Difference between revisions of "Project File:Continuous Simulations – Optional"

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(β†’β€Ž3.8.7 Distributed Hydrometeorology Data - Optional)
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==3.8.7 Distributed Hydrometeorology Data - Optional ==
 
==3.8.7 Distributed Hydrometeorology Data - Optional ==
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This function allows GSSHA to read in raster-based hydrometeorology data.  The input files must be in the same projection as the GSSHA model and must be larger than the model domain.  Please see [[Raster-Based HMET]] for more details.
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This function allows GSSHA to read in raster-based hydrometeorology data.  The input files must be in the same projection as the GSSHA model and must be larger than the model domain.  Please see [[Distributed HMET Data]] for more details.
 
{| class="thin" width=700px
 
{| class="thin" width=700px
 
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! Card !! Argument !! Units !! Description
 
! Card !! Argument !! Units !! Description
 
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| <pre>HMET_ASCII  ***.txt</pre> || ''File || see [[Raster-Based HMET]] || Inputs hyrometeorology data (temperature, relative humidity, pressure, etc.) in each cell based on hourly ASCII files, giving the model more spatial variability.  The files must have a specific format as described in '''[[Raster-Based HMET]]'''.
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| <pre>HMET_ASCII  ***.txt</pre> || ''File || see [[Distributed HMET Data]] || Inputs hyrometeorology data (temperature, relative humidity, pressure, etc.) in each cell based on hourly ASCII files, giving the model more spatial variability.  The files must have a specific format as described in '''[[Distributed HMET Data]]'''.
 
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Revision as of 16:27, 21 December 2012

Continuous simulations require general information about the watershed location, selection of a method to calculate evapo-transpiration (ET), hydrometeorological (HMET) data in one of three available formats, and the appropriate distributed data either from the Mapping Table file or from GRASS ASCII maps.

3.8.1 Required Inputs

Card Argument Units Description
LONG_TERM
none   Specifies continuous simulation. REQUIRES one of ET_CALC_PENMAN or ET_CALC_DEARDORFF.

REQUIRES one of three HMET formats. Also REQUIRES INF_REDIST or INF_RICHARDS.

LATITUDE  ##.##
real decimal
degrees
Latitude of catchment centroid.
LONGITUDE  ##.##
real decimal
degrees
Longitude of catchment centroid.
GMT  ##.##
real hr Number of hours difference between the time zone of the catchment and Greenwich Mean Time (e.g. –6 for EDT).
SOIL_MOIST_DEPTH  ##.##
real m Depth of the active soil moisture layer from which ET occurs (m).
EVENT_MIN_Q  ##.##
real m3/s Threshold discharge for continuing runoff events.
ET_CALC_PENMAN
none Calculate evapo-transpiration using the Penman-Monteith (1971) method.

3.8.2 Seasonal Canopy Resistance - Optional

Card Argument Units Description
SEASONAL_RS
none Specifies that the values of canopy resistance vary seasonally

3.8.3 Format of Hydrometeorological (HMET) Data – Required, Select One Format

Card Argument Description
HMET_SURFAWAYS  "filename.hmt"
file name ASCII file with hourly HMET data formatted in the form of the NOAA/NCDC Surface Airways Data. Mutually exclusive with HMET_SAMSON and HMET_WES; one required for LONG_TERM.
HMET_SAMSON  "filename.hmt"
file name ASCII file with hourly HMET data formatted as per the NOAA/NCDC SAMSON CD-ROM data set. Mutually exclusive with HMET_WES and HMET_SURFAWAYS; one required for LONG_TERM.
HMET_WES  "filename.hmt"
file name ASCII file with hourly HMET data written using a simple format discussed in the Continuous Simulation Section of this document. Mutually exclusive with HMET_SURFAWAYS and HMET_SAMSON; one required for LONG_TERM.


3.8.4 ET Parameter Assignment – Required, Select Mapping Table or GRASS ASCII maps

Long-term simulation parameters must be assigned using either the Mapping Table or providing the GRASS ASCII maps as described below. Albedo, wilting point, transmission coefficient, vegetation height and canopy resistance are also required for ET_CALC_PENMAN.

