Contents
Introduction
The conceptual solution for the interface between HEC-RAS and FEWS has been illustrated in Figure 1. Two modes of working are identified that each support a basic use case. The modes of working are:
- Operational forecasting mode
- Calibration mode
The technical implementations for both modes of working are quite different. For running HEC-RAS in operational forecasting mode from FEWS, a software interface will be required that directly controls the model runs.
Calibration is considered as an activity that should be carried out offline from the forecasting system. This means that no direct control from FEWS will be required but a user will need to be able to migrate model datasets (calibrated schematizations) from the HEC-RAS calibration environment to the forecasting environment.
Present documentation will describe the first mode of operation. For details about operating model in the calibration mode please check standard HEC-RAS documentation.
Operating Forecasting Model
Figure 1 Components used to run forecasts using HEC-RAS model in the FEWS/CHPS system
Operating HEC-RAS Model and FEWS Adapter
The HEC-RAS model provides the compute engine for running a hydraulic model schematization for a section of a river or a part of a river system. The HEC-RAS Adapter forms the interface between the FEWS Forecasting Shell and the HEC-RAS model.
The HEC-RAS compute engine is, as its name suggests, the component that actually performs the HEC-RAS simulation. This simulation is controlled from the FEWS Adapter, and all run time data such as initial and boundary conditions, and parameter settings are passed through the adapter from and to the FEWS Forecasting Shell.
Download
Example of the HEC-RAS adapter configuration, including model binary files can be found in the following zip file:
Interface between FEWS and HEC-RAS
The FEWS Adapter for HEC-RAS forms the interface between the FEWS Forecasting Shell and the HEC-RAS model. The adapter accepts the request from the Forecasting Shell to run HEC-RAS, and imports the required data provided by the Forecasting Shell.
This data shall be provided in a standardized XML interface format, the FEWS Published Interface. Once a HEC-RAS run has been completed, relevant results are passed back to the Forecasting Shell in the form of the standardized XML interface format.
A schematic representation of the communication between the Forecasting Shell and the HEC-RAS model via the FEWS Adapter is shown in the diagram below.
Figure 2 Data flows involved during run of HEC-RAS model FEWS adapter
The FEWS Adapter allows running of HEC-RAS by FEWS. The FEWS Adapter should be considered as a thin communication (software) layer on top the existing HEC-RAS engine. The adapter is tightly connected to the model engine. For longer term consistency, a FEWS adapter should therefore preferably be maintained by the owner of the model code, in this case HEC. The FEWS Adapter for HEC-RAS shall be developed by HEC or handed over to HEC upon completion.
The features of the are listed in the tables below.
Preprocessing 01 |
Clean up work and output folder |
Preprocessing 02 |
Create module diagnostics file in Published Interface (PI) format |
Preprocessing 03 |
Read the time series from PI time series |
Preprocessing 04 |
Convert input PI time series into RAS *.b01 files |
Launcher 01 |
Run HEC-RAS with run period and model alternative |
Postprocessing 01 |
Open/create module diagnostics file in PI format |
Postprocessing 02 |
Read the output time series from the RAS DSS and binary output files |
Postprocessing 03 |
Write the time series to the output.xml |
Postprocessing 04 |
Write the time series to the binary-output.xml |
Postprocessing 05 |
Write the updated PI state file to export folder |
ID Mapping
The location parameters used in FEWS can be coupled to HEC-RAS DSS path names through ID-mapping. The configuration files for ID-mapping should be created separately for each HEC-RAS model. Please consult 08 Mapping Id's flags and units for more information on how to configure id mapping in FEWS system.
Directory structure
The data directories and configuration files that are required for operating the FEWS Adapter for HEC-RAS have been shown below.
Note that only binary and configuration files relevant to the HEC-RAS adapter are included, in a real configuration a lot more files can be involved used by another modules of the FEWS system.
