4: 4: ======================================================================== 4: Begin execution of tiegcm1.95 at 01/12/14 12:49:53 4: Host = puffin 4: System = LINUX 4: Logname = emery 4: ======================================================================== 4: 4: init_timer: level= 1 rtc=F sys=T 4: mp_init: ntask= 8 mytid= 4 4: Current working directory (cwd) = /hao/aim3/emery/tiegcm_w05afrl/tiegcm-linux 4: Process ID (pid) = 19116 4: 4: Reading input data... 4: 4: 4: mkntask: i= 1 j= 8 i*j= 8 ntask= 8 4: mkntask: i= 2 j= 4 i*j= 8 ntask= 8 4: mkntask: i= 4 j= 2 i*j= 8 ntask= 8 4: mkntask: i= 8 j= 1 i*j= 8 ntask= 8 4: Input: mkntask chose ntask_lon= 4 ntask_lat= 2 (ntask= 8) 4: Will use the Weimer 2005 potential model 4: wei05sc_ncfile=/hao/aim3/tgcm/data/wei05sc.nc 4: Note INPUT: Both gpi_ncfile and imf_ncfile are specified. 4: In this case, only f10.7 flux will be used from the gpi file. 4: Note INPUT: gpi_ncfile has been specified with Weimer convection model. 4: In this case, only f10.7 flux will be used from the gpi file. 4: Doing expansion of mss histvol paths: 4: p_w05afrl_28-29feb08_001.nc to p_w05afrl_28-29feb08_003.nc by 1 4: Doing expansion of mss histvol paths: 4: s_w05afrl_28-29feb08_001.nc to s_w05afrl_28-29feb08_009.nc by 1 4: Input: Expanded secout file s_w05afrl_28-29feb08_001.nc to 4: s_w05afrl_28-29feb08_001.nc 4: Input: Expanded secout file s_w05afrl_28-29feb08_002.nc to 4: s_w05afrl_28-29feb08_002.nc 4: Input: Expanded secout file s_w05afrl_28-29feb08_003.nc to 4: s_w05afrl_28-29feb08_003.nc 4: Input: Expanded secout file s_w05afrl_28-29feb08_004.nc to 4: s_w05afrl_28-29feb08_004.nc 4: Input: Expanded secout file s_w05afrl_28-29feb08_005.nc to 4: s_w05afrl_28-29feb08_005.nc 4: Input: Expanded secout file s_w05afrl_28-29feb08_006.nc to 4: s_w05afrl_28-29feb08_006.nc 4: Input: Expanded secout file s_w05afrl_28-29feb08_007.nc to 4: s_w05afrl_28-29feb08_007.nc 4: Input: Expanded secout file s_w05afrl_28-29feb08_008.nc to 4: s_w05afrl_28-29feb08_008.nc 4: Input: Expanded secout file s_w05afrl_28-29feb08_009.nc to 4: s_w05afrl_28-29feb08_009.nc 4: INPUT NOTE: adding mandatory field ZMAG to secondary history fields (field 37) 4: 4: ------------------------------------------------------------------------ 4: USER INPUT PARAMETERS: 4: label = tiegcm res=5.0_w05afrl 4: (optional text label for current run) 4: High-lat electric potential model: potential_model = WEIMER05 4: weimer coefs: wei05sc_ncfile = /hao/aim3/tgcm/data/wei05sc.nc 4: gpi run: gpi_ncfile = $TGCMDATA/gpi_2000001-2011212.nc 4: imf run: imf_ncfile = $TGCMDATA/imf_OMNI_2008001-2008366.nc 4: gswm migrating diurnal file: gswm_mi_di_ncfile = /hao/aim3/tgcm/data/gswm_diurn_5.0d_99km.nc 4: gswm migrating semi-diurnal file: gswm_mi_sdi_ncfile = /hao/aim3/tgcm/data/gswm_semi_5.0d_99km.nc 4: start_year = 2008 (starting calendar day) 4: start_day = 59 (starting calendar year) 4: calendar_advance = 1 (model will be advanced in calendar time starting on this day) 4: step = 90 (model timestep (seconds)) 4: ntask_lon = 4 (number of mpi tasks in longitude dimension) 4: ntask_lat = 2 (number of mpi tasks in latitude dimension) 4: total tasks = ntask_lon*ntask_lat = 8 4: source = /hao/aim3/emery/tiegcm_w05afrl/tiegcm-linux/p_w05afrl_feb08_003.nc 4: (file or mss path containing source history) 4: source_start = 59, 0, 0 (model time of source history) 4: output (primary history output files) = 4: p_w05afrl_28-29feb08_001.nc, p_w05afrl_28-29feb08_002.nc 4: p_w05afrl_28-29feb08_003.nc, 4: start (model start times) = 4: 59, 0, 0 4: stop (model stop times) = 4: 61, 0, 0 4: hist (primary history disk write frequencies) = 4: 0, 1, 0 4: Maxmimum number of histories per primary file = 17 4: secout (secondary history output files)= 4: s_w05afrl_28-29feb08_001.nc, s_w05afrl_28-29feb08_002.nc 4: s_w05afrl_28-29feb08_003.nc, s_w05afrl_28-29feb08_004.nc 4: s_w05afrl_28-29feb08_005.nc, s_w05afrl_28-29feb08_006.nc 4: s_w05afrl_28-29feb08_007.nc, s_w05afrl_28-29feb08_008.nc 4: s_w05afrl_28-29feb08_009.nc, 4: secstart (secondary history start times) = 4: 59, 0, 0 4: secstop (secondary history stop times) = 4: 61, 0, 0 4: sechist (secondary history disk write frequencies) = 4: 0, 0,15 4: secflds (secondary history fields) = 4: TN UN VN WN O1 4: NO O2 DEN NE TE 4: TI TEC POTEN UI_ExB VI_ExB 4: WI_ExB SIGMA_PED SIGMA_HAL HMF2 NMF2 4: QJOULE QJOULE_VOL QJOULE_INTEGZ ZG 4: ALFA EFLUX EX EY EZ 4: ED1 ED2 BMAG OPLUS NOP_diag 4: O2P_diag ZMAG 4: Maximum number of histories per secondary file = 25 4: Number of bytes for values of fields on secondary histories (sech_nbyte) = 4 4: eddy_dif = 0 (DOY-dependent eddy diffusion flag) 4: tide (amplitudes and phases of semidiurnal tide) = 4: 0.0E+00 0.0E+00 0.0E+00 0.0E+00 0.0E+00 0.00 0.00 0.00 0.00 0.00 4: tide2 (amplitude and phase of diurnal tide) = 4: 0.0E+00 0.00 4: aurora = 1 (0/1 flag for aurora) 4: colfac = 1.500 (collision factor) 4: If any of the following are spval ( 0.1000E+37), they will be calculated 4: during the simulation on a per timestep basis: 4: power = 0.1000E+37 (Hemispheric