#!/bin/csh -f ##SBATCH -J 12km-sf ##SBATCH -p compute ##SBATCH -t 10:00:00 ##SBATCH -n 16 #SBATCH -t 4:00:00 #SBATCH --mem=100000 #SBATCH --nodes=2 #SBATCH --ntasks-per-node=16 #SBATCH -J CMAQ_Bench #SBATCH -p debug_queue ##SBATCH -p 528_queue #SBATCH --exclusive #SBATCH -o /proj/ie/proj/CMAS/WRF-CMAQ/openmpi_4.0.1_gcc_9.1.0_debug/WRF-4.1.1/twoway_model_411_532_nf_run_script.log #SBATCH -e /proj/ie/proj/CMAS/WRF-CMAQ/openmpi_4.0.1_gcc_9.1.0_debug/WRF-4.1.1/twoway_model_411_532_nf_run_script.log set NPROCS = 6 #> Configure the system environment and set up the module #> capability limit stacksize unlimited # =================================================================== #> Runtime Environment Options # =================================================================== echo 'Start Model Run At ' `date` #> Toggle Diagnostic Mode which will print verbose information to #> standard output setenv CTM_DIAG_LVL 0 set echo # Set Working, Input, and Output Directories set ROOT_PATH = /home/stiphen/WRFCMAQ set WRF_DIR = $ROOT_PATH/WRFV411 # WRF source code directory set INPDIR = $ROOT_PATH/2016_12SE1 #Input Directory set OMIpath = $WRF_DIR/cmaq # path optics related data files set OUTPUT_ROOT = $ROOT_PATH # output root directory set NMLpath = $WRF_DIR/cmaq # path with *.nml file mechanism dependent set NMLpath2 = $WRF_DIR/cmaq # path with Species_Table_TR_0.nml file set EMISSCTRL = $WRF_DIR/cmaq # path of Emissions Control File #> Set Start and End Days for looping setenv NEW_START TRUE #> Set to FALSE for model restart set START_DATE = "2016-07-01" #> beginning date (July 1, 2016) set END_DATE = "2016-07-01" #> ending date (July 14, 2016) #> Set Timestepping Parameters set STTIME = 000000 #> beginning GMT time (HHMMSS) set NSTEPS = 240000 #> time duration (HHMMSS) for this run set TSTEP = 010000 #> output time step interval (HHMMSS) set version = 411532 set MECH = cb6r3_ae7_aq # Mechanism ID set resolution = 12km setenv RUNID v${version} set EXEC = wrf.exe #> Keep or Delete Existing Output Files set CLOBBER_DATA = TRUE setenv PRINT_PROC_TIME Y #> Print timing for all science subprocesses to Logfile #> [ default: TRUE or Y ] setenv STDOUT T #> Override I/O-API trying to write information to both the processor #> logs and STDOUT [ options: T | F ] #> WRF-CMAQ number of columns, rows and layers setenv WRF_COL_DIM 113 # wrf west_east_stag setenv WRF_ROW_DIM 93 # wrf south_north_stag setenv WRF_LAY_DIM 36 # wrf bottom_top_stag setenv CMAQ_COL_DIM 100 setenv CMAQ_ROW_DIM 80 setenv TWOWAY_DELTA_X 6 # distance between the wrf and cmaq lower left corner in the x-direction setenv TWOWAY_DELTA_Y 6 # distance between the wrf and cmaq lower left corner in the y-direction setenv WRF_LC_REF_LAT 40.0 # WRF Lambert conformal reference latitude #> WRF-CMAQ Configuratin Options setenv RUN_CMAQ_DRIVER T # [F] setenv DO_SW_CAL F # Short-wave radiation calculation ([F] setenv DO_LW_CAL F # Long-wave radiation calculation (experimental) [F] setenv WRF_CMAQ_FREQ 5 # run n wrf step and then 1 cmaq step [1] setenv CREATE_PHYSICAL_FILE F # MCIP FILES from AQPREP[F] setenv FILE_TIME_STEP 1000 # in hhmmss format set cont_from_spinup_run = F # indicates whether a wrf spinup run prior to the twoway model run set wrf_tstep = 60 # WRF model time-step set NUM_LAND_USE_TYPE = 40 # MODIS IS 20, USGS is 24, NCLD50 is 50, NCLD40 is 40 set radt = 20 # radiation module time step if (($DO_SW_CAL == T) || ($DO_LW_CAL == T)) then setenv CMAQ_WRF_FEEDBACK T # [F] else setenv CMAQ_WRF_FEEDBACK F # [F] endif set rad_scheme = _rrtmg_$radt if ($CMAQ_WRF_FEEDBACK == 'T') then if ($DO_LW_CAL == T) then set feedback = slf else set feedback = sf endif else set feedback = nf endif set call_ratio = "${WRF_CMAQ_FREQ}_1" set output_direct_name = output_${resolution}_${feedback}${rad_scheme}_${call_ratio}_v${version} set OUTDIR = $OUTPUT_ROOT/$output_direct_name # output files and directories setenv GRID_NAME SE53BENCH #> check GRIDDESC file for GRID_NAME options setenv GRIDDESC $OUTDIR/GRIDDESC #> grid description file if (! -e $OUTDIR ) then mkdir -p $OUTDIR endif set wrf_hr = $STTIME #> WRF breaks down its sttime into HH,MM,SS #> variable initilization to calculate WRF-TIME set wrf_min = 0 set wrf_sec = 0 #> HHMMSS broken down into HH:MM:SS @ wrf_sec = $wrf_hr % 100 @ wrf_hr = ($wrf_hr - $wrf_sec) / 100 @ wrf_min = $wrf_hr % 100 @ wrf_hr = ($wrf_hr - $wrf_min) / 100 set wrf_date = `date -ud "$wrf_hr":"$wrf_min":"$wrf_sec" +%H:%M:%S` set wrf_hr = $NSTEPS #> WRF breaks down its NSTEPS into HH,MM,SS #> HHMMSS broken down into HH:MM:SS @ wrf_sec = $wrf_hr % 100 @ wrf_hr = ($wrf_hr - $wrf_sec) / 100 @ wrf_min = $wrf_hr % 100 @ wrf_hr = ($wrf_hr - $wrf_min) / 100 set wrf_restart_interval = 0 @ wrf_restart_interval = ($wrf_sec / 60) + ($wrf_min) + ($wrf_hr * 60) #> Output Species and Layer Options #> CONC file species; comment or set to "ALL" to write all species to CONC setenv CONC_SPCS "O3 NO ANO3I ANO3J NO2 FORM ISOP NH3 ANH4I ANH4J ASO4I ASO4J" setenv CONC_BLEV_ELEV " 1 1" #> CONC file layer range; comment to write all layers to CONC #> ACONC file species; comment or set to "ALL" to write all species to ACONC #setenv AVG_CONC_SPCS "O3 NO CO NO2 ASO4I ASO4J NH3" setenv AVG_CONC_SPCS "ALL" setenv ACONC_BLEV_ELEV " 1 1" #> ACONC file layer range; comment to write all layers to ACONC setenv AVG_FILE_ENDTIME N #> override default beginning ACONC timestamp [ default: N ] #> Synchronization Time Step and Tolerance Options setenv CTM_MAXSYNC 300 #> max sync time step (sec) [ default: 720 ] setenv CTM_MINSYNC 60 #> min sync time step (sec) [ default: 60 ] setenv SIGMA_SYNC_TOP 0.7 #> top sigma level thru which sync step determined [ default: 0.7 ] #setenv ADV_HDIV_LIM 0.95 #> maximum horiz. div. limit for adv step adjust [ default: 0.9 ] setenv CTM_ADV_CFL 0.95 #> max CFL [ default: 0.75] #setenv RB_ATOL 1.0E-09 #> global ROS3 solver absolute tolerance [ default: 1.0E-07 ] #> Science Options setenv CTM_OCEAN_CHEM Y #> Flag for ocean halgoen chemistry and sea spray aerosol emissions [ default: Y ] setenv CTM_WB_DUST N #> use inline windblown dust emissions [ default: Y ] setenv CTM_WBDUST_BELD BELD3 #> landuse database for identifying dust source regions #> [ default: UNKNOWN ]; ignore if CTM_WB_DUST = N setenv CTM_LTNG_NO N #> turn on lightning NOx [ default: N ] setenv KZMIN Y #> use Min Kz option in edyintb [ default: Y ], #> otherwise revert to Kz0UT setenv CTM_MOSAIC N #> landuse specific deposition velocities [ default: N ] setenv CTM_FST N #> mosaic method to get land-use specific stomatal flux #> [ default: N ] setenv PX_VERSION Y #> WRF PX LSM setenv CLM_VERSION N #> WRF CLM LSM setenv NOAH_VERSION N #> WRF NOAH LSM setenv CTM_ABFLUX Y #> ammonia bi-directional flux for in-line deposition #> velocities [ default: N ] setenv CTM_BIDI_FERT_NH3 T #> subtract fertilizer NH3 from emissions because it will be handled #> by the BiDi calculation [ default: Y ] setenv CTM_HGBIDI N #> mercury bi-directional flux for in-line deposition #> velocities [ default: N ] setenv CTM_SFC_HONO Y #> surface HONO interaction [ default: Y ] setenv CTM_GRAV_SETL Y #> vdiff aerosol gravitational sedimentation [ default: Y ] setenv CTM_BIOGEMIS Y #> calculate in-line biogenic emissions [ default: N ] setenv CTM_TURN_ON_PV N #> WRF-CMAQ ONLY turn on/off PV [default: N -- make sure compiled with pv on] #> Vertical Extraction Options setenv VERTEXT N setenv VERTEXT_COORD_PATH ${INPDIR}/lonlat.csv #> I/O Controls setenv IOAPI_LOG_WRITE F #> turn on excess WRITE3 logging [ options: T | F ] setenv FL_ERR_STOP N #> stop on inconsistent input files setenv PROMPTFLAG F #> turn on I/O-API PROMPT*FILE interactive mode [ options: T | F ] setenv IOAPI_OFFSET_64 YES #> support large timestep records (>2GB/timestep record) [ options: YES | NO ] setenv IOAPI_CHECK_HEADERS N #> check file headers [ options: Y | N ] setenv CTM_EMISCHK N #> Abort CMAQ if missing surrogates from emissions Input files setenv EMISDIAG F #> Print Emission Rates at the output time step after they have been #> scaled and modified by the user Rules [options: F | T or 2D | 3D | 2DSUM ] #> Individual streams can be modified using the variables: #> GR_EMIS_DIAG_## | STK_EMIS_DIAG_## | BIOG_EMIS_DIAG #> MG_EMIS_DIAG | LTNG_EMIS_DIAG | DUST_EMIS_DIAG #> SEASPRAY_EMIS_DIAG #> Note that these diagnostics are different than other emissions diagnostic #> output because they occur after scaling. setenv EMIS_SYM_DATE N #> Master switch for allowing CMAQ to use the date from each Emission file #> rather than checking the emissions date against the internal model date. #> [options: T | F or Y | N]. If false (F/N), then the date from CMAQ's internal #> time will be used and an error check will be performed (recommended). Users #> may switch the behavior for individual emission files below using the variables: #> GR_EM_SYM_DATE_## | STK_EM_SYM_DATE_## [ default : N ] #> Diagnostic Output Flags setenv CTM_CKSUM Y #> checksum report [ default: Y ] setenv CLD_DIAG Y #> cloud diagnostic file [ default: N ] setenv CTM_PHOTDIAG Y #> photolysis diagnostic file [ default: N ] setenv NLAYS_PHOTDIAG "1" #> Number of layers for PHOTDIAG2 and PHOTDIAG3 from #> Layer 1 to NLAYS_PHOTDIAG [ default: all layers ] #setenv NWAVE_PHOTDIAG "294 303 310 316 333 381 607" #> Wavelengths written for variables #> in PHOTDIAG2 and PHOTDIAG3 #> [ default: all wavelengths ] setenv CTM_PMDIAG N #> Instantaneous Aerosol Diagnostic File [ default: Y ] setenv CTM_APMDIAG Y #> Hourly-Average Aerosol Diagnostic File [ default: Y ] setenv APMDIAG_BLEV_ELEV "1 1" #> layer range for average pmdiag = NLAYS setenv CTM_SSEMDIAG N #> sea-spray emissions diagnostic file [ default: N ] setenv CTM_DUSTEM_DIAG N #> windblown dust emissions diagnostic file [ default: N ]; #> Ignore if CTM_WB_DUST = N setenv CTM_DEPV_FILE N #> deposition velocities diagnostic file [ default: N ] setenv VDIFF_DIAG_FILE N #> vdiff & possibly aero grav. sedimentation diagnostic file [ default: N ] setenv LTNGDIAG N #> lightning diagnostic file [ default: N ] setenv B3GTS_DIAG N #> BEIS mass emissions diagnostic file [ default: N ] setenv CTM_WVEL Y #> save derived vertical velocity component to conc #> file [ default: Y ] setenv SD_TIME_SERIES F #> WRF-CMAQ sub domain time series output option [F] #setenv SD_SCOL 241 #> WRF-CMAQ sub domain time series starting column #setenv SD_ECOL 248 #> WRF-CMAQ sub domain time series ending column #setenv SD_SROW 160 #> WRF-CMAQ sub domain time series starting row #setenv SD_EROW 169 #> WRF-CMAQ sub domain time series ending row #setenv SD_CONC_SPCS "NO2 NO O3 NO3 CO ASO4J ASO4I ANH4J ANH4I ANO3J ANO3I AORGAJ AORGAI AORGPAJ AORGPAI AORGBJ AORGBI AECJ AECI A25J A25I ACORS ASEAS ASOIL" #> sub domain time series species subset list #> MPI Optimization Flags setenv MPI_SM_POOL 16000 #> increase shared memory pool in case many MPI_SEND headers setenv MP_EAGER_LIMIT 65536 #> set MPI message passing buffer size to max setenv MP_SINGLE_THREAD yes #> optimize for single threaded applications [ default: no ] setenv MP_STDOUTMODE ordered #> order output by the processor ID setenv MP_LABELIO yes #> label output by processor ID [ default: no ] setenv MP_SHARED_MEMORY yes #> force use of shared memory for tasks on same node [ default: no ] setenv MP_ADAPTER_USE shared #> share the MP adapter with other jobs setenv MP_CPU_USE multiple #> share the node with multiple users/jobs setenv MP_CSS_INTERRUPT yes #> specify whether arriving packets generate interrupts [ default: no ] # ===================================================================== #> Input Directories and Filenames # ===================================================================== set ICpath = $INPDIR/icbc #> initial conditions input directory set BCpath = $INPDIR/icbc #> boundary conditions input directory set EMISpath = $INPDIR/emis/gridded_area/gridded #> gridded emissions input directory set EMISpath2 = $INPDIR/emis/gridded_area/rwc #> gridded surface residential wood combustion emissions directory set IN_PTpath = $INPDIR/emis/inln_point #> point source emissions input directory set IN_LTpath = $INPDIR/lightning #> lightning NOx input directory set METpath = $INPDIR/WRF-CMAQ/wrfv4.1.1_inputs #> WRF Meteorology path #set JVALpath = $INPDIR/jproc #> offline photolysis rate table directory set OMIpath = $WRF_DIR/cmaq #> ozone column data for the photolysis model set LUpath = $INPDIR/land #> BELD landuse data for windblown dust model set SZpath = $INPDIR/land #> surf zone file for in-line seaspray emissions # ===================================================================== #> Begin Loop Through Simulation Days # ===================================================================== set rtarray = "" set TODAYG = ${START_DATE} set TODAYJ = `date -ud "${START_DATE}" +%Y%j` #> Convert YYYY-MM-DD to YYYYJJJ set START_DAY = ${TODAYJ} set STOP_DAY = `date -ud "${END_DATE}" +%Y%j` #> Convert YYYY-MM-DD to YYYYJJJ set NDAYS = 0 while ($TODAYJ <= $STOP_DAY ) #>Compare dates in terms of YYYYJJJ set NDAYS = `echo "${NDAYS} + 1" | bc -l` #> Retrieve Calendar day Information set YYYYMMDD = `date -ud "${TODAYG}" +%Y%m%d` #> Convert YYYY-MM-DD to YYYYMMDD set YYYYMM = `date -ud "${TODAYG}" +%Y%m` #> Convert YYYY-MM-DD to YYYYMM set YYMMDD = `date -ud "${TODAYG}" +%y%m%d` #> Convert YYYY-MM-DD to YYMMDD set YYYYJJJ = $TODAYJ #> Calculate Yesterday's Date set YESTERDAY = `date -ud "${TODAYG}-1days" +%Y%m%d` #> Convert YYYY-MM-DD to YYYYJJJ # ===================================================================== #> Set Output String and Propagate Model Configuration Documentation # ===================================================================== echo "" echo "Set up input and output files for Day ${TODAYG}." #> set output file name extensions setenv CTM_APPL ${RUNID}_${YYYYMMDD} #> Copy