Card Argument Description
ALBEDO  "filename.alb"
map name Name of GRASS ASCII map containing short-wave albedo values (0.0 – 1.0).
WILTING_POINT  "filename.wtp"
map name Name of GRASS ASCII map containing values of the wilting point volumetric water content (0.0 - 1.0).
TCOEFF  "filename.tcf"
map name Name of GRASS ASCII map containing values of the canopy optical transmission coefficient. (0.0 - 1.0).
VHEIGHT  "filename.vht"
map name Name of GRASS ASCII map containing values of the vegetation height in m. This value is used in calculating the aerodynamic resistance of the reference crop (m) and used in assigning root depth when using INF_RICHARDS.
CANOPY  "filename.cpy"
map name Name of GRASS ASCII map containing values of the canopy average stomatal resistance (s/m).

3.8.5 Optional Inputs

Card Argument Units Description
TOP_LAYER_DEPTH ##.##
real m If using GAR, can specify a top layer that is less than or equal to SOIL_MOIST_DEPTH, default is SOIL_MOIST_DEPTH (m).
END_TIME [yr mo day hr min]
date and time date and time Absolute date and time to end the long term simulation. Takes the form year month day hour min, such as 2002 6 30 24 00. Used for stopping the simulation before the end of data.
START_DATE [yr mo day ]
date year month day Absolute date to start the long term simulation. Takes the form year month day, such as 2002 6 30. Used for starting the the simulation after the beginning of the hmet data start. Must be used with START_TIME. Start time and date must coincide with a date and time in the hmet series that is not within a precipitation event.
START_TIME [hr min]
time hour minute Absolute date and time to end the long term simulation. Takes the form of hour min, 24 00. Used for starting the the simulation after the beginning of the hmet data start. Must be used with START_DATE. Start time and date must coincide with a date and time in the hmet series that is not within a precipitation event.


3.8.6 Snow Card Inputs - Optional

Cards calling which snow melt algorithm to use

Melt Method Card Description
Hybrid Energy Balance
default (no card required)
The Hybrid Energy Balance Method for melting snow is the default, so it is utilized if NWSRFS_SNOW and EB_SNOW are not present in the Project File.
Temperature Index
NWSRFS_SNOW
The Temperature Index Method for melting snow is utilized if this card is present in the Project File.
Energy Balance
EB_SNOW
The Energy Balance Method for melting snow is utilized if this card is present in the Project File.

Cards Associated with All Three Melt Methods

Card Argument Units Description
NWSRFS_SCF     ##.##
real fraction Snow Cover Factor (adjusts for mis-readings in the gage data (see Continuous:Snowfall_Accumulation_and_Melting).
SNOW_TEMP_BASE ##.##
real °C Base Temperature (MBASE) at which melt begins in snow.
SNOW_NO_INFILTRATE
    This option prevents infiltration in any cell containing snow.
INIT_SWE_DEPTH #.# or File
real or File m Initializes the snow water equivalent (SWE) for the entire model. If a value is specified the entire model initializes with that value of SWE. A map file may also be specified. The projection and spatial coordinates must be the same as the model. An example input file is shown below.
SNOW_SWE_FILE  ***.swe
File m Outputs time-series snow water equivalent maps (similar to DEP file).

Example file when using INIT_SWE_DEPTH
Init Snow.jpg


Cards Associated with BOTH Hybrid Energy Balance and Temperature Index Methods

Card Argument Units Description
NWSRFS_FR_USE  ##.##
real fraction Specifies the fraction of precipitation in the form of rain when the temperature in the cell drops below MBASE.
NWSRFS_TIPM       ##.##
real   Snow Cover Thermal Gradient
NWSRFS_NMF        ##.##
real mm/°C/dt Negative Melt Factor.
NWSRFS_FUA        ##.##
real   Empirical Wind Function Factor.
NWSRFS_PLWHC      ##.##
real  % Percent Liquid Water Holding Capacity.
NWSRFS_ELEV_SNOW  File
File depends on parameter This card allows some of the parameters related to snow to be varied depending on elevation using elevation bands. Model elevation (*.ele file) must be in meters. The format of the input file is shown below.

