 170 L30010 x 127 M30,20 171 L30020 x 128 M90,2 172 L90002 x 129 M90,10 173 L90010 x 130 M90,20 174 L90020 x 131 V1,100 181 H01100 x 132 V15,5 197 H15005 x 133 V30,5 204 H30005 x 134 V30,20 206 H30020 x 135 V30,100 209 H30100 x 136 V1,2 175 H01002 x 137 V1,5 176 H01005 x 138 V1,10 177 H01010 x 139 V1,20 178 H01020 x 140 V1,25 179 H01025 x 141 V1,50 180 H01050 x 142 V3,2 182 H03002 x 143 V3,5 183 H03005 x 144 V3,10 184 H03010 x 145 V3,20 185 H03020 x 146 V3,25 186 H03025 x 147 V3,5 187 H03050 x 148 V3,100 188 H03100 x 149 V7,2 189 H07002 x 150 V7,5 190 H07005 x 151 V7,10 191 H07010 x 152 V7,20 192 H07020 x 153 V7,25 193 H07025 x 154 V7,50 194 H07050 x 155 V7,100 195 H07100 x 156 V15,2 196 H15002 x 157 V15,10 198 H15010 x 158 V15,20 199 H15020 x 159 V15,25 200 H15025 x 160 V15,50 201 H15050 x 161 V15,100 202 H15100 x 162 V30,2 203 H30002 x 163 V30,10 205 H30010 x 164 V30,25 207 H30025 x 165 V30,50 208 H30050 x 166 237 UBC166 x 167 238 UBC167 x 168 DEPH25 210 DEPH25 x 169 239 UBC169 x 170 240 UBC170 x 171 D95 211 QEX95P x 172 D90 212 QEX90P x 173 D75 213 QEX75P x 174 D70 214 QEX70P x 175 D50 215 QEX50P x 176 D25 216 QEX25P x 177\^ D10 217 QEX10P x 178 P500 73 P500. x 179 WRC SKEW 77 WRCSKW x 180 WRC MEAN 78 WRCMN x 181 WRC SD 79 WRCSD x 182 241 UBC182 x 183 242 UBC183 x 184 243 UBC184 x 185 244 UBC185 x 186 245 UBC186 x 187 246 UBC187 x 188 247 UBC188 x 189 248 UBC189 x 190 249 UBC190 x 191 250 UBC191 x 192 251 UBC192 x 193 252 UBC193 x 194 253 UBC194 x 195 254 UBC195 x 196 YRSPK 80 YRSPK x 197 YRSHISPK 81 YRSHPK x 198 YRSDAY 218 YRSDAY x 199 YRSLOW 219 YRSLOW x 200 255 UBC200 x XLOC 1 x-sect location, feet from right bank looking upstream XXLOC 2 x-sect location, percent from right bank looking upstream XDPTH 3 sampling depth (feet) XWDTH 4 stream width (feet) XXLOC 5 x-section location, vertical (percent of total depth) XXLOC 9 x-section location, feet from left bank looking downstream XTH20 10 temperature, water (deg. C) XTPAH 12 temperature, evaporation, 48 in. pan (deg. C) XTPAN 13 temperature, evaporation, 24 in. pan (deg. C) XTWTB 14 temperature, wet bulb (deg. C) XTEMP 20 temperature, air (deg. C) XBPRS 25 barometric pressure (mm of hg) XSRAD 30 solar radiation, incidental, intensity (calories/sq cm/day)XWNDS 35 wind speed (mph) XWNDD 36 wind direction, in degrees from true north (clockwise) XPREC 45 rainfall, accumulated (inches) XEVAP 50 evaporation, total (inches per day) XHUMD 52 humidity, relative (percent) XRESV 54 reservoir storage (ac-ft) ] XSVEL 55 stream velocity (feet per second) XFLOW 60 discharge, in cubic feet per second X Z 65 gage height (feet above datum) XTURB 70 (jtu) XTURB 76 (ntu) XCOLR 80 (platinum-cobalt units) XOXPT 90 oxidation reduction potential (millivolts) XSPCD 95 specific conductance, micro siemens/centimeter at 25 deg. CX `ta has been defined. Thus, no editing of Mass-link information may be performed. 8  Which Mass-link table do you want to modify? @MLT @@MLT ` Only one record exists in this Mass Link table, and deleting aMass Link table has not yet been implemented. Thus, this record cannot be dropped from the Mass Link table. a_ subscript.TMEMS1 DFIELD8 dc0 %$Target member name second subscript. TMEMS2 In the SCHEMATIC block the user specifies the global linkages of landsegments with stream reaches and between stream reaches.  <-Volume-> <-Grp> <-Member-><--Mult--> Tran<-Target vols> <-Grp> <-Member->Ac x x<-factor-> strg x x MASS-LINK @@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 a0?PERLND,IMPLND,RCHRES,COPY ,PLTGEN,DISPLY,DURANL,GENER ,MUTSIN "!Operation-type of the source opn. SVOL AFIELD2 /!Group to which the source time series belongs. SGRPN a0BFIELD3 _"Source member name. Default: all members. Refer to Time SeriesCatalogue for more information. SMEMN b0BFIELD4 bc0 $"Source member name first subscript.SMEMS1 CFIELD5 cc0 %#Source member name second subscript. SMEMS2 CFIELD6 cPyy1. ^#The factor by which data from the source will be multiplied beforebeing added to the target. MFACTR DFIELD7 d0?PERLND,IMPLND,RCHRES,COPY ,PLTGEN,DISPLY,DURANL,GENER ,MUTSIN $Operation-type of the target. TVOL DFIELD10/$Group to which the target time series belongs. TGRPN d0EFIELD11_%Target member name. Default: all members. Refer to Time SeriesCatalogue for more information. TMEMN e0EFIELD12ec0 $%Target member name first subscript.TMEMS1 FFIELD13fc0 %&Target member name second subscript. TMEMS2 In the MASS-LINK block the user specifies those time series connections whichwill be combined with the linkages in the SCHEMATIC block to generate a setof time series connections in the NETWORK block. { For the UCI file in use, no Mass-link dab` EFIELD10e '-999 %Dataset Number.TVOLNO FFIELD11)&Dataset name or dataset TSTYP attribute. TMEMN f0FFIELD12f0 g&Quality-of-data (TVOL=WDM); specifies the quality tag to beattached to data placed in a WDMS dataset. QLFG GFIELD13g  ENGL,METR ENGL 2'Unit system of data to be written to WDM dataset. TSYST GFIELD14gAGG,DEF 'String indicating whether the data should be aggregated when placedin a WDMS dataset having a timestep greater than the source timestep.Valid value is AGG; default value is no aggregation. AGGST HFIELD15h ADD,INS,REP(String indicating how the target dataset is to be accessed. Validvalues are: ADD, INS, and REP for the TSS file; and ADD or REPfor a WDMS file. AMDST vIn the EXTERNAL TARGETS block the user specifies those time series whichwill be output from the operations in a RUN. y <-Volume-> <--Area--> <-Volume-> Ac x <-factor-> x SCHEMATIC @@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 a0?PERLND,IMPLND,RCHRES,COPY ,PLTGEN,DISPLY,DURANL,GENER ,MUTSIN "!Operation-type of the source opn. SVOL AFIELD2 a -999 !Source Operation-type No. SVOLNO BFIELD3 bPyy1. ^"The factor by which data from the source will be multiplied beforebeing added to the target. MFACTR BFIELD4 b0?PERLND,IMPLND,RCHRES,COPY ,PLTGEN,DISPLY,DURANL,GENER ,MUTSIN "Operation-type of the target. TVOL CFIELD5 c -999 #Target Operation-type No. TVOLNO CFIELD6 c -999 %#MLID is the associated Mass Link No. MLID DFIELD7 dc0 $$Target member name firstcaTOPFST is the first target Operation-type No. TOPFST FFIELD11f0 -&TOPLST is the last target Operation-type No. TOPLST FFIELD12/&Group to which the target time series belongs. TGRPN f0GFIELD13_'Target member name. Default: all members. Refer to Time SeriesCatalogue for more information. TMEMN g0GFIELD14gc1 $'Target member name first subscript.TMEMS1 HFIELD15hc1 %(Target member name second subscript. TMEMS2 In