Power) 4: ctpoten= 0.1000E+37 (Cross-cap potential) 4: kp = 0.1000E+37 (Kp index) 4: bximf = 0.1000E+37 (BX component of IMF) 4: byimf = 0.1000E+37 (BY component of IMF) 4: bzimf = 0.1000E+37 (Bz component of IMF) 4: swvel = 0.1000E+37 (solar wind velocity) 4: swden = 0.1000E+37 (solar wind density) 4: f107 = 0.1000E+37 (F10.7 solar flux) 4: f107a = 0.1000E+37 (81-day ave F10.7 flux) 4: al = 0.1000E+37 (AL, lower auroral mag index) 4: END USER INPUT PARAMETERS 4: ------------------------------------------------------------------------ 4: 4: j= 1 itask_table(:,j)= -1 4 5 6 7 -1 4: j= 2 itask_table(:,j)= -1 -1 -1 -1 -1 -1 4: 4: mytid= 4 mytidi,j= 0 1 lat0,1= 19 36 (18) lon0,1= 1 19 (19) ncells= 342 4: 4: Task 4: 4: tasks( 4)%mytid = 4 4: tasks( 4)%mytidi= 0 4: tasks( 4)%mytidj= 1 4: tasks( 4)%nlats = 18 4: tasks( 4)%nlons = 19 4: tasks( 4)%lat0 = 19 4: tasks( 4)%lat1 = 36 4: tasks( 4)%lon0 = 1 4: tasks( 4)%lon1 = 19 4: tasks( 4)%mylats= 4: 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 4: 34 35 36 4: tasks( 4)%mylons= 4: 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 4: 16 17 18 19 4: Model version = tiegcm1.95 4: 4: Set constants: 4: nlat= 36 nlon= 72 nlev= 28 4: dz= 0.50 4: dlat= 5.00 dlon= 5.00 4: zbound (cm) = 0.963723E+07 4: zmbot, zmtop = -6.750 7.250 (bottom,top midpoint levels) 4: zibot, zitop = -7.000 7.000 (bottom,top interface levels) 4: dt = 90.00 secs 4: grav = 870.00 4: freq_3m3 = 0.3506E-04 freq_semidi= 0.1454E-03 4: dipmin = 0.170 4: check_exp = F 4: kut (for filtering) = 1 2 3 5 6 7 9 10 11 13 14 15 17 17 17 17 17 17 17 17 17 17 17 17 15 14 13 11 10 9 7 6 5 3 2 1 4: init: iyear= 2008 iday= 59 4: gswm_mi_di_ncfile = /hao/aim3/tgcm/data/gswm_diurn_5.0d_99km.nc 4: gswm_mi_sdi_ncfile = /hao/aim3/tgcm/data/gswm_semi_5.0d_99km.nc 4: hist_init: nstep=*** 4: Allocated gswm t,u,v,z (lon0:lon1,lat0:lat1) 4: Allocated private gwm t,u,v,z (lon0:lon1,lat0:lat1,nmonth,nhour) 4: allocdata: all tasks allocate fzg: nlevp1= 29 nlonp4= 76 nlat= 36 4: init_lbc: allocated subdomains tlbc, ulbc, vlbc 4: init_lbc_nm: allocated subdomains tlbc_nm, ulbc_nm, vlbc_nm 4: init_lbc: allocated globals tlbc_glb, ulbc_glb, vlbc_glb: nlonp4= 76 nlat= 36 4: init_lbc: allocated globals tlbc_nm_glb, ulbc_nm_glb, vlbc_nm_glb: nlonp4= 76 nlat= 36 4: 4: Model run initialization: 4: nstep = 1920 (Number of time steps this run) 4: iter = 56640 (Initial iteration number) 4: iyear = 2008 (Beginning calendar year) 4: iday = 59 (Beginning calendar day) 4: igswm_mi_di = 1 (If > 0, GSWM diurnal tidal database will be used.) 4: igswm_mi_sdi= 1 (If > 0, GSWM semidiurnal tidal database will be used.) 4: igswm_nm_di= 0 (If > 0, GSWM nonmigrating diurnal tidal database will be used.) 4: igswm_nm_sdi= 0 (If > 0, GSWM nonmigrating semidiurnal tidal database will be used.) 4: nlev = 28 (Number of levels (midpoints and interfaces)) 4: 4: zpmid (midpoint levels) = 4: -6.750 -6.250 -5.750 -5.250 -4.750 -4.250 -3.750 -3.250 -2.750 -2.250 4: -1.750 -1.250 -0.750 -0.250 0.250 0.750 1.250 1.750 2.250 2.750 4: 3.250 3.750 4.250 4.750 5.250 5.750 6.250 6.750 7.250 4: 4: zpint (interface levels) = 4: -7.000 -6.500 -6.000 -5.500 -5.000 -4.500 -4.000 -3.500 -3.000 -2.500 4: -2.000 -1.500 -1.000 -0.500 0.000 0.500 1.000 1.500 2.000 2.500 4: 3.000 3.500 4.000 4.500 5.000 5.500 6.000 6.500 7.000 4: 4: nmlevp1= 32 zpmag_mid (mag midpoint levels) = 4: -8.250 -7.750 -7.250 -6.750 -6.250 -5.750 -5.250 -4.750 -4.250 -3.750 4: -3.250 -2.750 -2.250 -1.750 -1.250 -0.750 -0.250 0.250 0.750 1.250 4: 1.750 2.250 2.750 3.250 3.750 4.250 4.750 5.250 5.750 6.250 4: 6.750 7.250 4: 4: nmlevp1= 32 zpmag_int (mag interface levels) = 4: -8.500 -8.000 -7.500 -7.000 -6.500 -6.000 -5.500 -5.000 -4.500 -4.000 4: -3.500 -3.000 -2.500 -2.000 -1.500 -1.000 -0.500 0.000 0.500 1.000 4: 1.500 2.000 2.500 3.000 3.500 4.000 4.500 5.000 5.500 6.000 4: 6.500 7.000 4: 4: This is an initial run: 4: start_year = 2008 (Starting year of initial run) 4: start_day = 59 (Starting day of initial run) 4: start_mtime= 59 0 0 (Starting mtime of initial run) 4: 4: Primary Histories: 4: nsource = 1 (If > 0, a primary source history was provided) 4: nseries_prim = 1 (Number of primary time series) 4: nhist_total = 49 (Number of primary histories to be written) 4: nfiles_prim = 3 (Number of primary output files to be written) 4: mxhist_prim = 17 (Maximum number of primary histories per file) 4: 4: Secondary Histories: 4: nseries_sech = 1 (Number of secondary time series) 4: nsech_total = 193 (Number of secondary histories to be written) 4: nfiles_sech = 8 (Number of secondary output files to be written) 4: mxhist_sech = 25 (Maximum number of secondary histories per file) 4: nfsech = 37 (Number of requested secondary history fields) 4: secondary history field 1: TN 4: secondary history field 2: UN 4: secondary history field 3: VN 4: secondary history field 4: WN 4: secondary history field 5: O1 4: secondary history field 6: NO 4: secondary history field 7: O2 4: secondary history field 8: DEN 4: secondary history field 9: NE 4: secondary history field 10: TE 