+---bin
| hec.jar
| heclib.jar
| heclib60.dll
| javaHeclib.dll
| libjavaHeclib.so
| module-adapter-hec-ras.jar......................... pre- and pos- adapter, Coverts HEC-RAS data files to/from FEWS-PI format
| nwsras.jar......................................... main library used by the adapter, reads and writes HEC-RAS data files
|
\---connecticu
+---ColdStates
| hecras_connecticut_Historical Default.zip...... cold state files
|
+---Config
| +---IdMapFiles
| | IdExportHECRAS.xml......................... custom mappings for the HEC-RAS variables and locations
| |
| \---ModuleConfigFiles
| hecras_Connecticut_Forecast.xml............ main configuration file of the adapter
|
\---Modules
\---hec-ras
+---bin........................................ directory which contains all HEC-RAS executables for Windows and Linux platforms
| DSSWriter.exe.......................... generates binary file containing detailed model output
| dss_writer
| GeomPreprocessor.exe................... converts geometry files from GUI ASCII format to binary
| geo_pre
| Steady.exe............................. performs steady flow simulations
| steady
| Unsteady.exe........................... performs unsteady flow simulations
| unsteady
| libmtsk.so.1
|
\---connecticut
+---input.................................. input directory of the adapter, input FEWS-PI time series files
| inputs.xml
|
+---log.................................... log messages written by the pre- and post- adapters
| postadapter.xml
| preadapter.xml
|
+---output................................. contains HEC-RAS output converted from the binary and dss output files
| binary-output.xml
| output.xml
|
\---work................................... working directory of the adapters
clean.cmd.......................... Windows and Linux scripts used to clean temporary files
clean.sh
run.cmd............................ Windows and Linux scripts used to execute the HEC-RAS model
run.sh
ctfld2ras.b01
ctfld2ras.b02
ctfld2ras.b03
ctfld2ras.c02
ctfld2ras.f04
ctfld2ras.g02
ctfld2ras.p01
ctfld2ras.p02
ctfld2ras.p05
ctfld2ras.prj
ctfld2ras.r01
ctfld2ras.r02
ctfld2ras.r03
ctfld2ras.r05
ctfld2ras.u01
ctfld2ras.u02
ctfld2ras.x02
Communication between FEWS system and pre-/post- adapter strictly follows the FEWS Published Interface format.
Description of the HEC-RAS data files
Table 1 List of files to be read and written by adapter
Extension |
Description |
pre-adapter input |
pre-adapter output |
post-adapter input |
post-adapter output |
|---|---|---|---|---|---|
.prj |
project file |
|
|
|
|
.p01 |
plan files |
|
|
|
|
.g01 |
geometry files |
|
|
|
|
.f01 |
flow files |
|
|
|
|
.u01 |
unsteady flow files |
|
|
|
|
.b01 |
unsteady run files |
|
|
|
|
.x01 |
input file for geometry preprocessor |
|
|
|
|
.r01 |
steady run file |
|
|
|
|
.O01 |
binary output file |
|
|
|
|
.bco |
model log file |
|
|
|
|
.c01 |
output of geometry preprocessor |
|
|
|
|
.dss |
input / output files |
|
|
|
|
.hyd01 |
input file for geometry preprocessor |
|
|
|
|
Configuring HEC-RAS adapter
HEC-RAS model adapter follows standard way of integrating external models into the Delft-FEWS system by use of General Adapter. For more details about configuration of General Adapter please check 05 General Adapter Module.