Model Configuration To Output Folder if ( ! -d "$OUTDIR" ) mkdir -p $OUTDIR cp $WRF_DIR/cmaq/CCTM*.cfg $OUTDIR/CCTM_${CTM_APPL}.cfg # ===================================================================== #> Input Files (Some are Day-Dependent) # ===================================================================== #> Initial conditions if ($NEW_START == true || $NEW_START == TRUE ) then setenv ICFILE ICON_20160630_bench.nc setenv INIT_MEDC_1 notused setenv INITIAL_RUN Y #related to restart soil information file #> WRF-CMAQ Configuration setenv WRF_RSTFLAG .false. #WRF Restart Flag setenv FEEDBACK_RSTFLAG .false. # indicates whether feedback information is available in the wrfrst file if ($cont_from_spinup_run == T) then set cont_from_spinup_run = F setenv WRF_RSTFLAG .true. #WRF Restart Flag # else # setenv FEEDBACK_RSTFLAG .true. endif setenv pxlsm_smois_init 1 else set ICpath = $OUTDIR setenv ICFILE CCTM_CGRID_${RUNID}_${YESTERDAY}.nc setenv INIT_MEDC_1 $ICpath/CCTM_MEDIA_CONC_${RUNID}_${YESTERDAY}.nc setenv INITIAL_RUN N #> WRF-CMAQ Configuration setenv WRF_RSTFLAG .true. #WRF Restart Flag setenv FEEDBACK_RSTFLAG .true. # indicates whether feedback information is available in the wrfrst file if ($cont_from_spinup_run == T) then set cont_from_spinup_run = F setenv WRF_RSTFLAG .true. #WRF Restart Flag setenv FEEDBACK_RSTFLAG .false. # indicates whether feedback information is available in the wrfrst file else setenv FEEDBACK_RSTFLAG .true. endif setenv pxlsm_smois_init 0 endif #> Boundary conditions set BCFILE = BCON_${YYYYMMDD}_bench.nc #> Off-line photolysis rates #set JVALfile = JTABLE_${YYYYJJJ} #> Ozone column data set OMIfile = OMI_1979_to_2019.dat #> Optics file set OPTfile = PHOT_OPTICS.dat #> MCIP meteorology files setenv GRID_BDY_2D BUFFERED # GRID files are static, not day-specific setenv GRID_CRO_2D BUFFERED setenv GRID_CRO_3D BUFFERED setenv GRID_DOT_2D BUFFERED setenv MET_CRO_2D BUFFERED setenv MET_CRO_3D BUFFERED setenv MET_DOT_3D BUFFERED setenv MET_BDY_3D BUFFERED #setenv LUFRAC_CRO BUFFERED #> Emissions Control File #> #> IMPORTANT NOTE #> #> The emissions control file defined below is an integral part of controlling the behavior of the model simulation. #> Among other things, it controls the mapping of species in the emission files to chemical species in the model and #> several aspects related to the simulation of organic aerosols. #> Please carefully review the emissions control file to ensure that it is configured to be consistent with the assumptions #> made when creating the emission files defined below and the desired representation of organic aerosols. #> For further information, please see: #> + AERO7 Release Notes section on 'Required emission updates': #> https://github.com/USEPA/CMAQ/blob/master/DOCS/Release_Notes/aero7_overview.md #> + CMAQ User's Guide section 6.9.3 on 'Emission Compatability': #> https://github.com/USEPA/CMAQ/blob/master/DOCS/Users_Guide/CMAQ_UG_ch06_model_configuration_options.md#6.9.3_Emission_Compatability #> + Emission Control (DESID) Documentation in the CMAQ User's Guide: #> https://github.com/USEPA/CMAQ/blob/master/DOCS/Users_Guide/Appendix/CMAQ_UG_appendixB_emissions_control.md #> setenv EMISSCTRL_NML ${WRF_DIR}/cmaq/EmissCtrl_${MECH}.nml #> Spatial Masks For Emissions Scaling setenv CMAQ_MASKS $SZpath/12US1_surf_bench.nc #> horizontal grid-dependent surf zone file #> Gridded Emissions Files setenv N_EMIS_GR 2 set EMISfile = emis_mole_all_${YYYYMMDD}_cb6_bench.nc setenv GR_EMIS_001 ${EMISpath}/${EMISfile} setenv GR_EMIS_LAB_001 GRIDDED_EMIS setenv GR_EM_SYM_DATE_001 F set EMISfile = emis_mole_rwc_${YYYYMMDD}_12US1_cmaq_cb6_2016ff_16j.nc setenv GR_EMIS_002 ${EMISpath2}/${EMISfile} setenv GR_EMIS_LAB_002 GRIDDED_RWC setenv GR_EM_SYM_DATE_002 F #> In-line point emissions configuration setenv N_EMIS_PT 8 #> Number of elevated source groups set STKCASEG = 12US1_2016ff_16j # Stack Group Version Label set STKCASEE = 12US1_cmaq_cb6_2016ff_16j # Stack Emission Version Label # Time-Independent Stack Parameters for Inline Point Sources setenv STK_GRPS_001 $IN_PTpath/stack_groups/stack_groups_ptnonipm_${STKCASEG}.nc setenv STK_GRPS_002 $IN_PTpath/stack_groups/stack_groups_ptegu_${STKCASEG}.nc setenv STK_GRPS_003 $IN_PTpath/stack_groups/stack_groups_othpt_${STKCASEG}.nc setenv STK_GRPS_004 $IN_PTpath/stack_groups/stack_groups_ptagfire_${YYYYMMDD}_${STKCASEG}.nc setenv STK_GRPS_005 $IN_PTpath/stack_groups/stack_groups_ptfire_${YYYYMMDD}_${STKCASEG}.nc setenv STK_GRPS_006 $IN_PTpath/stack_groups/stack_groups_ptfire_othna_${YYYYMMDD}_${STKCASEG}.nc setenv STK_GRPS_007 $IN_PTpath/stack_groups/stack_groups_pt_oilgas_${STKCASEG}.nc setenv STK_GRPS_008 $IN_PTpath/stack_groups/stack_groups_cmv_c3_${STKCASEG}.nc # Emission Rates for Inline Point Sources setenv STK_EMIS_001 $IN_PTpath/ptnonipm/inln_mole_ptnonipm_${YYYYMMDD}_${STKCASEE}.nc setenv STK_EMIS_002 $IN_PTpath/ptegu/inln_mole_ptegu_${YYYYMMDD}_${STKCASEE}.nc setenv STK_EMIS_003 $IN_PTpath/othpt/inln_mole_othpt_${YYYYMMDD}_${STKCASEE}.nc setenv STK_EMIS_004 $IN_PTpath/ptagfire/inln_mole_ptagfire_${YYYYMMDD}_${STKCASEE}.nc setenv STK_EMIS_005 $IN_PTpath/ptfire/inln_mole_ptfire_${YYYYMMDD}_${STKCASEE}.nc setenv STK_EMIS_006 $IN_PTpath/ptfire_othna/inln_mole_ptfire_othna_${YYYYMMDD}_${STKCASEE}.nc setenv STK_EMIS_007 $IN_PTpath/pt_oilgas/inln_mole_pt_oilgas_${YYYYMMDD}_${STKCASEE}.nc setenv STK_EMIS_008 $IN_PTpath/cmv_c3/inln_mole_cmv_c3_${YYYYMMDD}_${STKCASEE}.nc # Label Each Emissions Stream setenv STK_EMIS_LAB_001 POINT_NONEGU setenv STK_EMIS_LAB_002 POINT_EGU setenv STK_EMIS_LAB_003 POINT_OTHER setenv STK_EMIS_LAB_004 POINT_AGFIRES setenv STK_EMIS_LAB_005 POINT_FIRES setenv STK_EMIS_LAB_006 POINT_OTHFIRES setenv STK_EMIS_LAB_007 POINT_OILGAS setenv STK_EMIS_LAB_008 POINT_CMV # Stack emissions diagnostic files #setenv STK_EMIS_DIAG_001 2DSUM #setenv STK_EMIS_DIAG_002 2DSUM #setenv STK_EMIS_DIAG_003 2DSUM #setenv STK_EMIS_DIAG_004 2DSUM #setenv STK_EMIS_DIAG_005 2DSUM # Allow CMAQ to Use Point Source files with dates that do not # match the internal model date setenv STK_EM_SYM_DATE_001 T setenv STK_EM_SYM_DATE_002 T setenv STK_EM_SYM_DATE_003 T setenv STK_EM_SYM_DATE_004 T setenv STK_EM_SYM_DATE_005 T setenv STK_EM_SYM_DATE_006 T setenv STK_EM_SYM_DATE_007 T setenv STK_EM_SYM_DATE_008 T #> Lightning NOx configuration if ( $CTM_LTNG_NO == 'Y' ) then setenv LTNGNO "InLine" #> set LTNGNO to "Inline" to activate in-line calculation #> In-line lightning NOx options setenv USE_NLDN Y #> use hourly NLDN strike file [ default: Y ] if ( $USE_NLDN == Y ) then setenv NLDN_STRIKES ${IN_LTpath}/NLDN.12US1.${YYYYMMDD}_bench.nc endif setenv LTNGPARMS_FILE ${IN_LTpath}/LTNG_AllParms_12US1_bench.nc #> lightning parameter file endif #> In-line biogenic emissions configuration if ( $CTM_BIOGEMIS == 'Y' ) then set IN_BEISpath = ${INPDIR}/land setenv GSPRO $WRF_DIR/cmaq/gspro_biogenics.txt setenv B3GRD $IN_BEISpath/b3grd_bench.nc setenv BIOSW_YN Y #> use frost date switch [ default: Y ] setenv BIOSEASON $IN_BEISpath/bioseason.cmaq.2016_12US1_full_bench.ncf #> ignore season switch file if BIOSW_YN = N setenv SUMMER_YN Y #> Use summer normalized emissions? [ default: Y ] setenv PX_VERSION Y #> MCIP is PX version? [ default: N ] setenv SOILINP $OUTDIR/CCTM_SOILOUT_${RUNID}_${YESTERDAY}.nc #> Biogenic NO soil input file; ignore if INITIAL_RUN = Y endif #> Windblown dust emissions configuration if ( $CTM_WB_DUST == 'Y' ) then # Input variables for BELD3 Landuse option setenv DUST_LU_1 $LUpath/beld3_12US1_459X299_output_a_bench.nc setenv DUST_LU_2 $LUpath/beld4_12US1_459X299_output_tot_bench.nc endif #> In-line sea spray emissions configuration setenv OCEAN_1 $SZpath/12US1_surf_bench.nc #> horizontal grid-dependent surf zone file #> Bidirectional ammonia configuration if ( $CTM_ABFLUX == 'Y' ) then setenv E2C_SOIL ${LUpath}/epic_festc1.4_20180516/2016_US1_soil_bench.nc setenv E2C_CHEM ${LUpath}/epic_festc1.4_20180516/2016_US1_time${YYYYMMDD}_bench.nc setenv E2C_CHEM_YEST ${LUpath}/epic_festc1.4_20180516/2016_US1_time${YESTERDAY}_bench.nc setenv E2C_LU ${LUpath}/beld4_12kmCONUS_2011nlcd_bench.nc endif #> Inline Process Analysis setenv CTM_PROCAN N #> use process analysis [ default: N] if ( $?CTM_PROCAN ) then # $CTM_PROCAN is defined if ( $CTM_PROCAN == 'Y' || $CTM_PROCAN == 'T' ) then #> process analysis global column, row and layer ranges # setenv PA_BCOL_ECOL "10 90" # default: all columns # setenv PA_BROW_EROW "10 80" # default: all rows # setenv PA_BLEV_ELEV "1 4" # default: all levels setenv PACM_INFILE ${NMLpath}/pa_${MECH}.ctl setenv PACM_REPORT $OUTDIR/"PA_REPORT".