the NETWORK block the user specifies those time series whichwill be passed between operations via the internal scratch pad. <-Volume-> <-Grp> <-Member-><--Mult-->Tran <-Volume-> Tsys Agg AmdAc x x x<-factor->strg x qf tem stg stg EXT TARGETS@@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 a0?PERLND,IMPLND,RCHRES,COPY ,PLTGEN,DISPLY,DURANL,GENER ,MUTSIN "!Operation-type of the source opn. SVOL AFIELD2 a -999 !Source Operation-type No. SVOLNO BFIELD3 /"Group to which the source time series belongs. SGRPN b0BFIELD4 _"Source member name. Default: all members. Refer to time seriescatalogue for more information. SMEMN b0CFIELD5 cc1 $#Source member name first subscript.SMEMS1 CFIELD6 cc1 %#Source member name second subscript. SMEMS2 DFIELD7 dPyy1. ^$The factor by which data from the source will be multiplied beforebeing added to the target. MFACTR DFIELD8 d* ,SAME,AVER,DIV ,INTP,LAST,MAX ,MIN ,SUM ,DEFj$String indicating which transformation function to use intransferring time series from source to target. TRAN EFIELD9 e0?WDID %External target volume.TVOLdbD12/&Group to which the target time series belongs. TGRPN f0GFIELD13]'Target member name. Default: all members. Refer to Time Series Catalogfor more information. TMEMN g0GFIELD14gc1 $'Target member name first subscript.TMEMS1 HFIELD15hc1 %(Target member name second subscript. TMEMS2 In the EXTERNAL SOURCES block the user specifies those time series whichare to be supplied to operations in a RUN from sources external to it.$ Formats option not yet implemented. <-Volume-> <-Grp> <-Member-><--Mult-->Tran <-Target vols> <-Grp> <-Member->Ac x x x<-factor->strg x x x x  NETWORK@@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 a0?PERLND,IMPLND,RCHRES,COPY ,PLTGEN,DISPLY,DURANL,GENER ,MUTSIN "!Operation-type of the source opn. SVOL AFIELD2 a -999 !Source Operation-type No. SVOLNO BFIELD3 /"Group to which the source time series belongs. SGRPN b0BFIELD4 _"Source member name. Default: all members. Refer to Time SeriesCatalogue for more information. SMEMN b0CFIELD5 cc1 $#Source member name first subscript.SMEMS1 CFIELD6 cc1 %#Source member name second subscript. SMEMS2 DFIELD7 dPyy1. ^$The factor by which data from the source will be multiplied beforebeing added to the target. MFACTR DFIELD8 d ,SAME,AVER,DIV ,INTP,LAST,MAX ,MIN ,SUM ,DEFj$String indicating which transformation function to use intransferring time series from source to target. TRAN EFIELD9 e0?PERLND,IMPLND,RCHRES,COPY ,PLTGEN,DISPLY,DURANL,GENER ,MUTSIN %Operation-type of the target. TVOL EFIELD10e-999 .%ec table.a No + - I want to return to the previous screen.  <-Volume-> SsysSgap<--Mult-->Tran <-Target vols> <-Grp> <-Member->Ac x x tem strg<-factor->strg x x x x EXT SOURCES@@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 a0?WDID !External source volume.SVOL AFIELD2 a '-999 B!Dataset No. (TVOL = TSS or WDM); or Fortran unit No. (TVOL = SEQ) SVOLNO BFIELD3 "Dataset name (TVOL = TSS); or Dataset TSTYP attribute (TVOL = WDM).SFCLAS is a string indicating the class of format used in thesequential file. SMEMN b0BFIELD4 b0 "Quality-of-data flag (SVOL = WDM); specifies the minimum qualityWDMS data which will be accepted by HSPF; valid values = 0-31.Identifies an object-time format supplied in the FORMATS Block.QLFG CFIELD5 c  ENGL,METR ENGL S#Unit system of data in the source (SVOL = SEQ or WDM); valid valuesENGL and METR. SSYST CFIELD6 c ZERO,UNDF,DEF #String indicating how missing "cards" in the sequential file, orWDMS data having insufficient 'quality' will be regarded. Used inSVOL=SEQ or WDM.SGAPST DFIELD7 dPyy1. ^$The factor by which data from the source will be multiplied beforebeing added to the target. MFACTR DFIELD8 d ,SAME,AVER,DIV ,INTP,LAST,MAX ,MIN ,SUM, DEFd$String indicating which transformation function to use in transftime series from source to target.TRAN EFIELD9 e0?PERLND,IMPLND,RCHRES,COPY ,PLTGEN,DISPLY,DURANL,GENER ,MUTSIN "%Operation-type of the target opn. TVOL EFIELD10e-999 .%TOPFST is the first target Operation-type No. TOPFST FFIELD11f0 -&TOPLST is the last target Operation-type No. TOPLST FFIELfdSpecial actions block. Note that the value must be given in the unitsused internally for the quantity concerned, because no conversion isperformed when it is read in. Ac  CATEGORIES BLOCK @@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 !Category Numbera!AFIELD2 !Category Name a vThe CATEGORIES block associates a category name with a number for usein keeping track of categories in a simulation. < An error occurred while reading this record as a name line. Only one name exists in this user defined name statement, and atleast one name must exist at all times. Thus, this name cannot be dropped from the list. Only the first 100 records of this typecan be edited within this program. Additional records will have to be edited using a text editor.Ac  MONTH-DATA BLOCK @@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 !Month data heading aaAFIELD2 !Month data id aBFIELD3 b The MONTH-DATA block. Y dss f <--type> Ac dsn l  PATHNAMES BLOCK@@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 a '!DSS DSNAFIELD2 !DSS file aBFIELD3 "DSS data type b@BFIELD4 "DSS data path bThe PATHNAMES block. } For the UCI file in use this operation has not been defined. Thus, no editing of this operation's tables may be performed. 3 This block does not exist. Do you want to add it? @ 4` Yes - I want to add this block.a No + - I want to return to the previous screen. 3 This table does not exist. Do you want to add it? @ 4` Yes - I want to add thisgehis type exist. Do you want to add one? @ 4` Yes% - I want to add this type of record. a No + - I want to return to the previous screen. OAc <------------fname----------------------------------------> FILES BLOCK@@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 !File Type FTYPE a0AFIELD2 a-999 !File Unit Number FUNIT BFIELD3 "File Name FNAME baThe FILES block contains the names of input and output files usedby the program during the run. No logical connector ('or' or 'and') was specified for a conditionother than the last condition. Every condition except the lastcondition must end with a logical connector. Thus, this series of conditions is invalid. A logical connector ('or' or 'and') was specified for the lastcondition. The last condition cannot end with a logical connector. Thus, this condition is invalid. An error occurred while reading this record as an action line. If this line is actually a secondary line of a conditional it canbe modified by specifying the first line of this conditional. *User-Defined/Multiple Variable Lines* actAction <1><2><3> < > SPEC-ACTIONS @@FIELD0 ` NONE,DROP,COPY .  