4: secondary history field 11: TI 4: secondary history field 12: TEC 4: secondary history field 13: POTEN 4: secondary history field 14: UI_ExB 4: secondary history field 15: VI_ExB 4: secondary history field 16: WI_ExB 4: secondary history field 17: SIGMA_PED 4: secondary history field 18: SIGMA_HAL 4: secondary history field 19: HMF2 4: secondary history field 20: NMF2 4: secondary history field 21: QJOULE 4: secondary history field 22: QJOULE_VOL 4: secondary history field 27: EFLUX 4: secondary history field 34: OPLUS 4: secondary history field 35: NOP_diag 4: secondary history field 36: O2P_diag 4: secondary history field 37: ZMAG 4: 4: ------------------------------------------------------------------------------------------------ 4: Table of Available Diagnostic Fields: 4: Shortnames may be added to namelist SECFLDS 4: 4: Field Shortname Units Levels Caller Longname 4: - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 4: 1 CO2_COOL erg/g/s lev newton.F CO2 Cooling 4: 2 NO_COOL erg/g/s lev newton.F NO Cooling 4: 3 DEN g/cm3 ilev dt.F Total Density 4: 4 HEATING erg/g/s lev dt.F Total Heating 4: 5 HMF2 km none elden.F HMF2: Height of the F2 Layer 4: 6 NMF2 1/cm3 none elden.F NMF2: Peak Density of the F2 Layer 4: 7 FOF2 MHz none elden.F FOF2: Critical Frequency of the F2 Layer 4: 8 JE13D A/m2 mlev current.F JE13D: Eastward current density (3d) 4: 9 JE23D A/m2 mlev current.F JE23D: Downward current density (3d) 4: 10 JQR A/m2 none current.F JQR: Upward current density (2d) 4: 11 KQLAM A/m none current.F KQLAM: Height-integrated current density (+north) 4: 12 KQPHI A/m none current.F KQPHI: Height-integrated current density (+east) 4: 13 LAMDA_HAL 1/s lev lamdas.F LAMDA_HAL: Hall Ion Drag Coefficient 4: 14 LAMDA_PED 1/s lev lamdas.F LAMDA_PED: Pedersen Ion Drag Coefficient 4: 15 MU_M g/cm/s lev cpktkm.F MU_M: Molecular Viscosity Coefficient 4: 16 QJOULE erg/g/s lev qjoule.F QJOULE: Joule Heating 4: 17 SCHT km lev addiag.F SCHT: Pressure Scale Height 4: 18 SIGMA_HAL S/m lev lamdas.F SIGMA_HAL: Hall Conductivity 4: 19 SIGMA_PED S/m lev lamdas.F SIGMA_PED: Pedersen Conductivity 4: 20 TEC 1/cm2 none elden.F TEC: Total Electron Content 4: 21 UI_ExB cm/s ilev ionvel.F UI: Zonal Ion Drift (ExB) 4: 22 VI_ExB cm/s ilev ionvel.F VI: Meridional Ion Drift (ExB) 4: 23 WI_ExB cm/s ilev ionvel.F WI: Vertical Ion Drift (ExB) 4: 24 WN cm/s ilev swdot.F WN: Neutral Vertical Wind (plus up) 4: 25 O_N2 none lev comp.F O/N2 RATIO 4: 26 QJOULE_INTEG erg/cm2/s none qjoule.F Height-integrated Joule Heating 4: 27 BX none oplus.F BX/BMAG: Normalized eastward component of magnetic field 4: 28 BY none oplus.F BY/BMAG: Normalized northward component of magnetic field 4: 29 BZ none oplus.F BZ/BMAG: Normalized upward component of magnetic field 4: 30 BMAG Gauss none oplus.F BMAG: Magnetic field magnitude 4: 31 EX V/m ilev ionvel.F EX: Geographic zonal component of electric field 4: 32 EY V/m ilev ionvel.F EY: Geographic meridional component of electric field 4: 33 EZ V/m ilev ionvel.F EZ: Geographic vertical component of electric field 4: 34 ED1 V/m imlev dynamo.F ED1: Magnetic eastward component of electric field 4: 35 ED2 V/m imlev dynamo.F ED2: Magnetic downward (equatorward) component of electric field 4: 36 PHIM2D V none dynamo.F PHIM2D: 2d Electric Potential on magnetic grid 4: ------------------------------------------------------------------------------------------------ 4: 4: 4: ------------------------------------------------------------------------ 4: Getfile: remote=/hao/aim3/emery/tiegcm_w05afrl/tiegcm-linux/p_w05afrl_feb08_003.nc 4: Getfile: Found file /hao/aim3/emery/tiegcm_w05afrl/tiegcm-linux/p_w05afrl_feb08_003.nc 4: ------------------------------------------------------------------------ 4: 4: Acquired source history file /hao/aim3/emery/tiegcm_w05afrl/tiegcm-linux/p_w05afrl_feb08_003.nc 4: (disk file is /hao/aim3/emery/tiegcm_w05afrl/tiegcm-linux/p_w05afrl_feb08_003.nc) 4: Reading source history from diskfile /hao/aim3/emery/tiegcm_w05afrl/tiegcm-linux/p_w05afrl_feb08_003.nc: 4: nc_rdhist: seeking 59 0 0 found 57 0 0 n= 1 4: nc_rdhist: seeking 59 0 0 found 58 0 0 n= 2 4: nc_rdhist: seeking 59 0 0 found 59 0 0 n= 3 4: Note nc_rdhist: unused variable: calendar_advance 4: Note nc_rdhist: unused variable: write_date 4: Note nc_rdhist: unused variable: crit1 4: Note nc_rdhist: unused variable: crit2 4: Note nc_rdhist: unused variable: mag 4: Read field TN 3d subdomain min,max= 0.1589E+03 0.8184E+03 4: Read field UN 3d subdomain min,max= -0.9371E+04 0.3026E+05 4: Read field VN 3d subdomain min,max= -0.4159E+04 0.3057E+05 4: Read field O2 3d subdomain min,max= 0.5272E-04 0.2308E+00 4: Read field O1 3d subdomain min,max= 0.3023E-02 0.9951E+00 4: Read field N4S 3d subdomain min,max= 0.5974E-10 0.1557E-01 4: Read field NO 3d subdomain min,max= 0.3518E-06 0.3382E-03 4: Read field OP 3d subdomain min,max= 0.0000E+00 0.1370E+07 4: Read field N2D 3d subdomain min,max= 0.0000E+00 0.7007E-03 4: Read field TI 3d subdomain min,max= 0.1590E+03 0.1518E+04 4: Read field TE 3d subdomain min,max= 