${YYYYMMDD} endif endif #> Integrated Source Apportionment Method (ISAM) Options setenv CTM_ISAM N if ( $?CTM_ISAM ) then if ( $CTM_ISAM == 'Y' || $CTM_ISAM == 'T' ) then setenv SA_IOLIST ${INPDIR}/isam_control.txt setenv ISAM_BLEV_ELEV " 1 1" setenv AISAM_BLEV_ELEV " 1 1" #> Set Up ISAM Initial Condition Flags if ($NEW_START == true || $NEW_START == TRUE ) then setenv ISAM_NEW_START Y setenv ISAM_PREVDAY else setenv ISAM_NEW_START N setenv ISAM_PREVDAY "$OUTDIR/CCTM_SA_CGRID_${RUNID}_${YESTERDAY}.nc" endif #> Set Up ISAM Output Filenames setenv SA_ACONC_1 "$OUTDIR/CCTM_SA_ACONC_${CTM_APPL}.nc -v" setenv SA_CONC_1 "$OUTDIR/CCTM_SA_CONC_${CTM_APPL}.nc -v" setenv SA_DD_1 "$OUTDIR/CCTM_SA_DRYDEP_${CTM_APPL}.nc -v" setenv SA_WD_1 "$OUTDIR/CCTM_SA_WETDEP_${CTM_APPL}.nc -v" setenv SA_CGRID_1 "$OUTDIR/CCTM_SA_CGRID_${CTM_APPL}.nc -v" #> Set optional ISAM regions files # setenv ISAM_REGIONS /work/MOD3EVAL/nsu/isam_v53/CCTM/scripts/input/RGN_ISAM.nc endif endif #> Sulfur Tracking Model (STM) setenv STM_SO4TRACK N #> sulfur tracking [ default: N ] if ( $?STM_SO4TRACK ) then if ( $STM_SO4TRACK == 'Y' || $STM_SO4TRACK == 'T' ) then #> option to normalize sulfate tracers [ default: Y ] setenv STM_ADJSO4 Y endif endif # ===================================================================== #> Output Files # ===================================================================== #> set output file names setenv S_CGRID "$OUTDIR/CCTM_CGRID_${CTM_APPL}.nc" #> 3D Inst. Concentrations setenv CTM_CONC_1 "$OUTDIR/CCTM_CONC_${CTM_APPL}.nc -v" #> On-Hour Concentrations setenv A_CONC_1 "$OUTDIR/CCTM_ACONC_${CTM_APPL}.nc -v" #> Hourly Avg. Concentrations setenv MEDIA_CONC "$OUTDIR/CCTM_MEDIA_CONC_${CTM_APPL}.nc -v" #> NH3 Conc. in Media setenv CTM_DRY_DEP_1 "$OUTDIR/CCTM_DRYDEP_${CTM_APPL}.nc -v" #> Hourly Dry Deposition setenv CTM_DEPV_DIAG "$OUTDIR/CCTM_DEPV_${CTM_APPL}.nc -v" #> Dry Deposition Velocities setenv B3GTS_S "$OUTDIR/CCTM_B3GTS_S_${CTM_APPL}.nc -v" #> Biogenic Emissions setenv SOILOUT "$OUTDIR/CCTM_SOILOUT_${CTM_APPL}.nc" #> Soil Emissions setenv CTM_WET_DEP_1 "$OUTDIR/CCTM_WETDEP1_${CTM_APPL}.nc -v" #> Wet Dep From All Clouds setenv CTM_WET_DEP_2 "$OUTDIR/CCTM_WETDEP2_${CTM_APPL}.nc -v" #> Wet Dep From SubGrid Clouds setenv CTM_PMDIAG_1 "$OUTDIR/CCTM_PMDIAG_${CTM_APPL}.nc -v" #> On-Hour Particle Diagnostics setenv CTM_APMDIAG_1 "$OUTDIR/CCTM_APMDIAG_${CTM_APPL}.nc -v" #> Hourly Avg. Particle Diagnostics setenv CTM_RJ_1 "$OUTDIR/CCTM_PHOTDIAG1_${CTM_APPL}.nc -v" #> 2D Surface Summary from Inline Photolysis setenv CTM_RJ_2 "$OUTDIR/CCTM_PHOTDIAG2_${CTM_APPL}.nc -v" #> 3D Photolysis Rates setenv CTM_RJ_3 "$OUTDIR/CCTM_PHOTDIAG3_${CTM_APPL}.nc -v" #> 3D Optical and Radiative Results from Photolysis setenv CTM_SSEMIS_1 "$OUTDIR/CCTM_SSEMIS_${CTM_APPL}.nc -v" #> Sea Spray Emissions setenv CTM_DUST_EMIS_1 "$OUTDIR/CCTM_DUSTEMIS_${CTM_APPL}.nc -v" #> Dust Emissions setenv CTM_IPR_1 "$OUTDIR/CCTM_PA_1_${CTM_APPL}.nc -v" #> Process Analysis setenv CTM_IPR_2 "$OUTDIR/CCTM_PA_2_${CTM_APPL}.nc -v" #> Process Analysis setenv CTM_IPR_3 "$OUTDIR/CCTM_PA_3_${CTM_APPL}.nc -v" #> Process Analysis setenv CTM_IRR_1 "$OUTDIR/CCTM_IRR_1_${CTM_APPL}.nc -v" #> Chem Process Analysis setenv CTM_IRR_2 "$OUTDIR/CCTM_IRR_2_${CTM_APPL}.nc -v" #> Chem Process Analysis setenv CTM_IRR_3 "$OUTDIR/CCTM_IRR_3_${CTM_APPL}.nc -v" #> Chem Process Analysis setenv CTM_DRY_DEP_MOS "$OUTDIR/CCTM_DDMOS_${CTM_APPL}.nc -v" #> Dry Dep setenv CTM_DRY_DEP_FST "$OUTDIR/CCTM_DDFST_${CTM_APPL}.nc -v" #> Dry Dep setenv CTM_DEPV_MOS "$OUTDIR/CCTM_DEPVMOS_${CTM_APPL}.nc -v" #> Dry Dep Velocity setenv CTM_DEPV_FST "$OUTDIR/CCTM_DEPVFST_${CTM_APPL}.nc -v" #> Dry Dep Velocity setenv CTM_VDIFF_DIAG "$OUTDIR/CCTM_VDIFF_DIAG_${CTM_APPL}.nc -v" #> Vertical Dispersion Diagnostic setenv CTM_VSED_DIAG "$OUTDIR/CCTM_VSED_DIAG_${CTM_APPL}.nc -v" #> Particle Grav. Settling Velocity setenv CTM_LTNGDIAG_1 "$OUTDIR/CCTM_LTNGHRLY_${CTM_APPL}.nc -v" #> Hourly Avg Lightning NO setenv CTM_LTNGDIAG_2 "$OUTDIR/CCTM_LTNGCOL_${CTM_APPL}.nc -v" #> Column Total Lightning NO setenv CTM_VEXT_1 "$OUTDIR/CCTM_VEXT_${CTM_APPL}.nc -v" #> On-Hour 3D Concs at select sites # this is for creating physical files setenv PGRID_DOT_2D "$OUTDIR/GRID_DOT_2D_${CTM_APPL}.nc -v" setenv PGRID_CRO_2D "$OUTDIR/GRID_CRO_2D_${CTM_APPL}.nc -v" setenv PMET_CRO_2D "$OUTDIR/MET_CRO_2D_${CTM_APPL}.nc -v" setenv PMET_DOT_3D "$OUTDIR/MET_DOT_2D_${CTM_APPL}.nc -v" setenv PMET_CRO_3D "$OUTDIR/MET_CRO_3D_${CTM_APPL}.nc -v" # WRF-CMAQ Files if ($SD_TIME_SERIES == T) then setenv CTM_SD_TS "$OUTDIR/SD_TSfile_${CTM_APPL}.nc -v" endif setenv LAYER_FILE MET_CRO_3D @ n = 0 while ($n < $NPROCS) set name = `printf "_%3.3d\n" $n` setenv feed_back$name BUFFERED # for feedback file @ n++ end #> set floor file (neg concs) setenv FLOOR_FILE ${OUTDIR}/FLOOR_${CTM_APPL}.txt #> look for existing log files and output files ( ls CTM_LOG_???.${CTM_APPL} > buff.txt ) >& /dev/null ( ls ${OUTDIR}/CTM_LOG_???.