Action to take for this line: none,drop,copy AFIELD4 !Actual variable name. VNAME a0AFIELD5 a0 !First subscript for VNAME. NSUB BFIELD6 b0 "Second subscript for VNAME.NSUB BFIELD7 b0 "Third subscript for VNAME. NSUB CFIELD8 J#Fractions of total application allocated to each of the actual variables. FRAC c#(CFIELD9 c QUAN,MOVT,MOV1,MOV2QUAN #Action code. ACTCD hfity concerned, because no conversion isperformed when it is read in. |  Specify type of conditional desired: [@] 'IF' [@] 'ELSE' [@] 'ELSE_IF' [@] 'END_IF' @@] 'IF'` 8 _ONOFF @] 'ELSE'_ONOFF @] 'ELSE_IF'_ONOFF @] 'END_IF'4 Toggle this option on if this is an 'if' condition. A@] 'ELSE' a 6 _ONOFF @] 'IF'_ONOFF @] 'ELSE_IF'_ONOFF @] 'END_IF' 6! Toggle this option on if this is an 'else' condition. A@] 'ELSE_IF' a  3 _ONOFF @] 'IF'_ONOFF @] 'ELSE'_ONOFF @] 'END_IF' 9! Toggle this option on if this is an 'else if' condition. B@] 'END_IF'b 4 _ONOFF @] 'IF'_ONOFF @] 'ELSE'_ONOFF @] 'ELSE_IF'8" Toggle this option on if this is an 'end if' condition.) Specify the type of conditional desired. ` -------Special Action Conditions-------Action ppp ppp @FIELD0 ` NONE,DROP,COPY 3  Action to take for this condition: none,drop,copy AFIELD1 a{,[,(,B2! Parens, brackets, braces, or 'B' to leave blank. AFIELD2 a{,[,(,B2! Parens, brackets, braces, or 'B' to leave blank. BFIELD3 b{,[,(,B2" Parens, brackets, braces, or 'B' to leave blank. BFIELD4 " First quantity of conditional.b PCFIELD5 c =, !=, >, >=, <, <=# Compare operator. CFIELD6 !# Second quantity of conditional. cPDFIELD7 d},],),B2$ Parens, brackets, braces, or 'B' to leave blank. DFIELD8 d},],),B2$ Parens, brackets, braces, or 'B' to leave blank. EFIELD9 e},],),B2% Parens, brackets, braces, or 'B' to leave blank. EFIELD10e AND, OR, BLNK % Logical operator. For the UCI file in use, no Special Actions recordsof this type have been defined. Thus, no editing of this type of Special Actionsrecord may be performed.E No SPEC-ACTIONS records of tigable logic fails. C@TST c1 0# Number of CTCODE intervals to defer the action.D@DAT1 d0 -$ Year in which special action is to be taken. D@DA2 d 1 .$ Month in which special action is to be taken. E@DA3 e1 ,% Day on which special action is to be taken.E@DA4 e0 -% Hour at which special action is to be taken. F@DA5 f;0 /& Minute at which special action is to be taken. F@DSf20 P& ID number of distribution line that contains informationdefining distribution.G@TYg3 A' Variable or array element type: 2-INTEGER, 3-REAL, 4-DOUBLE PREC G@VNAME.&' Variable to act upon, left-justified. gH@NS1 h0 -( First subscript for VNAME, 0 if none exists. H@NS2 h0 .( Second subscript for VNAME, 0 if none exists. I@NS3 i0 -) Third subscript for VNAME, 0 if none exists. I@ACT i$1,2,3,4,5,6,7,=,+=,-=,*=,/=,MIN,MAX) Action code: 1 or = reset 4 or *= multiply 7 or MAX maximum 2 or += increment 5 or *= divide 3 or -= decrement 6 or MIN minimum J@RVAL......* This field contains quantitative data for the action to be takenIf the variable or array element to be acted on is an integer (Tvalue is read as an integer (IVAL); If it is REAL (TYPCOD=3 or 4is read as a real number (RVAL).jJ@RTU jYR,MO,DY,HR,MI MI * Code for repeat time units. K@RTS k1 .+ Time step at which to repeat special action. K@RIN k1 C+ Number of increments for which special action should be repeated. Special actions block. Note that the value must be given in the unitsused internally for the quantjhse variable. TSTEP FFIELD13fMI,HR,DY,MO,YR MI E&Code specifying time units of the period to aggregate base variable. CTCODE GFIELD14g1 7'Number of CTCODE intervals to aggregate base variable. TSTEP GFIELD15g SUM,AVER,MAX,MIN SUMA'Transformation function to use for aggregation of base variable. CTCODE Special actions block. Note that the value must be given in the unitsused internally for the quantity concerned, because no conversion isperformed when it is read in. % Modify parameters as desired for this special action: [@] Dated or [@] Undated Time Time ---------Date of Action-------- Dist Oper type Range units step Year Month Day Hour Minute ID [@OPTYP] [@FST][@LST] [@CT] [@TST] [@DAT1][@DA2][@DA3][@DA4][@DA5] [@DS] ----------Variable info----------- Action ---Repeat Time---- Type Name ----Subscripts---- code Value Units Step Intvl [@TY] [@VNAME.] [@NS1][@NS2][@NS3] [@ACT] [@RVAL......] [@RTU][@RTS][@RIN] @@] Dated ` $ _ONOFF @] Undated_OFFON @] Undated OFF @CT 4 26 6 30  OFF @TST 4 32 6 37  OFF @DAT1 4 40 6 46 OFF @DA2 4 47 6 52  OFF @DA3 4 53 6 58  OFF @DA4 4 59 6 64  OFF @DA5 4 65 6 70  OFF @DS 4 73 6 77  OFF @RTU 8 60 10 65 OFF @RTS 8 66 10 71 OFF @RIN 8 72 10 77< Toggle this option on if the special action is to be dated. A@] Undated a  _ONOFF @] Dated_OFFON @] Dated>! Toggle this option on if the special action is to be undated. A@OPTYP a'PERLND,IMPLND,RCHRES,COPY,PLTGEN,GENER ! Operation type.B@FST b-999 " First operation to act upon. B@LST b0 >" Last operation to act upon, 0 means use first operation only. C@CTc MI,HR,DY MI 2# Time units of action when applickiam>< > <1><2><3> < > <1><2><3> < > SPEC-ACTIONS @@FIELD0 ` NONE,DROP,COPY,***,MODI?  Action to take for this record: none,drop,copy,comment,modify AFIELD1 !User-defined variable name.UVNAME a 0AFIELD2 #!User-defined variable name record. aSpecial actions block. Note that the value must be given in the unitsused internally for the quantity concerned, because no conversion isperformed when it is read in. *User-Defined Variable Quantity Lines* lc ls ac as agfnAction <#> <1><2><3> <>< > <>< > < > SPEC-ACTIONS @@FIELD0 ` NONE,DROP,COPY,*** 8  Action to take for this record: none,drop,copy,commentAFIELD2 %!User-defined variable quantity name. UVQNAM a0AFIELD3 a0'PERLND,IMPLND,RCHRES,COPY,PLTGEN,GENER X!Operation type of base variable, or GLOBAL if base variable is in theglobal workspace.OPTYP BFIELD4 b^"Operation type number of base variable, or blank if base variableis in the global workspace. OPTNO BFIELD5 I"Actual variable name of base variable, or WORKSP is in global workspace. VNAME b0CFIELD6 c0 )#First subscript for VNAME, zero if none. NSUB CFIELD7 c0 *#Second subscript for VNAME, zero if none. NSUB DFIELD8 d0 )$Third subscript for VNAME, zero if none. NSUB DFIELD9 d3 '$2-integer, 3-real, 4-double precision. TYPCOD EFIELD10e,Pyy1.0&%Multiplier to apply to base variable. UVQMUL EFIELD11eMI,HR,DY,MO,YR MI ?