Example configuration of the HEC-RAS adapter:
<?xml version="1.0" encoding="UTF-8"?> <generalAdapterRun xmlns="http://www.wldelft.nl/fews" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.wldelft.nl/fews http://fews.wldelft.nl/schemas/version1.0/generalAdapterRun.xsd"> <general> <description>hecras Model for Kennebec River</description> <rootDir>%REGION_HOME%/Models/hecras/</rootDir> <workDir>%ROOT_DIR%/kennebec/work</workDir> <exportDir>%ROOT_DIR%/kennebec/input</exportDir> <exportDataSetDir>%ROOT_DIR%/kennebec/work</exportDataSetDir> <exportIdMap>IdExportHECRAS</exportIdMap> <exportUnitConversionsId>displayEnglishUnits</exportUnitConversionsId> <importDir>%ROOT_DIR%/kennebec/output</importDir> <importIdMap>IdImportHECRAS</importIdMap> <importUnitConversionsId>ImportEnglishUnits</importUnitConversionsId> <dumpFileDir>$GA_DUMPFILEDIR$</dumpFileDir> <dumpDir>%ROOT_DIR%/kennebec</dumpDir> <diagnosticFile>%ROOT_DIR%/kennebec/log/preadapter.xml</diagnosticFile> </general> <activities> <startUpActivities> <purgeActivity> <filter>%ROOT_DIR%/kennebec/log/*.*</filter> </purgeActivity> <purgeActivity> <filter>%ROOT_DIR%/kennebec/input/*.*</filter> </purgeActivity> <purgeActivity> <filter>%ROOT_DIR%/kennebec/output/*.*</filter> </purgeActivity> <purgeActivity> <filter>%ROOT_DIR%/kennebec/work/*.*</filter> </purgeActivity> </startUpActivities> <exportActivities> <exportStateActivity> <moduleInstanceId>HECRAS_KENNEBEC_UpdateStates</moduleInstanceId> <stateExportDir>%ROOT_DIR%/kennebec/work</stateExportDir> <stateConfigFile>%ROOT_DIR%/kennebec/work/state.xml</stateConfigFile> <stateLocations type="file"> <stateLocation> <readLocation>Augusta.p02.rst</readLocation> <writeLocation>Augusta.p02.rst</writeLocation> </stateLocation> </stateLocations> <stateSelection> <warmState> <stateSearchPeriod unit="day" start="-10" end="0"/> </warmState> </stateSelection> </exportStateActivity> <exportTimeSeriesActivity> <exportFile>input.xml</exportFile> <timeSeriesSets> <timeSeriesSet> <moduleInstanceId>HECRAS_KENNEBEC_Preprocessing_Forecast</moduleInstanceId> <valueType>scalar</valueType> <parameterId>QINE</parameterId> <locationId>SIDM1ME</locationId> <timeSeriesType>simulated forecasting</timeSeriesType> <timeStep unit="hour" multiplier="1"/> <relativeViewPeriod unit="hour" end="0" endOverrulable="true"/> <readWriteMode>read only</readWriteMode> </timeSeriesSet> <timeSeriesSet> <moduleInstanceId>HECRAS_KENNEBEC_Preprocessing_Forecast</moduleInstanceId> <valueType>scalar</valueType> <parameterId>STID</parameterId> <locationId>CASM1ME</locationId> <timeSeriesType>simulated forecasting</timeSeriesType> <timeStep unit="hour" multiplier="1"/> <relativeViewPeriod unit="hour" end="0" endOverrulable="true"/> <readWriteMode>read only</readWriteMode> </timeSeriesSet> </timeSeriesSets> </exportTimeSeriesActivity> <exportDataSetActivity> <moduleInstanceId>HECRAS_KENNEBEC_UpdateStates</moduleInstanceId> </exportDataSetActivity> </exportActivities> <!-- RAS execution --> <executeActivities> <executeActivity> <command> <className>nl.wldelft.fews.adapter.hec.HecRasPreAdapter</className> </command> <arguments> <argument>--project-file=%ROOT_DIR%/kennebec/work/Augusta.prj</argument> <argument>--dss-file=%ROOT_DIR%/kennebec/work/Augusta.dss</argument> </arguments> <timeOut>120000</timeOut> </executeActivity> <executeActivity> <command> <executable>%ROOT_DIR%/kennebec/work/run.sh</executable> </command> <timeOut>120000</timeOut> </executeActivity> <executeActivity> <command> <className>nl.wldelft.fews.adapter.hec.HecRasPostAdapter</className> </command