0.1591E+03 0.3312E+04 4: Read field NE 3d subdomain min,max= 0.1643E+04 0.1337E+07 4: Read field O2P 3d subdomain min,max= 0.0000E+00 0.6377E+05 4: Read field OMEGA 3d subdomain min,max= -0.4226E-04 0.1401E-03 4: Read field Z 3d subdomain min,max= 0.9627E+07 0.5303E+08 4: Read field POTEN 3d subdomain min,max= -0.1972E+05 0.1660E+05 4: Read field TN_NM 3d subdomain min,max= 0.1590E+03 0.8218E+03 4: Read field UN_NM 3d subdomain min,max= -0.9398E+04 0.2995E+05 4: Read field VN_NM 3d subdomain min,max= -0.4181E+04 0.3064E+05 4: Read field O2_NM 3d subdomain min,max= 0.5263E-04 0.2308E+00 4: Read field O1_NM 3d subdomain min,max= 0.3022E-02 0.9951E+00 4: Read field N4S_NM 3d subdomain min,max= 0.6085E-10 0.1557E-01 4: Read field NO_NM 3d subdomain min,max= 0.3526E-06 0.3403E-03 4: Read field OP_NM 3d subdomain min,max= 0.0000E+00 0.1379E+07 4: Read LBC from source history: i= 89 sh%lbc= -7.00 4: 4: ------------------------------------------------------------------------ 4: Read TGCM PRIMARY HISTORY (source history) 4: Diskfile: /hao/aim3/emery/tiegcm_w05afrl/tiegcm-linux/p_w05afrl_feb08_003.nc 4: label = tiegcm res=5.0_w05afrl 4: model_name = tiegcm 4: model_version = tiegcm1.95 4: create_date= 01/07/14 14:21:33 4: write_date = 4: logname = emery 4: host = polar 4: system = LINUX 4: run_type = 4: source_file = 4: output_file = 4: source_mtime = 57 0 0 4: initial_year = 2008 4: initial_day = 59 4: initial_mtime= 59 0 0 4: type = primary 4: ihist = 3 (nth history on history file) 4: delhmins= 0 (delta minutes between histories) 4: calendar year,day = 2008, 59 4: (model IS being advanced in calendar time) 4: modeltime = 59, 0, 0, 0 (model time day,hour,minute,seconds) 4: time = 4: ut = 0.00 (ut hours) 4: step = 120 (time step in seconds) 4: iter = 42480 (number of steps from 0,0,0) 4: nlat = 36 (number of latitudes) 4: nlon = 72 (number of longitudes) 4: nlev = 29 (number of levels) 4: zmtop = 7.250 (top midpoint level) 4: zmbot = -6.750 (bottom midpoint level) 4: zitop = 7.000 (top interface level) 4: zibot = -7.000 (bottom interface level) 4: dtide = 0.0E+00 0.0 (amp/phase of diurnal tide) 4: sdtide = 0.0E+00 0.0E+00 0.0E+00 0.0E+00 0.0E+00 0.0 0.0 0.0 0.0 0.0 4: (amp/phase of semi-diurnal tide) 4: f107d = 0.6907E+02 (daily solar flux) 4: f107a = 0.7078E+02 (average solar flux) 4: hpower = 0.2302E+02 (Gw) 4: ctpoten = 0.4832E+02 (Volts) 4: bzimf = 0.8934E+00 4: swvel = 0.4302E+03 4: swden = 0.1136E+02 4: al = 0.1000E+37 4: e1,e2 = 0.1914E+01 0.3532E+01 (ergs/cm2/s) 4: alfac,alfad = 0.1000E+00 0.5000E+00 (keV) 4: ec,ed = 0.7885E-01 0.1501E-01 (ergs/cm2/s) 4: colfac = 0.15E+01 4: joulefac = 0.15E+01 4: p0 = 0.50E-06 4: p0_model= 0.50E-03 4: grav = 0.87E+03 4: nflds = 24 (number of model fields) 4: gswm_mi_di_ncfile = /hao/aim3/tgcm/data/gswm_diurn_5.0d_99km.nc 4: gswm_mi_sdi_ncfile = /hao/aim3/tgcm/data/gswm_semi_5.0d_99km.nc 4: gswm_nm_di_ncfile = [none] 4: gswm_nm_sdi_ncfile = [none] 4: see_ncfile = [none] 4: gpi_ncfile = /hao/aim3/tgcm/data/gpi_2000001-2011212.nc 4: ncep_ncfile = [none] 4: imf_ncfile = /hao/aim3/tgcm/data/imf_OMNI_2008001-2008366.nc 4: saber_ncfile = [none] 4: tidi_ncfile = [none] 4: tuv_lbc_intop= 0 (if 1, then lbc of t,u,v are stored in top k slot (old histories)) 4: LBC = -7.00 (lower boundary interface level) 4: ntask_mpi = 8 (number of MPI tasks) 4: coupled_cmit = 0 (1 if coupled with CISM/CMIT, 0 otherwise) 4: There are 24 fields on this history, as follows: 4: TN UN VN O2 O1 N4S NO OP 4: N2D TI TE NE O2P OMEGA Z POTEN 4: TN_NM UN_NM VN_NM O2_NM O1_NM N4S_NM NO_NM OP_NM 4: ------------------------------------------------------------------------ 4: 4: 4: Enter advance: iter= 56640 nstep= 1920 4: 4: ------------------------------------------------------------------------ 4: Getfile: remote=$TGCMDATA/gpi_2000001-2011212.nc 4: Getfile: Found file /hao/aim3/tgcm/data/gpi_2000001-2011212.nc 4: ------------------------------------------------------------------------ 4: 4: 4: ------------------------------------------------------------------------ 4: RDGPI: read GPI data file: 4: Number of days on GPI data file = 4230 4: First and last year-days = 2000003 2011210 4: Completed read from GPI data file /hao/aim3/tgcm/data/gpi_2000001-2011212.nc 4: ------------------------------------------------------------------------ 4: 4: 4: ------------------------------------------------------------------------ 4: GETGPI: get geophysical indices from data file /hao/aim3/tgcm/data/gpi_2000001-2011212.nc 4: Initial requested iyear=2008 iday= 59 iutsec= 90 4: Obtained the following GPI at the requested date and time: 4: f107 = 0.6907E+02 4: f107a = 0.7078E+02 4: power = 0.4210E+02 4: ctpoten = 0.7136E+02 4: ------------------------------------------------------------------------ 4: 4: 4: ------------------------------------------------------------------------ 4: Getfile: remote=$TGCMDATA/imf_OMNI_2008001-2008366.nc 4: Getfile: Found file /hao/aim3/tgcm/data/imf_OMNI_2008001-2008366.nc 4: ------------------------------------------------------------------------ 4: 4: 4: ------------------------------------------------------------------------ 4: RDIMF: read IMF data file: 4: Opened netcdf imf data file /hao/aim3/tgcm/data/imf_OMNI_2008001-2008366.nc 4: rdimf: date min,max= 2008001.0000 2009001.0000 4: rdimf: bx min,max= -10.92 12.74 4: rdimf: by min,max= -21.14 15.92 4: rdimf: bz min,max= -14.64 16.77 4: rdimf: swvel min,max= 262.25 812.57 4: rdimf: swden min,max= 0.73 62.56 4: ------------------------------------------------------------------------ 4: 4: 4: ------------------------------------------------------------------------ 4: Getfile: remote=/hao/aim3/tgcm/data/gswm_diurn_5.0d_99km.nc 4: Getfile: Found file /hao/aim3/tgcm/data/gswm_diurn_5.0d_99km.nc 4: ------------------------------------------------------------------------ 4: 4: 4: ------------------------------------------------------------------------ 4: Reading GSWM data file /hao/aim3/tgcm/data/gswm_diurn_5.0d_99km.nc 4: Completed read from GSWM data file /hao/aim3/tgcm/data/gswm_diurn_5.0d_99km.nc 4: 4: ------------------------------------------------------------------------ 4: 4: ------------------------------------------------------------------------ 4: Getfile: remote=/hao/aim3/tgcm/data/gswm_semi_5.0d_99km.nc 4: Getfile: Found file /hao/aim3/tgcm/data/gswm_semi_5.0d_99km.nc 4: ------------------------------------------------------------------------ 4: 4: 4: ------------------------------------------------------------------------ 4: Reading GSWM data file /hao/aim3/tgcm/data/gswm_semi_5.0d_99km.nc 4: Completed read from GSWM data file /hao/aim3/tgcm/data/gswm_semi_5.0d_99km.nc 4: 4: ------------------------------------------------------------------------ 4: 4: aurora_cons: 4: cusp: alfac= 0.100 ec= 0.079 fc= 0.2466E+09 4: drizzle: alfad= 0.500 ed= 0.015 fd= 0.9416E+07 4: auroral radius = max of rhp,rcp= 20.503 21.140 4: roth, rote (MLT) = 0.416 -0.093 4: 1/e-widths = h1,h2= 2.350 3.556 4: energy flux = e1,e2= 1.921 3.546 4: add_sproton = F 4: 4: wei05sc: completed read of file /hao/aim3/tgcm/data/wei05sc.nc 4: Step 10 of 1920 mtime= 59 0 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 10 GPI f107= 69.061 f107a= 70.784 power from bzimf,swvel= 23.531 4: 4: Allocated 3d sech field ZG(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field ZG (ix= 25): 4: short_name = ZG 4: long_name = Geometric Height ZG 4: units = cm 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field WN(lon= 76,lat= 36,lev= 29) 4: 4: Initialized diagnostic secondary history field WN (ix= 4): 4: short_name = WN 4: long_name = WN: Neutral Vertical Wind (plus up) 4: units = cm/s 4: geo = T 4: mag = F 4: dimnames = lon lat lev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field EX(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field EX (ix= 28): 4: short_name = EX 4: long_name = EX: Geographic zonal component of electric field 4: units = V/m 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field EY(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field EY (ix= 29): 4: short_name = EY 4: long_name = EY: Geographic meridional component of electric field 4: units = V/m 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field EZ(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field EZ (ix= 30): 4: short_name = EZ 4: long_name = EZ: Geographic vertical component of electric field 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field UI_ExB(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field UI_ExB (ix= 14): 4: short_name = UI_ExB 4: long_name = UI: Zonal Ion Drift (ExB) 4: units = cm/s 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field VI_ExB(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field VI_ExB (ix= 15): 4: short_name = VI_ExB 4: long_name = VI: Meridional Ion Drift (ExB) 4: units = cm/s 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field WI_ExB(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field WI_ExB (ix= 16): 4: short_name = WI_ExB 4: long_name = WI: Vertical Ion Drift (ExB) 4: units = cm/s 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field OPLUS(lon= 76,lat= 36,lev= 29) 4: 4: Initialized diagnostic secondary history field OPLUS (ix= 34): 4: short_name = OPLUS 4: long_name = O+ Ion 4: units = 4: geo = T 4: mag = F 4: dimnames = lon lat lev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 2d sech field TEC(lon= 76,lat= 36) 4: 4: Initialized diagnostic secondary history field TEC (ix= 12): 4: short_name = TEC 4: long_name = TEC: Total Electron Content 4: units = 1/cm2 4: geo = T 4: mag = F 4: dimnames = lon lat 4: dimsizes = 76 36 0 4: ndims = 2 4: task0_only = F 4: 4: Allocated 2d sech field HMF2(lon= 76,lat= 36) 4: 4: Initialized diagnostic secondary history field HMF2 (ix= 19): 4: short_name = HMF2 4: long_name = HMF2: Height of the F2 Layer 4: units = km 4: geo = T 4: mag = F 4: dimnames = lon lat 4: dimsizes = 76 36 0 4: ndims = 2 4: task0_only = F 4: 4: Allocated 2d sech field NMF2(lon= 76,lat= 36) 4: 4: Initialized diagnostic secondary history field NMF2 (ix= 20): 4: short_name = NMF2 4: long_name = NMF2: Peak Density