%Code specifying time units of the period to lag base variable. CTCODE FFIELD12f0 1&Number of CTCODE intervals to lag baljsponds to the value specified on the standard line.DSIND AFIELD3 a -999 Q!Number of separate actions or applicationsto divide the total application into. CNTBFIELD4 bMI,HR,DY,MO,YR MI U"Code specifying time units of the interval betweenseparate applications or actions. CTCODE BFIELD5 b-999 :"Number of CTCODE intervals between separate applications. TSTEP CFIELD6 c(SKIP,SHIFT,ACCUM SKIP `#Deferral flag - indicates how to treat deferral of the action(s) undera conditional situation.CDEFFG CFIELD7 c(yy0.01#Fractions for each of the separate applications. FRACT DFIELD8 d"(yy0.01$Fractions for each of the separate applications. FRACT DFIELD9 d'(yy0.01$Fractions for each of the separate applications. FRACT EFIELD10e,(yy0.01%Fractions for each of the separate applications. FRACT EFIELD11e1(yy0.01%Fractions for each of the separate applications. FRACT FFIELD12f6(yy0.01&Fractions for each of the separate applications. FRACT FFIELD13f;(yy0.01&Fractions for each of the separate applications. FRACT GFIELD14g@(yy0.01'Fractions for each of the separate applications. FRACT GFIELD15gE(yy0.01'Fractions for each of the separate applications. FRACT HFIELD16hJ(yy0.01(Fractions for each of the separate applications. FRACT Special actions block. Note that the value must be given in the unitsused internally for the quantity concerned, because no conversion isperformed when it is read in. *User-Defined/Multiple Variable Lines* cnt act actAction < > <> < > SPEC-ACTIONS @@FIELD0 ` NONE,DROP,COPY,*** 8  Action to take for this record: none,drop,copy,commentAFIELD2 a2-999 H!Index number - correnl 4 COL 5 @FIELD1 `@y0.   Value for column 1. COLUMN1AFIELD2 a@y0. ! Value for column 2. COLUMN2AFIELD3 a@y0. ! Value for column 3. COLUMN3BFIELD4 b@y0. " Value for column 4. COLUMN4BFIELD5 b@y0. " Value for column 5. COLUMN5FTABLES are used to specify, in discrete form, a functional relationshipbetween two or more variables. Each column is dedicated to one of thevaribles, and each row contains corresponding values of the set. _Enter information for this FTABLE COL 1 COL 2 COL 3 COL 4 COL 5 COL 6 @FIELD1 `@y0.   Value for column 1. COLUMN1AFIELD2 a@y0. ! Value for column 2. COLUMN2AFIELD3 a@y0. ! Value for column 3. COLUMN3BFIELD4 b@y0. " Value for column 4. COLUMN4BFIELD5 b@y0. " Value for column 5. COLUMN5CFIELD6 c@y0. # Value for column 6. COLUMN6FTABLES are used to specify, in discrete form, a functional relationshipbetween two or more variables. Each column is dedicated to one of thevaribles, and each row contains corresponding values of the set. Only one conditional exists in this "IF" or "ELSE IF" statement, and atleast one conditional must exist at all times. Thus, this record cannot be dropped from the conditional list.  Specify type of record to add: [@] 'IF' Condition [@] Action record [@] 'ELSE' Condition [@] 'ELSE_IF' Condition [@] 'END_IF' Condition Add [@] before or [@] after this record. @@] 'IF'` I _ONOFF @] 'ELSE'_ONOFF @] 'ELSE_IF'_ONOFF @] 'END_IF'_ONOFF @] Action 0 Toggle this option on to add an 'if' condition. A@] 'om Number of rows in FTABLE. AFIELD3 aQ 1 ! Number of columns in FTABLE. BFIELD4 bNO,YES " Modify header for this FTABLE.BFIELD5 bNO,YES " Modify data for this FTABLE. FTABLES are used to specify, in discrete form, a functional relationshipbetween two or more variables. Each column is dedicated to one of thevaribles, and each row contains corresponding values of the set. xEnter header information for this FTABLE. column 1 column 2 column 3 column 4 column 5 column 6 column 7@FIELD1 '  Header for this column of the FTABLE. COLUMN1`PAFIELD2 '! Header for this column of the FTABLE. COLUMN2a PAFIELD3 '! Header for this column of the FTABLE. COLUMN3aPBFIELD4 '" Header for this column of the FTABLE. COLUMN4b"PBFIELD5 '" Header for this column of the FTABLE. COLUMN5b-PCFIELD6 '# Header for this column of the FTABLE. COLUMN6c8PCFIELD7 '# Header for this column of the FTABLE. COLUMN7cCPFTABLES are used to specify, in discrete form, a functional relationshipbetween two or more variables. Each column is dedicated to one of thevaribles, and each row contains corresponding values of the set. KEnter information for this FTABLE COL 1 COL 2 COL 3 COL 4 @FIELD1 `@y0.   Value for column 1. COLUMN1AFIELD2 a@y0. ! Value for column 2. COLUMN2AFIELD3 a@y0. ! Value for column 3. COLUMN3BFIELD4 b@y0. " Value for column 4. COLUMN4FTABLES are used to specify, in discrete form, a functional relationshipbetween two or more variables. Each column is dedicated to one of thevaribles, and each row contains corresponding values of the set. UEnter information for this FTABLE COL 1 COL 2 COL 3 COLpnP' Flag indicating if run is to be made,if zero only interpretation will be done.H@UNIT h"( Unit system; 1-english, 2-metric. 6 This block must always be present in a RUN input set. For the UCI file in use, no Opn Sequence data has been defined. Thus, no editing of Opn Sequence information may be performed. Ac Operation #@FIELD0 ` NO,DP,CP,**8  Action to take for this record: none,drop,copy,commentAFIELD1 a@<PERLND,IMPLND,RCHRES,COPY,PLTGEN,DISPLY,DURANL,GENER,MUTSIN!Type of this operation.OPTYP AFIELD2 a!Number of this operation. OPTNO vThis block specifies the various operations to be performed in the RUNand, optionally, their grouping into INGROUPS. ^  Specify INGRP Time Units and Time Step: @ Hours [@NOH] @ Minutes [@NOM] @@ Hours` " _ONOFF @ Minutes_OFFON @ Minutes  OFF @NOH 4 16 4 21 G Toggle this option on if the time interval is to be in units of hours. A@ Minutes a $ _ONOFF @ Hours_OFFON @ Hours  OFF @NOM 6 16 6 21 I! Toggle this option on if the time interval is to be in units of minutes. A@NOH a0,1,2,3,4,6,8,12,24'! Enter the desired time step in hours. B@NOM b< 0,1,2,3,4,5,6,10,12,15,20,30,60)" Enter the desired time step in minutes. Only one record exists in the Opn Sequence block, and at least onerecord must exist in the Opn Sequence block at all times. Thus, this record cannot be dropped from the Opn Sequence block.u For the UCI file in use, no FTABLE data has been defined. Thus, no editing of FTABLE information may be performed. `Enter information about FTABLES. ID number # rows # columns mod header? modify data?@FIELD1 `Q-999 #  Identification number for FTABLE. AFIELD2 a Q1 !qogories @MUtsin @MAss-link @REturn@ ` GLobal a Opn_sequence a FTables b SPec-actions b FIles c CAtegories c PErlnd d Implnd d RChres e COpy e PLtgen f DIsply f DUranl g GEner g MUtsin h EXT-Sourcesh FOrmatsi Network i EXT-Targets j SChematic j MAss-link k MOnth-Data k PAthnames l REturn  Choose a block to modify.  