> <arguments> <argument>--project-file=%ROOT_DIR%/kennebec/work/Augusta.prj</argument> <argument>--output-log-file=%ROOT_DIR%/kennebec/log/postadapter.xml</argument> <argument>--output-pi-file=%ROOT_DIR%/kennebec/output/output.xml</argument> <argument>--output-binary-file=%ROOT_DIR%/kennebec/work/Augusta.IC.O02</argument> <argument>--output-binary-pi-file=%ROOT_DIR%/kennebec/output/binary-output.xml</argument> </arguments> <timeOut>1500000</timeOut> </executeActivity> </executeActivities> <importActivities> <importTimeSeriesActivity> <importFile>output.xml</importFile> <timeSeriesSets> <timeSeriesSet> <moduleInstanceId>HECRAS_KENNEBEC_Forecast</moduleInstanceId> <valueType>scalar</valueType> <parameterId>SSTG</parameterId> <locationId>AUGM1ME</locationId> <timeSeriesType>simulated forecasting</timeSeriesType> <timeStep unit="hour" multiplier="1"/> <readWriteMode>add originals</readWriteMode> </timeSeriesSet> <timeSeriesSet> <moduleInstanceId>HECRAS_KENNEBEC_Forecast</moduleInstanceId> <valueType>scalar</valueType> <parameterId>SQIN</parameterId> <locationId>AUGM1ME</locationId> <timeSeriesType>simulated forecasting</timeSeriesType> <timeStep unit="hour" multiplier="1"/> <readWriteMode>add originals</readWriteMode> </timeSeriesSet> </timeSeriesSets> </importTimeSeriesActivity> </importActivities> </activities> </generalAdapterRun>
List of input and output variables which can be exchanged with the Delft-FEWS system and HEC-RAS adapter
Whe HEC-RAS adapter is configured properly and forecast is performed from the Delft-FEWS system - a list of input and output variables will be written into the standard log file of the system. The location and variables are based on the active <region>.b01 file of the HEC-RAS model configured in the GUI of HEC-RAS. Pre-adapter of the HEC-RAS will provide list of all possible input variables and locations in the following part of the log file:
... 156 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Found input at locations: 156 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - CT River, R1, 334752.0, Flow Hydrograph 156 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - CT River, R1, 0.00, Stage Hydrograph ...
Locations and variables listed after the line Found input at locations: can be configured in the Delft-FEWS as a part of adapter input, e.g. input.xml in this case may contain something like the lines below:
<TimeSeries
xsi:schemaLocation="http://www.wldelft.nl/fews/PI http://fews.wldelft.nl/schemas/version1.0/pi-schemas/pi_timeseries.xsd"
version="1.2" xmlns="http://www.wldelft.nl/fews/PI" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
<timeZone>0.0</timeZone>
<series>
<header>
<type>instantaneous</type>
<locationId>CT RIVER R1 334752.0</locationId>
<parameterId>Flow Hydrograph</parameterId>
<timeStep unit="second" multiplier="3600"/>
<startDate date="2008-11-06" time="12:00:00"/>
<endDate date="2008-11-08" time="12:00:00"/>
<missVal>-999.0</missVal>
<stationName>Connicut River at Thompsonville</stationName>
<units>cms</units>
</header>
<event date="2008-11-06" time="12:00:00" value="14.98" flag="0"/>
<event date="2008-11-06" time="13:00:00" value="14.705" flag="0"/>
<event date="2008-11-06" time="14:00:00" value="14.43" flag="0"/>
<event date="2008-11-06" time="15:00:00" value="14.155" flag="0"/>
<event date="2008-11-06" time="16:00:00" value="13.88" flag="0"/>
<event date="2008-11-06" time="17:00:00" value="13.605" flag="0"/>
...
Note that <parameterId> and <locationId> are exactly the same as the variables and locations listed in the log file.