${CTM_APPL} >> buff.txt ) >& /dev/null set log_test = `cat buff.txt`; rm -f buff.txt set OUT_FILES = (${FLOOR_FILE} ${S_CGRID} ${CTM_CONC_1} ${A_CONC_1} ${MEDIA_CONC} \ ${CTM_DRY_DEP_1} $CTM_DEPV_DIAG $B3GTS_S $SOILOUT $CTM_WET_DEP_1\ $CTM_WET_DEP_2 $CTM_PMDIAG_1 $CTM_APMDIAG_1 \ $CTM_RJ_1 $CTM_RJ_2 $CTM_RJ_3 $CTM_SSEMIS_1 $CTM_DUST_EMIS_1 $CTM_IPR_1 $CTM_IPR_2 \ $CTM_IPR_3 $CTM_IRR_1 $CTM_IRR_2 $CTM_IRR_3 $CTM_DRY_DEP_MOS \ $CTM_DRY_DEP_FST $CTM_DEPV_MOS $CTM_DEPV_FST $CTM_VDIFF_DIAG $CTM_VSED_DIAG \ $CTM_LTNGDIAG_1 $CTM_LTNGDIAG_2 $CTM_VEXT_1 ) if ( $?CTM_ISAM ) then if ( $CTM_ISAM == 'Y' || $CTM_ISAM == 'T' ) then set OUT_FILES = (${OUT_FILES} ${SA_ACONC_1} ${SA_CONC_1} ${SA_DD_1} ${SA_WD_1} \ ${SA_CGRID_1} ) endif endif set OUT_FILES = `echo $OUT_FILES | sed "s; -v;;g" | sed "s;MPI:;;g" ` ( ls $OUT_FILES > buff.txt ) >& /dev/null set out_test = `cat buff.txt`; rm -f buff.txt #> delete previous output if requested if ( $CLOBBER_DATA == true || $CLOBBER_DATA == TRUE ) then echo echo "Existing Logs and Output Files for Day ${TODAYG} Will Be Deleted" #> remove previous log files foreach file ( ${log_test} ) #echo "Deleting log file: $file" /bin/rm -f $file end #> remove previous output files foreach file ( ${out_test} ) #echo "Deleting output file: $file" /bin/rm -f $file end /bin/rm -f ${OUTDIR}/CCTM_EMDIAG*${RUNID}_${YYYYMMDD}.nc else #> error if previous log files exist if ( "$log_test" != "" ) then echo "*** Logs exist - run ABORTED ***" echo "*** To overide, set CLOBBER_DATA = TRUE in run_cctm.csh ***" echo "*** and these files will be automatically deleted. ***" exit 1 endif #> error if previous output files exist if ( "$out_test" != "" ) then echo "*** Output Files Exist - run will be ABORTED ***" foreach file ( $out_test ) echo " cannot delete $file" end echo "*** To overide, set CLOBBER_DATA = TRUE in run_cctm.csh ***" echo "*** and these files will be automatically deleted. ***" exit 1 endif endif #> for the run control ... setenv CTM_STDATE $YYYYJJJ setenv CTM_STTIME $STTIME setenv CTM_RUNLEN $NSTEPS setenv CTM_TSTEP $TSTEP setenv INIT_CONC_1 $ICpath/$ICFILE setenv BNDY_CONC_1 $BCpath/$BCFILE setenv OMI $OMIpath/$OMIfile setenv OPTICS_DATA $OMIpath/$OPTfile #setenv XJ_DATA $JVALpath/$JVALfile #> species defn & photolysis setenv gc_matrix_nml ${NMLpath}/GC_$MECH.nml setenv ae_matrix_nml ${NMLpath}/AE_$MECH.nml setenv nr_matrix_nml ${NMLpath}/NR_$MECH.nml setenv tr_matrix_nml ${NMLpath}/Species_Table_TR_0.nml #> check for photolysis input data setenv CSQY_DATA ${NMLpath}/CSQY_DATA_$MECH if (! (-e $CSQY_DATA ) ) then echo " $CSQY_DATA not found " exit 1 endif if (! (-e $OPTICS_DATA ) ) then echo " $OPTICS_DATA not found " exit 1 endif cd $OUTDIR # =================================================================== #> Building WRF Namelist. # =================================================================== if ( -f namelist.input ) rm -f namelist.input cat << End_Of_Namelist > namelist.input &time_control run_hours = $wrf_hr, run_minutes = $wrf_min, run_seconds = $wrf_sec, start_year = `date -ud "${TODAYG}" +%Y`, start_month = `date -ud "${TODAYG}" +%m`, start_day = `date -ud "${TODAYG}" +%d`, start_hour = `date -ud "$wrf_date" +%H`, start_minute = `date -ud "$wrf_date" +%M`, start_second = `date -ud "$wrf_date" +%S`, interval_seconds = 10800, input_from_file = .true., HISTORY_INTERVAL = 60, FRAMES_PER_OUTFILE = 25, restart = $WRF_RSTFLAG, restart_interval = $wrf_restart_interval, write_hist_at_0h_rst = .true., io_form_history = 2, io_form_restart = 2, io_form_input = 2, io_form_boundary = 2, io_form_auxinput2 = 2, io_form_auxinput4 = 2, debug_level = 0, auxinput1_inname = "met_em.d01.", auxinput4_inname = "wrflowinp_d01", auxinput4_interval = 360, auxinput4_end_h = 1000000, reset_simulation_start = .false., iofields_filename = "output.var.txt", / &domains time_step = $wrf_tstep, time_step_fract_num = 0, time_step_fract_den = 1, max_dom = 1, s_we = 1, e_we = $WRF_COL_DIM, s_sn = 1, e_sn = $WRF_ROW_DIM, s_vert = 1, e_vert = $WRF_LAY_DIM, p_top_requested = 5000, eta_levels = 1.000, 0.9975, 0.995, 0.990, 0.985, 0.980, 0.970, 0.960, 0.950, 0.940, 0.930, 0.920, 0.910, 0.900, 0.880, 0.860, 0.840, 0.820, 0.800, 0.770, 0.740, 0.700, 0.650, 0.600, 0.550, 0.500, 0.450, 0.400, 0.350, 0.300, 0.250, 0.200, 0.150, 0.100, 0.050, 0.000 num_metgrid_levels = 40, dx = 12000, dy = 12000, grid_id = 1, parent_id = 0, i_parent_start = 0, j_parent_start = 0, parent_grid_ratio = 1, parent_time_step_ratio = 1, feedback = 1, smooth_option = 0, / &physics mp_physics = 10, mp_zero_out = 2, mp_zero_out_thresh = 1.0e-8, ra_lw_physics = 4, ra_sw_physics = 4, radt = $radt, co2tf = 1, sf_sfclay_physics = 7, num_soil_layers = 2, pxlsm_smois_init = $pxlsm_smois_init, pxlsm_modis_veg = 1, sf_surface_physics = 7, sf_urban_physics = 0, bl_pbl_physics = 7, bldt = 0, cu_physics = 1, kfeta_trigger = 2 cudt = 0, ishallow = 0, shcu_physics = 0, prec_acc_dt = 60, isfflx = 1, ifsnow = 1, icloud = 1, cu_rad_feedback = .true., surface_input_source = 1, num_land_cat = $NUM_LAND_USE_TYPE, num_soil_cat = 16, sst_update = 1, seaice_threshold = 100, slope_rad = 1, topo_shading = 1, shadlen = 25000., do_radar_ref = 1, grav_settling = 0, / &fdda grid_fdda = 1, grid_sfdda = 1, gfdda_inname = "wrffdda_d", sgfdda_inname = "wrfsfdda_d", pxlsm_soil_nudge = 1, sgfdda_end_h = 1000000, sgfdda_interval_m = 180, GFDDA_END_H = 1000000, gfdda_interval_m = 180, fgdt = 0, if_no_pbl_nudging_uv = 1, if_no_pbl_nudging_t = 1, if_no_pbl_nudging_q = 1, if_zfac_uv = 0, k_zfac_uv = 13, if_zfac_t = 0, k_zfac_t = 13, if_zfac_q = 0, k_zfac_q = 13, guv = 0.0001, gt = 0.0001, gq = 0.00001, guv_sfc = 0.0000, gt_sfc = 0.0000, gq_sfc = 0.0000, if_ramping = 1, dtramp_min = 60.0, io_form_gfdda = 2, rinblw = 250.0 / &dynamics hybrid_opt = 2, w_damping = 1, diff_opt = 1, km_opt = 4, diff_6th_opt = 2, diff_6th_factor = 0.12, damp_opt = 3, base_temp = 290. zdamp = 5000., dampcoef = 0.05, khdif = 0, kvdif = 0, non_hydrostatic = .true., moist_adv_opt = 2, tke_adv_opt = 2, scalar_adv_opt = 2, use_theta_m = 1, / &bdy_control spec_bdy_width = 5, spec_zone = 1, relax_zone = 4, specified = .true., spec_exp = 0.0, nested = .false., / &grib2 / &namelist_quilt nio_tasks_per_group = 0, nio_groups = 1, / End_Of_Namelist rm -f wrfbdy_d01 wrffdda_d01 wrfsfdda_d01 wrfinput_d01 wrflowinp_d01 ln -sf $METpath/wrfbdy_d01 wrfbdy_d01 ln -sf $METpath/wrffdda_d01 wrffdda_d01 ln -sf $METpath/wrfsfdda_d01 wrfsfdda_d01 if (${WRF_RSTFLAG} == .false.) then ln -sf $METpath/wrfinput_d01 wrfinput_d01 endif ln -sf $METpath/wrflowinp_d01 wrflowinp_d01 #----------------------------------------------------------------------- # Set up and run WRF-EM executable. #----------------------------------------------------------------------- if ( -f wrf.exe ) rm -f wrf.exe if ( -f ETAMPNEW_DATA ) rm -f ETAMPNEW_DATA if ( -f GENPARM.TBL ) rm -f GENPARM.TBL if ( -f landFilenames ) rm -f landFilenames if ( -f LANDUSE.TBL ) rm -f LANDUSE.TBL if ( -f RRTM_DATA ) rm -f RRTM_DATA if ( -f SOILPARM.TBL ) rm -f SOILPARM.TBL if ( -f tr49t67 ) rm -f tr49t67 if ( -f tr49t85 ) rm -f tr49t85 if ( -f tr67t85 ) rm -f tr67t85 if ( -f VEGPARM.TBL ) rm -f VEGPARM.TBL ln -s $WRF_DIR/main/wrf.exe wrf.exe ln -s $WRF_DIR/test/em_real/ETAMPNEW_DATA ETAMPNEW_DATA ln -s $WRF_DIR/test/em_real/GENPARM.TBL GENPARM.TBL ln -s $WRF_DIR/test/em_real/landFilenames landFilenames ln -s $WRF_DIR/test/em_real/LANDUSE.TBL LANDUSE.TBL ln -s $WRF_DIR/test/em_real/RRTM_DATA RRTM_DATA ln -s $WRF_DIR/test/em_real/RRTMG_SW_DATA RRTMG_SW_DATA ln -s $WRF_DIR/test/em_real/RRTMG_LW_DATA RRTMG_LW_DATA ln -s $WRF_DIR/test/em_real/SOILPARM.TBL SOILPARM.TBL ln -s $WRF_DIR/test/em_real/tr49t67 tr49t67 ln -s $WRF_DIR/test/em_real/tr49t85 tr49t85 ln -s $WRF_DIR/test/em_real/tr67t85 tr67t85 ln -s $WRF_DIR/test/em_real/VEGPARM.TBL VEGPARM.TBL ln -s $WRF_DIR/test/em_real/ozone_plev.formatted ozone_plev.formatted ln -s $WRF_DIR/test/em_real/ozone_lat.formatted ozone_lat.formatted ln -s $WRF_DIR/test/em_real/ozone.formatted ozone.formatted # =================================================================== #> Execution Portion # =================================================================== #> Print attributes of the executable if ( $CTM_DIAG_LVL != 0 ) then ls -l $WRF_DIR/main/$EXEC size $WRF_DIR/main/$EXEC unlimit limit endif #> Print Startup Dialogue Information to Standard Out echo echo "CMAQ Processing of Day $YYYYMMDD Began at `date`" echo #> Executable call for single PE, uncomment to invoke #( /usr/bin/time -p $WRF_DIR/$EXEC ) |& tee buff_${EXECUTION_ID}.txt #> Executable call for multi PE, configure for your system # set MPI = /usr/local/intel/impi/3.2.2.006/bin64 # set MPIRUN = $MPI/mpirun # ( /usr/bin/time -p mpirun -np $NPROCS $OUTDIR/$EXEC ) |& tee buff_${EXECUTION_ID}.txt /usr/bin/time -p mpirun -np $NPROCS $OUTDIR/$EXEC #> WRF-CMAQ LOGS are combined into WRF_LOGS no CTM_LOGS_* will be generated if ( ! -e $OUTDIR/${TODAYJ}) then mkdir $OUTDIR/${TODAYJ} endif mv rsl.* $OUTDIR/${TODAYJ} if ($CREATE_PHYSICAL_FILE == T) then mv MET* $OUTDIR/$today mv GRI* $OUTDIR/$today endif if ( $CTM_DIAG_LVL != 0 ) then mv CTM_DIAG_???.${CTM_APPL} $OUTDIR/${TODAYJ} endif #> The next simulation day will, by definition, be a restart setenv NEW_START false #> Increment both Gregorian and Julian Days set TODAYG = `date -ud "${TODAYG}+1days" +%Y-%m-%d` #> Add a day for tomorrow set TODAYJ = `date -ud "${TODAYG}" +%Y%j` #> Convert YYYY-MM-DD to YYYYJJJ end #Loop to the next Simulation Day