of the F2 Layer 4: units = 1/cm3 4: geo = T 4: mag = F 4: dimnames = lon lat 4: dimsizes = 76 36 0 4: ndims = 2 4: task0_only = F 4: 4: Allocated 3d sech field NOP_diag(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field NOP_diag (ix= 35): 4: short_name = NOP_diag 4: long_name = NO+ Ion 4: units = cm^3 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field O2P_diag(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field O2P_diag (ix= 36): 4: short_name = O2P_diag 4: long_name = O2+ Ion 4: units = cm^3 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 2d sech field BMAG(lon= 76,lat= 36) 4: 4: Initialized diagnostic secondary history field BMAG (ix= 33): 4: short_name = BMAG 4: long_name = BMAG: ht independent magnetic field strength 4: units = Gauss 4: geo = T 4: mag = F 4: dimnames = lon lat 4: dimsizes = 76 36 0 4: ndims = 2 4: task0_only = F 4: 4: Allocated 3d sech field SIGMA_PED(lon= 76,lat= 36,lev= 29) 4: 4: Initialized diagnostic secondary history field SIGMA_PED (ix= 17): 4: short_name = SIGMA_PED 4: long_name = SIGMA_PED: Pedersen Conductivity 4: units = S/m 4: geo = T 4: mag = F 4: dimnames = lon lat lev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field SIGMA_HAL(lon= 76,lat= 36,lev= 29) 4: 4: Initialized diagnostic secondary history field SIGMA_HAL (ix= 18): 4: short_name = SIGMA_HAL 4: long_name = SIGMA_HAL: Hall Conductivity 4: units = S/m 4: geo = T 4: mag = F 4: dimnames = lon lat lev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field QJOULE(lon= 76,lat= 36,lev= 29) 4: 4: Initialized diagnostic secondary history field QJOULE (ix= 21): 4: short_name = QJOULE 4: long_name = QJOULE: Joule Heating 4: units = erg/g/s 4: geo = T 4: mag = F 4: dimnames = lon lat lev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 2d sech field QJOULE_INTEG(lon= 76,lat= 36) 4: 4: Initialized diagnostic secondary history field QJOULE_INTEG (ix= 23): 4: short_name = QJOULE_INTEG 4: long_name = Height-integrated Joule Heating 4: units = erg/cm2/s 4: geo = T 4: mag = F 4: dimnames = lon lat 4: dimsizes = 76 36 0 4: ndims = 2 4: task0_only = F 4: 4: Allocated 3d sech field QJOULE_VOL(lon= 76,lat= 36,lev= 29) 4: 4: Initialized diagnostic secondary history field QJOULE_VOL (ix= 22): 4: short_name = QJOULE_VOL 4: long_name = QJOULE_VOL: 3d Joule Heating per volumn 4: units = mW/m2=ergs/cm2-s 4: geo = T 4: mag = F 4: dimnames = lon lat lev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 3d sech field DEN(lon= 76,lat= 36,ilev= 29) 4: 4: Initialized diagnostic secondary history field DEN (ix= 8): 4: short_name = DEN 4: long_name = Total Density 4: units = g/cm3 4: geo = T 4: mag = F 4: dimnames = lon lat ilev 4: dimsizes = 76 36 29 4: ndims = 3 4: task0_only = F 4: 4: Allocated 2d sech field ALFA(lon= 76,lat= 36) 4: 4: Initialized diagnostic secondary history field ALFA (ix= 26): 4: short_name = ALFA 4: long_name = 2D ALFA 4: units = keV 4: geo = T 4: mag = F 4: dimnames = lon lat 4: dimsizes = 76 36 0 4: ndims = 2 4: task0_only = F 4: 4: Allocated 2d sech field EFLUX(lon= 76,lat= 36) 4: 4: Initialized diagnostic secondary history field EFLUX (ix= 27): 4: short_name = EFLUX 4: long_name = 2D EFLUX 4: units = mW/m^2 4: geo = T 4: mag = F 4: dimnames = lon lat 4: dimsizes = 76 36 0 4: ndims = 2 4: task0_only = F 4: Step 20 of 1920 mtime= 59 0 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 20 GPI f107= 69.053 f107a= 70.784 power from bzimf,swvel= 23.515 4: Step 30 of 1920 mtime= 59 0 45 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 30 GPI f107= 69.045 f107a= 70.784 power from bzimf,swvel= 23.370 4: Step 40 of 1920 mtime= 59 1 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 40 GPI f107= 69.037 f107a= 70.784 power from bzimf,swvel= 23.696 4: Step 50 of 1920 mtime= 59 1 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 50 GPI f107= 69.029 f107a= 70.784 power from bzimf,swvel= 30.861 4: Step 60 of 1920 mtime= 59 1 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 60 GPI f107= 69.021 f107a= 70.784 power from bzimf,swvel= 70.072 4: Step 70 of 1920 mtime= 59 1 45 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 70 GPI f107= 69.013 f107a= 70.785 power from bzimf,swvel= 69.077 4: Step 80 of 1920 mtime= 59 2 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 80 GPI f107= 69.006 f107a= 70.785 power from bzimf,swvel= 46.891 4: Step 90 of 1920 mtime= 59 2 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 90 GPI f107= 68.998 f107a= 70.785 power from bzimf,swvel= 42.506 4: Step 100 of 1920 mtime= 59 2 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 100 GPI f107= 68.990 f107a= 70.785 power from bzimf,swvel= 40.811 4: Step 110 of 1920 mtime= 59 2 45 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 110 GPI f107= 68.982 f107a= 70.785 power from bzimf,swvel= 24.020 4: Step 120 of 1920 mtime= 59 3 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 120 GPI f107= 68.974 f107a= 70.786 power from bzimf,swvel= 22.632 4: Step 130 of 1920 mtime= 59 3 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 130 GPI f107= 68.966 