In the same way list of all output variables and locations can be found in the post-adapter log output, for example:
... 84843 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Profile, Profile number., 84843 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - W.S. Elev, Calculated water surface from energy equation., (ft) 84843 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - E.G. Elev, Energy gradeline for given WSEL., (ft) 84843 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Max Chl Dpth, Maximum main channel depth., (ft) 84843 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Min Ch El, Minimum Channel Elevation., (ft) 84843 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Q Left, Flow in left overbank., (cfs) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Q Channel, Flow in main channel., (cfs) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Q Right, Flow in right overbank., (cfs) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Q Total, Total flow in cross section., (cfs) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Flow Area, Total area of cross section active flow., (sq ft) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Flow Area L, Area of left overbank active flow., (sq ft) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Flow Area Ch, Area of main channel active flow., (sq ft) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - Flow Area R, Area of right overbank active flow., (sq ft) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - W.P. Total, Wetted perimeter of total cross section., (ft) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - W.P. Left, Wetted perimeter of left overbank., (ft) 84859 [main] INFO nl.wldelft.fews.adapter.hec.HecRasDataAccessFacadeImpl - W.P. Channel, Wetted perimeter of main channel., (ft) ...
Note that parameter names to be written into the output FEWS-PI file will contain only the short name of the parameter, e.g.: Q Right and not Flow in right overbank., (cfs).
The variables listed here will be written into the file specified as a "--output-binary-pi-file=<path>" argument of the post-adapter. Example of the resulting FEWS-PI xml can be found below:
<TimeSeries
xsi:schemaLocation="http://www.wldelft.nl/fews/PI http://fews.wldelft.nl/schemas/version1.0/pi-schemas/pi_timeseries.xsd"
version="1.2" xmlns="http://www.wldelft.nl/fews/PI" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
<timeZone>0.0</timeZone>
<series>
<header>
<type>instantaneous</type>
<locationId>CT River R1 334752.0</locationId>
<parameterId>W.S. Elev</parameterId>
<timeStep unit="second" multiplier="3600"/>
<startDate date="2008-11-06" time="00:00:00"/>
<endDate date="2008-11-08" time="00:00:00"/>
<missVal>NaN</missVal>
<units>[?]</units>
</header>
<event date="2008-11-06" time="00:00:00" value="32.06013" flag="0"/>
<event date="2008-11-06" time="01:00:00" value="32.06013" flag="0"/>
<event date="2008-11-06" time="02:00:00" value="32.034" flag="0"/>
<event date="2008-11-06" time="03:00:00" value="32.03394" flag="0"/>
...
<event date="2008-11-07" time="23:00:00" value="32.03618" flag="0"/>
<event date="2008-11-08" time="00:00:00" value="32.03598" flag="0"/>
</series>
<series>
<header>
<type>instantaneous</type>
<locationId>CT River R1 334752.0</locationId>
<parameterId>E.G. Elev</parameterId>
<timeStep unit="second" multiplier="3600"/>
<startDate date="2008-11-06" time="00:00:00"/>
<endDate date="2008-11-08" time="00:00:00"/>
<missVal>NaN</missVal>
<units>[?]</units>
</header>
<event date="2008-11-06" time="00:00:00" value="32.06734" flag="0"/>
<event date="2008-11-06" time="01:00:00" value="32.06734" flag="0"/>
<event date="2008-11-06" time="02:00:00" value="32.056885" flag="0"/>
...
Additionally to the variables available in the binary output of the HEC-RAS, usually called <file>.O01, a DSS output is available. In most cases it contains FLOW and STAGE variables. Example of the FEWS-PI generated from the DSS file is given below:
<TimeSeries
xsi:schemaLocation="http://www.wldelft.nl/fews/PI http://fews.wldelft.nl/schemas/version1.0/pi-schemas/pi_timeseries.xsd"
version="1.2" xmlns="http://www.wldelft.nl/fews/PI" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance">
<timeZone>0.0</timeZone>
<series>
<header>
<type>instantaneous</type>
<locationId>CT RIVER R1/0.00</locationId>
<parameterId>FLOW</parameterId>
<timeStep unit="second" multiplier="3600"/>
<startDate date="2008-11-06" time="00:00:00"/>
<endDate date="2008-11-08" time="00:00:00"/>
<missVal>NaN</missVal>
<units>CFS</units>
</header>
<event date="2008-11-06" time="00:00:00" value="24.38823" flag="0"/>
<event date="2008-11-06" time="01:00:00" value="-5.8442316" flag="0"/>
<event date="2008-11-06" time="02:00:00" value="68.705124" flag="0"/>
<event date="2008-11-06" time="03:00:00" value="391.09784" flag="0"/>
...