Enter information for table &.  Modify GLOBAL parameters as necessary. Runinfo:@RIN.......................................................................... Simulation starting date Simulation ending date RI output level: @RILV Year Mo Dy Hr Mi Year Mo Dy Hr Mi SP output level: @SPLV @SYR @SM @SD @SH @SI @EYR @EM @ED @EH @EI Resume flag: @REFG Run flag : @RUFG Unit system: @UNIT @@RIN * Enter a description of the UCI file here. `A@SYR a'! Starting year of simulation. A@SMa ! Starting month of simulation. B@SDb" Starting day of simulation.B@SHb" Starting hour of simulation. C@SIc<# Starting minute of simulation. C@EYR c'# Ending year of simulation. D@EMd $ Ending month of simulation.D@EDd$ Ending day of simulation. E@EHe% Ending hour of simulation. E@EIe<% Ending minute of simulation. F@RILV f H& Governs quantity of informative output produced by the run interpreter.F@SPLV f 8& Governs quantity of informative special actions output.G@REFG gR' Flag indicating if run is to be in resume mode,not supported in current release. G@RUFG gUp5 -WW[_20001115105618 20001115105618 HBCMOD 0^pz=`vxSlo.A17E0 " Select a UCI modify option. GENERAL SIMULATION UTILITY TIMESERIES @GLobal @PErlnd @COpy @EXT-Sources @Opn_sequence @Implnd @PLtgen @FOrmats @FTables @RChres @DIsply @Network @SPec-actions @DUranl @EXT-Targets @FIles @MOnth-Data @GEner @SChematic @PAthnames @CAte&CCCCC is active. It must appear as an input to this operation in theEXT SOURCES, NETWORK, and/or SCHEMATIC/MASS-LINK blocks. `  1 1 1 5 10 5 -4&D &CCCCC :&I The required input timeseries &CCCCC &I &I was omitted for thisoperation. It is required for this operation type whenever section&CCCCC is active but section &CCCCC is inactive. It must appear asan input to this operation in the EXT SOURCES, NETWORK, and/orSCHEMATIC/MASS-LINK blocks.k  1 1 1 5 10 5 -4&D &CCCCC :&I The required input timeseries &CCCCC &I &I was omitted for thisoperation. It is required for this operation type whenever section&CCCCC is active and the value of flag &CCCCC equals &I . It mustappear as an input to this operation in the EXT SOURCES, NETWORK,and/or SCHEMATIC/MASS-LINK blocks.   1 1 1 5 10 5 -4&D &CCCCC :&I The required input timeseries &CCCCC &I &I was omitted for thisoperation. It is required for this operation type whenever section&CCCCC is active, section &CCCCC is inactive, and the value of flag&CCCCC equals &I . It must appear as an input to this operation inthe EXT SOURCES, NETWORK, and/or SCHEMATIC/MASS-LINK blocks.N  1 1 1 5 10 5 -4&D &CCCCC :&I The required input timeseries &CCCCC &I &I was omitted for thisoperation. It is required for this operation type whenever the valueof flag &CCCCC equals &I . It must appear as an input to this operationin the EXT SOURCES, NETWORK, and/or SCHEMATIC/MASS-LINK blocks. b 1 1ACTIVITY 101 101 301 301 1 1 8 1 1PRINT-INFO 102 102 302 302 2 1 8 1 1BINARY-INFO 136 136 336 336 3 1 11 1 1GEN-INFO 103 103 303 303 4 1 2 1 2ATEMP-DAT 104 201 304 401 5 2 1 1 1ICE-FLAG 105 105 305 305 6 3 2 1 1SNOW-FLAGS 106 106 306 306 7 3 7 1 2SNOW-PARM1 107 202 307 402 8 3 6 1 2SNOW-PARM2 108 203 308 403 9 3 12 1 2MON-MELT-FAC 109 204 309 404 10 3 6 1 2SNOW-INIT1 110 205 310 405 11 3 3 1 2SNOW-INIT2 111 206 311 406 12 3 5 1 1IWAT-PARM1 112 112 312 312 13 4 4 1 2IWAT-PARM2 113 207 313 407 14 4 2 1 2IWAT-PARM3 114 208 314 408 15 4 12 1 2MON-RETN 115 209 315 409 16 4 12 1 2MON-MANNING 116 116 316 316 17 4 2 1 2IWAT-STATE1 117 210 317 410 18 4 0 0 0DDDDDDDDDDDD 000 000 000 000 19 3 1 1SLD-PARM1 118 118 318 318 20 5 4 1 2SLD-PARM2 119 211 319 411 21 5 12 1 2MON-SACCUM 120 212 320 412 22 5 12 1 2MON-REMOV 121 121 321 321 23 5 1 1 2SLD-STOR 122 213 322 413 24 5 2 1 1IWT-PARM1 123 123 323 323 25 6 3 1 2IWT-PARM2 124 214 324 414 26 6 2 1 2LAT-FACTOR 125 125 325 325 27 6 12 1 2MON-AWTF 126 215 326 415 28 6 12 1 2MON-BWTF 127 216 327 416 29 6 3 1 2IWT-INIT 128 217 328 417 30 6 1 1 1NQUALS 129 129 329 329 31 7 20 1 1IQL-AD-FLAGS 130 130 330 330 32 7 8 10 1QUAL-PROPS 131 131 331 331 33 71 5 10 2QUAL-INPUT 13 $!20050725132959 20050725132959 HSPFXX pv+BJ;i~   ************************************************************ * * * Hydrological Simulation Program - FORTRAN * * * ************************************************************ Developed for: Modified and Maintained by U.S. Environmental Aqua Terra Consultants Protection Agency (650)962-1864 Office of Research email: hspf@aquaterra.com and Development Center for Exposure Assessment Modeling Athens, Georgia (706)355-8400 email: ceam@epamail.epa.gov In cooperation with: U.S. Geological Survey Release 12.2 Water Resources Discipline July 2005 Office of Surface Water Reston, Virginia email: h2osoft@usgs.gov   Start of Jobm  PREPROCESSING USERS CONTROL INPUT. SEARCHING FOR BOUNDARIES OF NEXT DATA SET IN USERS CONTROL INPUT.   End of Job 6  INTERPRETING RUN DATA SET IN USERS CONTROL INPUT  ==================================================================================================================================== PROCESSING FORMATS BLOCK  FINISHED PROCESSING FORMATS BLOCK ==================================================================================================================================== vTit the RCHRES HT-BED-DELTT table. c ; C@ HEAT-INITo# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HEAT-INIT table. c - D@ SANDFG l$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES SANDFG table.d ! D@ SED-GENPARM q$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES SED-GENPARM table. d 5$E@ SED-HYDPARM q% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES SED-HYDPARM table. e 5( E@ SAND-PM m% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES SAND-PM table. e %,F@ SILT-CLAY-PM r& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES SILT-CLAY-PM table. f 90 F@ SSED-INITo& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES SSED-INIT table. f -4 G@ BED-INIT n' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES BED-INIT table. g )8   Select RCHRES table(s) to modify. GQUAL @ GQ-GENDATA @ GQ-PHOTPM @ GQ-ADRATE @ GQ-GAMMA @ GQ-AD-FLAGS @ GQ-CFGAS @ GQ-ADTHETA @ GQ-DELTA @ GQ-QALDATA @ GQ-BIOPM @BGQ-SEDCONC @ GQ-CLDFACT @ GQ-QALFG @ MON-BIO @ GQ-VALUES @ MON-CLOUD @ GQ-FLG2 @ GQ-GENDECAY @ MON-WATEMP @ MON-SEDCONC @ GQ-HYDPM @AGQ-SEDDECAY @ MON-ROXYGEN @ MON-PHYTO @ GQ-ROXPM @ GQ-KD @ GQ-ALPHA @ GQ-DAUGHTER @@ GQ-GENDATA p Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GQ-GENDATA table.