f107a= 70.786 power from bzimf,swvel= 23.170 4: Step 140 of 1920 mtime= 59 3 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 140 GPI f107= 68.958 f107a= 70.786 power from bzimf,swvel= 34.720 4: Step 150 of 1920 mtime= 59 3 45 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 150 GPI f107= 68.950 f107a= 70.786 power from bzimf,swvel= 31.306 4: Step 160 of 1920 mtime= 59 4 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 160 GPI f107= 68.942 f107a= 70.786 power from bzimf,swvel= 38.505 4: Step 170 of 1920 mtime= 59 4 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 170 GPI f107= 68.934 f107a= 70.786 power from bzimf,swvel= 43.982 4: Step 180 of 1920 mtime= 59 4 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 180 GPI f107= 68.926 f107a= 70.787 power from bzimf,swvel= 51.400 4: Step 190 of 1920 mtime= 59 4 45 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 190 GPI f107= 68.918 f107a= 70.787 power from bzimf,swvel= 43.884 4: Step 200 of 1920 mtime= 59 5 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 200 GPI f107= 68.910 f107a= 70.787 power from bzimf,swvel= 37.984 4: Step 210 of 1920 mtime= 59 5 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 210 GPI f107= 68.902 f107a= 70.787 power from bzimf,swvel= 40.391 4: Step 220 of 1920 mtime= 59 5 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 220 GPI f107= 68.895 f107a= 70.787 power from bzimf,swvel= 33.680 4: Step 230 of 1920 mtime= 59 5 45 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 230 GPI f107= 68.887 f107a= 70.788 power from bzimf,swvel= 32.130 4: Step 240 of 1920 mtime= 59 6 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 240 GPI f107= 68.879 f107a= 70.788 power from bzimf,swvel= 36.186 4: Step 250 of 1920 mtime= 59 6 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 250 GPI f107= 68.871 f107a= 70.788 power from bzimf,swvel= 33.411 4: Step 260 of 1920 mtime= 59 6 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 260 GPI f107= 68.863 f107a= 70.788 power from bzimf,swvel= 21.729 4: Step 270 of 1920 mtime= 59 6 45 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 270 GPI f107= 68.856 f107a= 70.788 power from bzimf,swvel= 21.617 4: Step 280 of 1920 mtime= 59 7 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 280 GPI f107= 68.848 f107a= 70.789 power from bzimf,swvel= 22.047 4: Step 290 of 1920 mtime= 59 7 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 290 GPI f107= 68.840 f107a= 70.789 power from bzimf,swvel= 21.621 4: Step 300 of 1920 mtime= 59 7 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 300 GPI f107= 68.832 f107a= 70.789 power from bzimf,swvel= 22.800 4: Step 310 of 1920 mtime= 59 7 45 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 310 GPI f107= 68.825 f107a= 70.789 power from bzimf,swvel= 22.712 4: Step 320 of 1920 mtime= 59 8 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 320 GPI f107= 68.817 f107a= 70.789 power from bzimf,swvel= 24.219 4: Step 330 of 1920 mtime= 59 8 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 330 GPI f107= 68.809 f107a= 70.789 power from bzimf,swvel= 25.913 4: Step 340 of 1920 mtime= 59 8 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 340 GPI f107= 68.802 f107a= 70.790 power from bzimf,swvel= 26.184 4: Step 350 of 1920 mtime= 59 8 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 350 GPI f107= 68.794 f107a= 70.790 power from bzimf,swvel= 26.204 4: Step 360 of 1920 mtime= 59 9 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 360 GPI f107= 68.787 f107a= 70.790 power from bzimf,swvel= 26.328 4: Step 370 of 1920 mtime= 59 9 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 370 GPI f107= 68.779 f107a= 70.790 power from bzimf,swvel= 25.885 4: Step 380 of 1920 mtime= 59 9 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 380 GPI f107= 68.772 f107a= 70.790 power from bzimf,swvel= 26.150 4: Step 390 of 1920 mtime= 59 9 45 0 secs/step (sys) = 0.25 4: GPI+IMF run: istep= 390 GPI f107= 68.765 f107a= 70.791 power from bzimf,swvel= 26.130 4: Step 400 of 1920 mtime= 59 10 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 400 GPI f107= 68.757 f107a= 70.791 power from bzimf,swvel= 24.603 4: Step 410 of 1920 mtime= 59 10 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 410 GPI f107= 68.750 f107a= 70.791 power from bzimf,swvel= 24.042 4: Step 420 of 1920 mtime= 59 10 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 420 GPI f107= 68.743 f107a= 70.791 power from bzimf,swvel= 60.838 4: Step 430 of 1920 mtime= 59 10 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 430 GPI f107= 68.735 f107a= 70.791 power from bzimf,swvel= 65.835 4: Step 440 of 1920 mtime= 59 11 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 440 GPI f107= 68.728 f107a= 70.791 power from bzimf,swvel= 70.173 4: Step 450 of 1920 mtime= 59 11 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 450 GPI f107= 68.721 f107a= 70.792 power from bzimf,swvel= 51.374 4: Step 460 of 1920 mtime= 59 11 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 460 GPI f107= 68.714 f107a= 70.792 power from bzimf,swvel= 