Difference between revisions of "Output:Run Summary File"
(No difference)
|
Latest revision as of 18:05, 20 May 2008
The run summary contains a summary for each event simulated and simulation totals after the last event summary. For each event the run summary file contains a number of sections: title, start-up inputs, mass-conservation, warnings, and outputs. If Richards’ equation is used to simulate the unsaturated zone a separate mass-conservation section is included in each event summary. If saturated groundwater is simulated then a separate mass-conservation is included in each event summary. The following is an example of the run summary file output for a continuous simulation with a single event. In this example Richards’ equation is used to simulate the unsaturated zone and lateral groundwater flow is calculated, along with interaction with the stream network.
_________GSSHA start-up information________ Run parameters read from WMS project file: 10gw.prj reading watershed mask from file: test.mask number of grid cells in watershed: 110 reading elevation map from file: elev_file reading soil map from file: test.mask reading water table map from file: test.wt reading aquifer bottom map from file: test.gwb Inital volume of water in root zone= 4989.621857 Inital volume of water in soil column= 574165.748622 reading groundwater boundary file: test.bound reading hyd. cond. map from file: hycond_file reading link map from file: test2.link reading node map from file: test2.node reading channel input data from file test.chan1 Initial soil water volume= 24948.109285 writing output for optimization to file using precipitation data from file: one_event.gag Running.... GSSHA LONG-TERM RUNOFF SIMULATION SUMMARY- EVENT 1 Event began on strict Julian date: 2445113.04166667 Event ended on strict Julian date: 2445113.66111111 Event began on 05/23/1982 at 13:00 GMT -6.0 hours. GSSHA used NCDC/SAMSON hydrometeorological data from the MEMPHIS station Hydrometeorology data began on: 05/24/1982 at 3:00 and ended on: 07/01/1982 at 0:00 The following number of hydromet. data points were repaired:0 Penman-Monteith evapo-transpiration was calculated. With raingage data using Thiessen polygon interpolation. time step 60.0 seconds elevation and gridsize are in meters initial basin-averaged soil water content:16.21 percent number of time steps with rain: 630 elapsed time when rain began: 2204.00 peak occured on strict Julian date: 2445113.45486111 date/time of peak discharge: 5/23/1982 22:55:00 peak discharge (cms): 4.22 initial volume on overland (cu. m): 0.0 initial volume in channels (cu. m): 0.0 inital volume of snow (cu. m): 0.0 volume of rainfall (cubic meters): 225500.0 volume of discharge (cu. m): 122219.5 volume of infiltrated water (cu. m): 99579.3 volume of water exfiltrated (cu. m): 0.0 volume of lateral inflow (cu. m): 122652.2 volume of gw to chan (cu. m): -402.6 volume from overland point sources 0.0 volume remaining on surface (cu. m): 2005.3 final volume in channels (cu. m): 29.9 final volume of snow (cu. m): 0.0 mass conservation error: 0.0001 percent Richard's EQ. Computations volume lost due to dir. evap (cu. m): 1263.3 net vol infiltrated to soil (cu. m.): 99354.7 volume to deep ground water (cu. m): 1025.9 Initial volume in soils (cu. m.): 574198.2 Final volume in soils (cu. m.): 670524.7 Richard equation mass balance error -0.1902 percent Number of cells at start of event 9595 Number of cells at end of event 9589 net volume of infiltration is infiltration minus evaporation GROUNDWATER CALCULATION SUMMARIES FOR EVENT volume of water directly to surface from groundwater (cu. m): 0.0 beginning vol of water exfiltrated this event (cu. m): 0.0 total vol of water exfiltrated this run (cu. m): 0.0 vol from gw to unsat this event (cu. m): -910.1 vol from gw to chan this event (cu. m): -402.6 final basin-averaged soil water content:74.69 percent THE FOLLOWING WARNINGS ARE GIVEN: No Warnings. THE FOLLOWING INPUTS WERE READ: A WMS Project File was used. Floating point GRASS maps were read. THE FOLLOWING PROCESSES WERE SIMULATED: Explicit diffusive-wave channel routing. Uniform overland roughness. Infiltration by Richards Eq. THE FOLLOWING OUTPUT MAPS WERE WRITTEN EVERY 60 TIME STEP(S): ASCII WMS maps of: overland flow depth. THE FOLLOWING ASCII OUTPUT FILES WERE WRITTEN TO EVERY 1 TIME STEP(S): hydrograph at the catchment outlet. SIMULATION TOTALS GROUNDWATER CALCULATIONS GW volume start = 58878050.00 GW volume end = 58880266.51 Sat/unsat. trickery = 0.00 Exfiltration back on overland = 0.00 Infiltration to groundwater = 900.98 Total inputs to groundwater= 2212.47 Mass Balance error = -0.00 GLOBAL MASS BALANCE CALCULATIONS All volumes are in cubic meters Initial volume on surface= 0.00 Initial volume in channels= 0.00 Initial volume in soils= 574165.75 Initial volume in groundwater= 58878050.00 Final volume on surface= 2005.27 Final volume in channels= 29.94 Final volume in soils= 670524.67 Final volume in groundwater= 58880266.51 Final volume of snow= 0.00 Total amount of precip= 225500.00 Total amount of infiltration= 99579.28 Total amount of evaporation= 1576.53 Total direct evaporation= 1263.26 Total flux from unsat to gw= 900.98 Total amount of discharge= 122219.46 Total flux of gw across bounds= 0.00 Total flux from gw to river= -402.57 Total amount of exfiltration= 0.00 Total overland point sources= 0.00 Mass balance error of inputs= 0.000094 percent Overall mass balance error = -0.001836 percent
GSSHA User's Manual
- 14 Output
- 14.1 Required Flags and Files
- 14.2 Run Summary File
- 14.3 Optional Flags
- 14.4 Time Series Data at Internal Locations
- 14.5 WMS Hydrograph File
- 14.6 Time Series Maps