<event date="2008-11-07" time="23:00:00" value="438.6425" flag="0"/>
<event date="2008-11-08" time="00:00:00" value="-5259.6562" flag="0"/>
</series>
<series>
<header>
<type>instantaneous</type>
<locationId>CT RIVER R1/0.00</locationId>
<parameterId>STAGE</parameterId>
<timeStep unit="second" multiplier="3600"/>
<startDate date="2008-11-06" time="00:00:00"/>
<endDate date="2008-11-08" time="00:00:00"/>
<missVal>NaN</missVal>
<units>FEET</units>
</header>
<event date="2008-11-06" time="00:00:00" value="5.0" flag="0"/>
<event date="2008-11-06" time="01:00:00" value="5.0" flag="0"/>
<event date="2008-11-06" time="02:00:00" value="5.0" flag="0"/>
<event date="2008-11-06" time="03:00:00" value="5.0" flag="0"/>
...
Running model from FEWS
Check Delft-FEWS User Guide on how to run configured model from the Delft-FEWS system.
Running model using command-line
For testing purposes and also to simplify configuration of the HEC-RAS adapter the following command-line scripts were created:
- run.cmd - allows to run HEC-RAS model using command-line
- run.sh
- clean.cmd - cleans model working directory, all temporary or output files of the HEC-RAS model
- clean.sh
Scripts are available for Windows and Linux OS, .cmd and .sh extensions correspondingly.
Note that all files names and extensions used in the run.cmd or run.sh scripts must be defined correctly based on used input data files of the HEC-RAS model in the HEC-RAS GUI.
@echo on set RAS_BIN_HOME=..\..\bin echo Processing geometry ... %RAS_BIN_HOME%\GeomPreprocessor.exe ctfld2ras.x02 runnext=1 echo Running Unsteady.exe ... %RAS_BIN_HOME%\Unsteady.exe ctfld2ras.c02 b03 runnext=1 echo Running Steady.exe (also produces binary output, after Unsteady.exe) ... %RAS_BIN_HOME%\Steady.exe ctfld2ras.r03 runnext=1 echo Writing DSS ... %RAS_BIN_HOME%\DSSWriter.exe ctfld2ras.c02 p03 runnext=1 pause
del *.hyd* del *.IC* del *.O0* del Steady_CRASHED del *scratch* del *bco del *blf del *.xrj del *.a0* del *.hto* del *.t* del *.c del ctfld2ras.dsc del ctfld2ras.dss del GeomPreprocessor_CRASHED del *.bco* del *.rst
#!/bin/sh RAS_BIN_PATH=../../bin export LD_LIBRARY_PATH=$RAS_BIN_PATH:$LD_LIBRARY_PATH echo "Running Geometry Preprocessor ..." $RAS_BIN_PATH/geo_pre ctfld2ras.x02 echo "Running Unsteady ..." $RAS_BIN_PATH/unsteady ctfld2ras.c02 b02 echo "Running Steady ..." $RAS_BIN_PATH/steady ctfld2ras.r01 echo "Running DSS Writer ..." $RAS_BIN_PATH/dss_writer ctfld2ras.c02 p02
rm -f ./*.hyd* rm -f ./*.IC* rm -f ./*.O0* rm -f ./Steady_CRASHED rm -f ./*scratch* rm -f ./*bco rm -f ./*blf rm -f ./*.xrj rm -f ./*.a0* rm -f ./*.hto* rm -f ./*.t* rm -f ./*.c rm -f ./ctfld2ras.dsc rm -f ./ctfld2ras.dss rm -f ./GeomPreprocessor_CRASHED rm -f ./*.bco*