` 1A@ GQ-AD-FLAGS q! Toggle field On (X) or Off ( ) using the space bar. Toggle thiwu34G@I p' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-CFVOL table.g 38G@J r' Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-CDEMAND table. g ;< H@ ADCALC q( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES ADCALC-DATA table. h 5@H@ NCONSk( Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES NCONS table. h DI@ CONS-AD-FLAGSs) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES CONS-AD-FLAGS table. i =H I@ CONS-DATAo) Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES CONS-DATA table. i -LD  Select RCHRES table(s) to modify. HTRCH SEDTRN @AHT-BED-FLAGS @CHT-BED-DELH @ SANDFG @ SILT-CLAY-PM @ HEAT-PARM @DHT-BED-DELTT @ SED-GENPARM @ SSED-INIT @BHT-BED-PARM @ HEAT-INIT @ SED-HYDPARM @ BED-INIT @EMON-HT-TGRND @ SAND-PM@@A r Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HT-BED-FLAGS table. ` ; A@ HEAT-PARMo! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HEAT-PARM table. a -A@B q! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HT-BED-PARM table. a 7 B@E r" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-HT-TGRND table. b ;B@C q" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HT-BED-DELH table. b 7C@D r# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edxvREC @ CONS-DATA @ GEN-INFO @CHYDR-IRRIG @HHYDR-CEVAP @DHYDR-INIT @IHYDR-CFVOL @JHYDR-CDEMAND @@ ACTIVI n Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES ACTIVITY table. ` ) A@ PRINT- p! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES PRINT-INFO table.a 1 A@ BINARY q! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES BINARY-INFO table. a 5  B@ GEN-IN n" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES GEN-INFO table. b )B@A p" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-PARM1 table.b 3C@B p# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-PARM2 table.c 3 C@ MON-CO o# Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES MON-CONVF table. c -D@C p$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-IRRIG table.d 3 D@D o$ Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-INIT table. d /$E@E s% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-CATEGORY table. e ?(E@F p% Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-CINIT table.e 3,F@G p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-CPREC table.f 30F@H p& Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the RCHRES HYDR-CEVAP table.f ywECAY GQIDGQ-SEDDECAY GQIDGQ-KD GQIDGQ-ADRATE GQIDGQ-ADTHETA GQIDGQ-SEDCONC GQIDGQ-DAUGHTER HYDROLYSISGQ-DAUGHTER OXIDATIONGQ-DAUGHTER PHOTOLYSISGQ-DAUGHTER [DUMMY]GQ-DAUGHTER BIODEGRADATIONGQ-DAUGHTER FIRST-ORDER DECAY~  0 19 20 15 37 29 68 13 83 23 108 7  Select RCHRES section(s) to modify. @ GENERAL, HYDR, ADCALC, CONS @ HTRCH, SEDTRN @ GQUAL @ RQUAL, OXRX @ NUTRX, PLANK @ PHCARB, ACIDPH @@ GENER Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit tables in the GENER, HYDR, ADCALC, or CONSsections.` uA@ HTRCH{! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit tables in the HTRCH or SEDTRN sections. a =A@ GQUALt! Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the tables in the GQUAL section.a ! B@ RQUAL}" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the tables in the RQUAL or OXRX sections. b 5B@ NUTRX~" Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the tables in the NUTRX or PLANK sections. b 9 C@ PHCARB # Toggle field On (X) or Off ( ) using the space bar. Toggle this field on to edit the tables in the PHCARB or ACIDPH sections.c A  Select RCHRES table(s) to modify. GENERAL HYDR ADCALC CONS @ ACTIVITY @AHYDR-PARM1 @EHYDR-CATEGORY @ ADCALC-DATA @ NCONS @ PRINT-INFO @BHYDR-PARM2 @FHYDR-CINIT @ CONS-AD-FLAGS @ BINARY-INFO @ MON-CONVF @GHYDR-CPzx 389 101 11 5 1 2PLNK-PARM4 209 209 409 409 102 11 6 1 2PHYTO-PARM 190 254 390 454 103 11 5 1 2ZOO-PARM1 191 191 391 391 104 11 4 1 2ZOO-PARM2 192 192 392 392 105 11 7 1 2BENAL-PARM 193 193 393 393 106 11 7 4 2BENAL-GROW 202 202 402 402 107 11 5 4 2BENAL-RESSCR 203 255 403 455 108 11 4 1 2BENAL-GRAZE 204 204 404 404 109 11 4 1 2BENAL-LIGHT 205 256 405 456 110 11 5 1 2BENAL-RIFF1 206 257 406 457 111 11 8 1 2BENAL-RIFF2 207 207 407 407 112 11 6 1 2PLNK-INIT 194 194 394 394 113 11 4 1 2BENAL-INIT 208 208 408 408 114 11 12 1 2MON-BINV 211 211 411 411 115 11 0 0 0NNNNNNNNNNNN 0 0 0 0 116 0 0 0PPPPPPPPPPPP 0 0 0 0 117 2 1 1PH-PARM1 195 195 395 395 118 12 3 1 2PH-PARM2 196 196 396 396 119 12 3 1 2PH-INIT 197 197 397 397 120 12 14 1 1ACID-FLAGS 198 198 398 398 121 13 7 1 2ACID-PARMS 199 199 399 399 122 13 7 1 2ACID-INIT 200 200 400 400 123 13 0 0 0END RCHRES 000 000 000 000 124 GENERAL 1HYDR 2ADCALC 3CONS 4HTRCH 5SEDTRN 6GQUAL 7RQUAL 8OXRX 9NUTRX 10PLANK 11PHCARB 12ACIDPH 13T CONS-DATA CONIDSILT-CLAY-PM SILTSILT-CLAY-PM CLAYGQ-QALDATA GQIDGQ-QALFG GQIDGQ-FLG2 GQIDGQ-HYDPM GQIDGQ-ROXPM GQIDGQ-PHOTPM GQIDGQ-CFGAS GQIDGQ-BIOPM GQIDMON-BIO GQIDGQ-GEND{y 0IIIIIIIIIIII 0 0 0 0 68 1 1 1BENTH-FLAG 161 161 361 361 69 8 2 1 2SCOUR-PARMS 162 248 362 448 70 8 1 1 1OX-FLAGS 163 163 363 363 71 9 4 1 2OX-GENPARM 164 249 364 449 72 9 1 1 2ELEV 165 250 365 450 73 9 6 1 2OX-BENPARM 166 166 366 366 74 9 1 1 2OX-CFOREA 167 167 367 367 75 9 2 1 2OX-TSIVOGLOU 168 168 368 368 76 9 2 1 2OX-LEN-DELTH 169 251 369 451 77 9 1 1 2OX-TCGINV 170 170 370 370 78 9 4 1 2OX-REAPARM 171 171 371 371 79 9 3 1 2OX-INIT 172 172 372 372 80 9 0 0 0JJJJJJJJJJJJ 0 0 0 0 81 0 0 0KKKKKKKKKKKK 0 0 0 0 82 0 0 0LLLLLLLLLLLL 0 0 0 0 83 8 1 1NUT-FLAGS 173 173 373 373 84 10 6 1 1NUT-AD-FLAGS 174 174 374 374 85 10 4 1 2CONV-VAL1 175 175 375 375 86 10 5 1 2NUT-BENPARM 176 176 376 376 87 10 6 1 2NUT-NITDENIT 177 177 377 377 88 10 2 1 2NUT-NH3VOLAT 178 178 378 378 89 10 6 1 2NUT-BEDCONC 179 179 379 379 90 10 6 1 2NUT-ADSPARM 180 180 380 380 91 10 5 1 2NUT-DINIT 181 181 381 381 92 10 6 1 2NUT-ADSINIT 182 182 382 382 93 10 12 1 2MON-PHVAL 183 183 383 383 94 10 9 1 1PLNK-FLAGS 184 184 384 384 95 11 6 1 1BENAL-FLAGS 201 201 401 401 96 11 6 1 1PLNK-AD-FLAGS 185 185 385 385 97 11 1 1 2SURF-EXPOSED 186 186 386 386 98 11 7 1 2PLNK-PARM1 187 252 387 452 99 11 7 1 2PLNK-PARM2 188 253 388 453 100 11 6 1 2PLNK-PARM3 189 189 389 |z2 245 332 445 34 6 7 1 2SHADE-PARM 258 258 458 458 35 5 0 0 0EEEEEEEEEEEE 0 0 0 0 36 0 0 0FFFFFFFFFFFF 0 0 0 0 37 8 1 1GQ-GENDATA 133 133 333 333 38 7 14 1 1GQ-AD-FLAGS 134 134 334 334 39 7 10 7 2GQ-QALDATA 135 135 335 335 40 71 7 7 1GQ-QALFG 136 136 336 336 41 71 7 7 