Example file when using NWSRFS_ELEV_SNOW
Band NWSRFS.jpg
Elevations are in meters, all other values are in their standard formats.

Cards Associated with JUST Temperature Index Method

Card Argument Units Description
NWSRFS_MF_MAX  ##.##
real mm/°C/dt Maximum Melt Factor, only works with NWSRFS_SNOW.
NWSRFS_MF_MIN  ##.##
real mm/°C/dt Minimum Melt Factor, only works with NWSRFS_SNOW.

Cards Associated with Vertical Melt Water Transport (Vertical MWT)

Card Argument Units Description
SNAP_RETENTION
    Uses the SNAP model (Albert & Krajeski, 1998) to simulate the vertical transport of melt-water through the snow pack (Vertical MWT).
VERT_SNOW_RETENTION
    Uses the SNAP model (Albert & Krajeski, 1998) to simulate the vertical transport of melt-water through the snow pack (Vertical MWT), but also distributes the melt incrementally over an hour instead of abruptly at every timestep that SNAP is run (which is hourly).

Cards Associated with Lateral Melt Water Transport (Lateral MWT)

Card Argument Units Description
SNOW_DARCY     ##.##
real m s-1 Simulates the lateral transport of melt-water through the snow pack based on work by Colbeck (1974) (Lateral MWT). The user specifies the initial hydraulic conductivity of the snow pack (m s-1), but the hydraulic conductivity changes with time according to the SNAP model (Albert & Krajeski, 1998).
SNOW_REYNOLDS  ##.##
real   Reynolds Number at which flow simulation switches from Darcian to regular Overland. Only effects cells covered by snow and only works when SNOW_DARCY card present in Project File.

Cards Associated with Orographic Effects

Card Argument Units Description
HMET_OROG_GAGES  ***.txt
File see Orographic Effects Adjusts the temperature in each cell based on elevation differences between the cell and multiple gage sites. The file must have a specific format as shown in Orographic Effects. Model elevation (*.ele file) must be in meters.
OROGVAR_HMET
    Adjusts the temperature in each cell based on elevation differences between the cell and the gage site (Orographic Effects). Only works when HMET_ELEV_GAGE and HMET_LAPSE_RATE cards present in Project File. This is an additional option if you do not want to use HMET_OROG_GAGES. Only one temperature gage used for this option. Model elevation (*.ele file) must be in meters.
HMET_ELEV_GAGE   ##.##
real m Elevation (m) of the gage site where temperature is measured. Only works when OROGVAR_HMET and HMET_LAPSE_RATE cards present in Project File.
HMET_LAPSE_RATE  ##.##
real °C km-1 Dry adiabatic lapse rate of the area modeled. Only works when OROGVAR_HMET and HMET_ELEV_GAGE cards present in Project File.


3.8.7 Distributed Hydrometeorology Data - Optional

This function allows GSSHA to read in raster-based hydrometeorology data. The input files must be in the same projection as the GSSHA model and must be larger than the model domain. Please see Distributed HMET Data for more details.

Card Argument Units Description
HMET_ASCII  ***.txt
File see Distributed HMET Data Inputs hyrometeorology data (temperature, relative humidity, pressure, etc.) in each cell based on hourly ASCII files, giving the model more spatial variability. The files must have a specific format as described in Distributed HMET Data.




GSSHA User's Manual

3 Project File
3.1     Required Inputs
3.2     Mapping Table – Optional
3.3     Overland Flow – Required
3.4     Interception – Optional
3.5     Rainfall Input and Options – Required
3.6     Infiltration – Optional
3.7     Channel Routing – Optional
3.8     Continuous Simulations – Optional
3.9     Saturated Groundwater Flow – Optional
3.10     Soil Erosion – Optional
3.11     Constituent Transport – Optional
3.12     Subsurface Drainage Network – Optional
3.13     Output Files – Required


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