1GQ-FLG2 137 137 337 337 42 71 4 7 2GQ-HYDPM 138 138 338 338 43 71 2 7 2GQ-ROXPM 139 139 339 339 44 71 20 7 2GQ-PHOTPM 140 140 340 340 45 71 1 7 2GQ-CFGAS 141 141 341 341 46 71 3 7 2GQ-BIOPM 142 142 342 342 47 71 12 7 2MON-BIO 143 143 343 343 48 71 2 7 2GQ-GENDECAY 144 144 344 344 49 71 4 7 2GQ-SEDDECAY 145 145 345 345 50 71 6 7 2GQ-KD 146 146 346 346 51 71 6 7 2GQ-ADRATE 147 147 347 347 52 71 6 7 2GQ-ADTHETA 148 148 348 348 53 71 6 7 2GQ-SEDCONC 149 149 349 349 54 71 6 1 2GQ-VALUES 150 246 350 446 55 7 12 1 2MON-WATEMP 151 247 351 447 56 7 12 1 2MON-ROXYGEN 152 152 352 352 57 7 18 1 2GQ-ALPHA 153 153 353 353 58 7 18 1 2GQ-GAMMA 154 154 354 354 59 7 18 1 2GQ-DELTA 155 155 355 355 60 7 18 1 2GQ-CLDFACT 156 156 356 356 61 7 12 1 2MON-CLOUD 157 157 357 357 62 7 12 1 2MON-SEDCONC 158 158 358 358 63 7 12 1 2MON-PHYTO 159 159 359 359 64 7 7 6 2GQ-DAUGHTER 160 160 360 360 65 7 0 0 0GGGGGGGGGGGG 0 0 0 0 66 0 0 0HHHHHHHHHHHH 0 0 0 0 67 0 0{ 1 1ACTIVITY 101 101 301 301 1 1 12 1 1PRINT-INFO 102 102 302 302 2 1 12 1 1BINARY-INFO 210 210 410 410 3 1 13 1 1GEN-INFO 103 103 303 303 4 1 19 1 1HYDR-PARM1 104 104 304 304 5 2 7 1 2HYDR-PARM2 105 230 305 430 6 2 12 1 2MON-CONVF 106 106 306 306 7 2 2 1 2HYDR-IRRIG 107 231 307 431 8 2 12 1 2HYDR-INIT 108 232 308 432 9 2 8 1 1HYDR-CATEGORY 109 109 309 309 10 2 40 1 2HYDR-CINIT 110 110 310 310 11 2 40 1 2HYDR-CPREC 111 111 311 311 12 2 60 1 2HYDR-CEVAP 112 112 312 312 13 2 80 1 2HYDR-CFVOL 113 113 313 313 14 2120 1 2HYDR-CDEMAND 114 233 314 433 15 2 2 1 2ADCALC-DATA 115 234 315 434 16 3 1 1 1NCONS 116 116 316 316 17 4 20 1 1CONS-AD-FLAGS 117 117 317 317 18 4 11 10 2CONS-DATA 118 118 318 318 19 4 0 0 0CCCCCCCCCCCC 0 0 0 0 20 3 1 1HT-BED-FLAGS 119 119 319 319 21 5 6 1 2HEAT-PARM 120 235 320 435 22 5 4 1 2HT-BED-PARM 121 236 321 436 23 5 12 1 2MON-HT-TGRND 122 237 322 437 24 5 7 1 2HT-BED-DELH 123 238 323 438 25 5 7 1 2HT-BED-DELTT 124 239 324 439 26 5 2 1 2HEAT-INIT 125 240 325 440 27 5 1 1 1SANDFG 126 126 326 326 28 6 3 1 2SED-GENPARM 127 241 327 441 29 6 3 1 2SED-HYDPARM 128 242 328 442 30 6 5 1 2SAND-PM 129 243 329 443 31 6 6 2 2SILT-CLAY-PM 130 244 330 444 32 6 3 1 2SSED-INIT 131 131 331 331 33 6 4 1 2BED-INIT 13Adsorbed NH4 thru indiv exits MET kg/iv 0 4.537E2 0 1000. OSPO4 5 4 -75 3 2 8 0 17039 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows of adsorbed PO4 thru indiv exits MET kg/iv 0 4.537E2 0 1000. PKCF2 5 10 -75 5 2 9 0 17977 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows thru indiv exits (Group PLANK) MET kg/iv 0 4.537E2 0 1000. PHCF2 5 3 -75 2 2 10 0 18165 ENG lb/iv 0 1.602E4 0 3.531E4 Outflows of TIC and CO2 thru indiv exits MET kg/iv 0 4.537E2 0 1000. ACFLX2 5 7 -75-18238 2 11 0 18599 ENG lb/iv 0 1.602E1 0 3.531E1 Outflows thru indiv exits (Group ACIDPH) MET lb/iv 0 0.4537 0 1. ya  20 1 1 5 Category tag &C was supplied in message WDM file. This is a program bug.  20 1 1 5 Unrecognized category tag &C was supplied by user in a UVQUAN line. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  20 1 1 5 Category tag &C was supplied by user in a UVQUAN line, but no category tags were defined in the CATEGORY block.  20 1 1 5 Unrecognized category tag &C was supplied by user in a UVNAME line. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  20 1 1 5 Category tag &C was supplied by user in a UVNAME line, but no category tags were defined in the CATEGORY block.  20 1 1 5 Unrecognized category tag &C was supplied by user in a Special Action line. Is it spelled correctly? Is it placed in the correct columns here? In the CATEGORY block?  20 1 1 5 Category tag &C was supplied by user in a Special Action line, but no category tags were defined in the CATEGORY block.  10 1 1 5 Problem reading the following mfact update special action: &CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC It has been ignored.y  10 1 1 5 Too many mfact update special actions have been requested. The maximum number allowed is &I .  1 1ACTIVITY 101 101 301 301 1 1 14 1 1PRINT-INFO 102 102 302 302 2 1 14 1 1BINARY-INFO 238 238 438 438 3 1 11 1 1GEN-INFO 103 103 303 303 4 1 2 1 2ATEMP-DAT 104 240 304 440 5 2 1 1 1ICE-FLAG 105 105 305 305 6 3 2 1 1SNOW-FLAGS 106 106 306 306 7 3 7 1 2SNOW-PARM1 107 241 307 441 8 3 6 1 2SNOW-PARM2 108 242 308 442 9 3 12 1 2MON-MELT-FAC 109 243 309 443 10 3 6 1 2SNOW-INIT1 110 244 310 444 11 3 3 1 2SNOW-INIT2 111 245 311 445 12 3 13 1 1PWAT-PARM1 112 112 312 312 13 4 7 1 2PWAT-PARM2 113 246 313 446 14 4 7 1 2PWAT-PARM3 114 247 314 447 15 4 6 1 2PWAT-PARM4 115 248 315 448 16 4 2 1 2PWAT-PARM5 116 249 316 449 17 4 6 1 2PWAT-PARM6 117 250 317 450 18 4 7 1 2PWAT-PARM7 118 251 318 451 19 4 7 1 2PWAT-STATE1 119 252 319 452 20 4 12 1 2MON-INTERCEP 120 253 320 453 21 4 12 1 2MON-UZSN 121 254 321 454 22 4 12 1 2MON-MANNING 122 122 322 322 23 4 12 1 2MON-INTERFLW 123 123 323 323 24 4 12 1 2MON-IRC 124 124 324 324 25 4 12 1 2MON-LZETPARM 125 125 325 325 26 4 8 1 2SOIL-DATA 126 255 326 455 27 4 4 1 2SOIL-DATA2 127 256 327 456 28 4 3 1 2SOIL-DATA3 128 257 328 457 29 4 13 1 1CROP-DATES 129 129 329 329 30 4 4 3 2CROP-STAGES 130 130 330 330 31 4 4 3 2CROP-SEASPM 131 258 331 458 32 4 5 1 1IRRIG-PARM1 132 132 332 332 33 4 8 1 2IRRIG-PARM2 /y $!20040719144732 20040719144732 PERLND U,-00P2q48Z;>ADFI5[hESp  & :/==JNOSlU5MN{SVWNXX[<_aNd0filprrsvy|~Dԃ*qˆHÐߙT|D5Qѭֳbһvbo\SLvo jk$8   pTl`!"B$%&<()*,%./0Y2395g67%:U=>HBHCDE0GGIVJKHMOOQ"RT0QEWlZ]`c=ePkynDqsFu7xzY}4i/r>/4GtNLM  U&8;I&NOSTNQfV4WFXXBZx]R`b*ei&k\n"qs)uxz"}N>lȉQ)ƗbŞtYұA ݿ +rmkcjC87aZ"<  kuMAI\/!"$%=& ()*u,-[/0$235M678;>B.CDEGGHIlKMNmOQRRTKSW[_a)dfloPrsvy{n~#˓=ǣv0۸yE/G#  12 sz $!20051202162314 20051202162314 IMPLND zJa0FN7KP4[D`h2  0#TB"uy 7 f/ >?i\~!f  eT#"5. T   6 |{ $!20051117171709 20051117171709 RCHRES $ei@ߡזAq֋N6C~|"z>xwt.ulmjiHgec<^6__]][3VUUSQ#KoHI>GDDB`BCp@@A?~<=;9`453{01e/,-+)n)&)'$y%">## &!$ -c'lXv z n0-R atD +y6tk1f{dba^\Z YWR8$7)''%I  i&i7f|߆}{y%t'ujlmjkfMdba^_n\ZXsWURQJDHIGGDEWBC<@@A>M<=:_86d52Z01D/g,-*(f))!''%"5##8 !!  >:8gm   H7JQ6*wthg|ec&^%_J][VTS9-4q&$m% S D $ fP  10 Ont.S  50 1 1 5The binary output interval (BIVL) for one or more RCHRES operationsdoes not equal the print output interval (PIVL), and both thebinary and print output options are on. When using both binaryand print output options, BIVL must equal PIVL. The remedy is tochange one or the other. BIVL = &I , and PIVL = &I . v (1X,5(1PE10.3)) FRRIF CMMV RIFCQ1 RIFCQ2 RIFCQ3 (ft/s) (cfs) (cfs) (cfs) z RCHRES FRRIF CMMV RIFCQ1 RIFCQ2 RIFCQ3 x - x m/s cms cms cms BENAL-RIFF1@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP #<?1.0]!FRRIF is the fraction of the reach that is composed of riffleswhere benthic algae can grow. FRRIF AFIELD4 aP75y1.0q!CMMV is the Michaelis-Menton half-saturation constant forriffle velocity in the nutrient availability equation. CMMV BFIELD5 bPy0. O"RIFCQ1 is the first critical flow level for rifflevelocity and average depth. RIFCQ1 BFIELD6 bPy0. P"RIFCQ2 is the second critical flow level for rifflevelocity and average depth.RIFCQ2 CFIELD7 cPy0. O#RIFCQ3 is the third critical flow level for rifflevelocity and average depth. RIFCQ3 4First group of riffle parameters for benthic algae.v (1X,5(1PE10.3)) FRRIF CMMV RIFCQ1 RIFCQ2 RIFCQ3 (m/s) (cms) (cms) (cms) V RCHRES RIFVEL1 RIFVEL2 RIFVEL3 RIFVEL4 RIFDEP1 RIFDEP2 RIFDEP3 RIFDEP4 x - x BENAL-RIFF2@@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a@?y1. W!RIFVEL(1) is the riffle velocity multiplier below the firstcritical flow value RIFCQ1 RIFVF1 AFIELD4 a@?y1. X!RIFVEL(2) is the riffle velocity multiplier below the secondcritical flow value RIFCQ2RIFVF2 BFIELD5 b@?y1. W"RIFVEL(3) is the riffle velocity multiplier below the thirdcritical flow value RIFCQ3 RIFVF3 BFIELD6 b@?y1. W"RIFVEL(4) is the riffle velocity multiplier above the thirdcritical flow value RIFCQ3  &I for PEST supplemental information reference in UCI record.T $!20030213131733 20030213131733 GETSUP       % U t       ==================================================================================================================================== PROCESSING PEST SUPPLEMENTAL FILE  FINISHED PROCESSING PEST SUPPLEMENTAL FILE ====================================================================================================================================o  20 1 1 5 Too many arrays specified in PEST supplemental file. The maximum number allowed is &I. v  20 1 1 5 Error reading header number &I in PEST supplemental file. ID read was &I. Number read was &I.  20 1 1 5 Too many entries in array for header number &I in PEST supplemental file. Header ID is &I. Maximum number of entries is &I. Number of entries requested is &I.s  20 1 1 5 ID &I for header number &I in PEST supplemental file is already in use by header number &I.  20 1 1 5 Error reading supplemental values for ID &I (header number &I) in PEST supplemental file. Attempting to read &I values.  20 1 1 5 Error reading supplemental values for ID &I (header number &I) in PEST supplemental file. Attempted to read &I values. N  20 1 1 5 Supplemental ID &I not found in PEST supplemental file. `  20 1 1 5 Error reading PEST supplemental information ID between columns &I and &I.  20 1 1 5 Incorrect delimteters(~) at columns &I andRIFVF4 CFIELD7 c@75?1. T#RIFDEP(1) is the riffle depth multiplier below the firstcritical flow value RIFCQ1RIFDF1 CFIELD8 c@75?1. U#RIFDEP(2) is the riffle depth multiplier below the secondcritical flow value RIFCQ2 RIFDF2 DFIELD9 d@75?1. T$RIFDEP(3) is the riffle depth multiplier below the thirdcritical flow value RIFCQ3RIFDF3 DFIELD10d@75?1. T$RIFDEP(4) is the riffle depth multiplier above the thirdcritical flow value RIFCQ3RIFDF4 5Second group of riffle parameters for benthic algae. c (1X,8(1PE10.3)) RIFVEL1 RIFVEL2 RIFVEL3 RIFVEL4 RIFDEP1 RIFDEP2 RIFDEP3 RIFDEP4 f RCHRES BENAL1 BENAL2 BENAL3 BENAL4 x - x mg/m2 mg/m2 mg/m2 mg/m2 BENAL-INIT @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aPy0. Q!BENAL(1) is the initial value of the first species of benthicalgae, as biomass. BENAL1 AFIELD4 aPy0. R!BENAL(2) is the initial value of the second species of benthicalgae, as biomass. BENAL2 BFIELD5 bPy0. Q"BENAL(3) is the initial value of the third species of benthicalgae, as biomass. BENAL3 BFIELD6 bPy0. R"BENAL(4) is the initial value of the fourth species of benthicalgae, as biomass. BENAL4 cInitial benthic algae conditions, if multiple species aresimulated - i.e. BALFG=2 and NUMBAL > 1. b (1X,4(1PE10.3)) BENAL1 BENAL2 BENAL3 BENAL4 (mg/m2) (mg/m2) (mg/m2) (mg/m2) z RCHRES NMINGR PMINGR CMINGR LMINGR NMINC x - x mg/l mg/l mg/l ly/min mg/l PLNK-PARM4 @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 aP75y0.001 =!NMINGR is the minimum nitrate concentration for algae growth NMINGR AFIELD4 aP75y0.001 ?!PMINGR is the minimum phosphate concentration for algae growth PMINGR BFIELD5 bP75y0.001 ;"CMINGR is the minimum CO2-C concentration for algae growth CMINGR BFIELD6 bP75y0.001 7"LMINGR is the minimum light intensity for algae growth LMINGR CFIELD7 cP.y0.001 ^#NMINC is the minimum inorganic nitrogen concentrationallowed to remain after nutrient uptake NMINC &General plankton parameters, group 4. v (1X,5(1PE10.3)) NMINGR PMINGR CMINGR LMINGR NMINC mg/l mg/l mg/l ly/min mg/l  RCHRES Values of benthic invertebrate density (mg/m2) x - x B1 B2 B3 B4 B5 B6 B7 B8 B9 B10 B11 B12 MON-BINV @@FIELD1 " RCHRES to which these data apply. OPNID `QAFIELD3 a(y0. O!BINVM(1) through BINVM(12) are monthly values of benthicinvertebrate density. BINVM1 AFIELD4 a(y0. BINVM2 BFIELD5 b(y0. BINVM3 BFIELD6 b(y0. BINVM4 CFIELD7 c(y0. BINVM5 CFIELD8 c(y0. BINVM6 DFIELD9 d(y0. BINVM7 DFIELD10d(y0. BINVM8 EFIELD11e(y0. BINVM9 EFIELD12e(y0. BINVM10FFIELD13f(y0. BINVM11FFIELD14f(y0. BINVM12cMonthly values of benthic invertebrate density; input onlyif BINVFG=3 in Table-type BENAL-FLAGS (1X,12(1PE10.3))Values of benthic invertebrate density (mg biomass/m2) at the start of each month: JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC  RCHRES SHADFG TOPFL VEGFL NSSP LATDEG LONDEG LONSTD x - x (deg) (deg) (deg) SHADE-PARM @@FIELD1 " RCHRES to which these data apply. OPNID `AAFIELD3 aP?0. 6!SHADFG specifies that the SHADE module is being used. SHADFG AFIELD4 aPAB41.!TOPFL is the unit number of the topographic data file forthis RCHRES. It contains location information and topographicdata for each Stream Sample Point (SSP) in the RCHRES.TOPFL BFIELD5 bPAB42."VEGFL is the unit number of the vegetative data file forthis RCHRES. It contains vegetation shading characteristicsdata for each Stream Sample Point (SSP) in the RCHRES. VEGFL BFIELD6 bPzC0. "NSSP is the number of Stream Sample Points (SSPs) definedfor the RCHRES. Topographic and vegetative characteristicsare defined at each SSP. NSSP CFIELD7 cP\\B40.1#LATDEG is the latitude of the RCHRES (degrees). LATDEG CFIELD8 cP44C-90. 2#LONDEG is the longitude of the RCHRES (degrees). LONDEG DFIELD9 dP44C-90. ?$LONSTD is the longitude of the center of the local time zone. LONSTD ,Parameters for SHADE calculations in HTRCH. (1X,6(1PE10.3)) SHADFG TOPFL VEGFL NSSP LATDEG LONDEG LONSTD (deg) (deg) (deg)