36.083 4: Step 470 of 1920 mtime= 59 11 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 470 GPI f107= 68.707 f107a= 70.792 power from bzimf,swvel= 25.177 4: Step 480 of 1920 mtime= 59 12 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 480 GPI f107= 68.700 f107a= 70.792 power from bzimf,swvel= 25.057 4: Step 490 of 1920 mtime= 59 12 15 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 490 GPI f107= 68.698 f107a= 70.792 power from bzimf,swvel= 24.852 4: Step 500 of 1920 mtime= 59 12 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 500 GPI f107= 68.696 f107a= 70.792 power from bzimf,swvel= 24.928 4: Step 510 of 1920 mtime= 59 12 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 510 GPI f107= 68.693 f107a= 70.792 power from bzimf,swvel= 40.513 4: Step 520 of 1920 mtime= 59 13 0 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 520 GPI f107= 68.691 f107a= 70.792 power from bzimf,swvel= 38.104 4: Step 530 of 1920 mtime= 59 13 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 530 GPI f107= 68.689 f107a= 70.792 power from bzimf,swvel= 25.311 4: Step 540 of 1920 mtime= 59 13 30 0 secs/step (sys) = 0.23 4: GPI+IMF run: istep= 540 GPI f107= 68.687 f107a= 70.792 power from bzimf,swvel= 32.020 4: Step 550 of 1920 mtime= 59 13 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 550 GPI f107= 68.685 f107a= 70.792 power from bzimf,swvel= 25.458 4: Step 560 of 1920 mtime= 59 14 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 560 GPI f107= 68.684 f107a= 70.792 power from bzimf,swvel= 25.529 4: Step 570 of 1920 mtime= 59 14 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 570 GPI f107= 68.682 f107a= 70.792 power from bzimf,swvel= 25.224 4: Step 580 of 1920 mtime= 59 14 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 580 GPI f107= 68.680 f107a= 70.792 power from bzimf,swvel= 25.373 4: Step 590 of 1920 mtime= 59 14 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 590 GPI f107= 68.678 f107a= 70.792 power from bzimf,swvel= 29.435 4: Step 600 of 1920 mtime= 59 15 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 600 GPI f107= 68.676 f107a= 70.792 power from bzimf,swvel= 41.075 4: Step 610 of 1920 mtime= 59 15 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 610 GPI f107= 68.675 f107a= 70.792 power from bzimf,swvel= 52.713 4: Step 620 of 1920 mtime= 59 15 30 0 secs/step (sys) = 0.25 4: GPI+IMF run: istep= 620 GPI f107= 68.673 f107a= 70.792 power from bzimf,swvel= 62.528 4: Step 630 of 1920 mtime= 59 15 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 630 GPI f107= 68.671 f107a= 70.792 power from bzimf,swvel= 66.578 4: Step 640 of 1920 mtime= 59 16 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 640 GPI f107= 68.670 f107a= 70.792 power from bzimf,swvel= 62.225 4: Step 650 of 1920 mtime= 59 16 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 650 GPI f107= 68.668 f107a= 70.792 power from bzimf,swvel= 64.550 4: Step 660 of 1920 mtime= 59 16 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 660 GPI f107= 68.667 f107a= 70.792 power from bzimf,swvel= 64.265 4: Step 670 of 1920 mtime= 59 16 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 670 GPI f107= 68.665 f107a= 70.792 power from bzimf,swvel= 65.014 4: Step 680 of 1920 mtime= 59 17 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 680 GPI f107= 68.664 f107a= 70.792 power from bzimf,swvel= 69.180 4: Step 690 of 1920 mtime= 59 17 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 690 GPI f107= 68.662 f107a= 70.792 power from bzimf,swvel= 84.950 4: Step 700 of 1920 mtime= 59 17 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 700 GPI f107= 68.661 f107a= 70.792 power from bzimf,swvel= 76.846 4: Step 710 of 1920 mtime= 59 17 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 710 GPI f107= 68.659 f107a= 70.792 power from bzimf,swvel= 65.799 4: Step 720 of 1920 mtime= 59 18 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 720 GPI f107= 68.658 f107a= 70.792 power from bzimf,swvel= 67.159 4: Step 730 of 1920 mtime= 59 18 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 730 GPI f107= 68.656 f107a= 70.792 power from bzimf,swvel= 61.544 4: Step 740 of 1920 mtime= 59 18 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 740 GPI f107= 68.655 f107a= 70.792 power from bzimf,swvel= 74.875 4: Step 750 of 1920 mtime= 59 18 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 750 GPI f107= 68.654 f107a= 70.791 power from bzimf,swvel= 77.569 4: Step 760 of 1920 mtime= 59 19 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 760 GPI f107= 68.652 f107a= 70.791 power from bzimf,swvel= 77.589 4: Step 770 of 1920 mtime= 59 19 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 770 GPI f107= 68.651 f107a= 70.791 power from bzimf,swvel= 70.848 4: Step 780 of 1920 mtime= 59 19 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 780 GPI f107= 68.650 f107a= 70.791 power from bzimf,swvel= 62.194 4: Step 790 of 1920 mtime= 59 19 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 790 GPI f107= 68.648 f107a= 70.791 power from bzimf,swvel= 65.962 4: Step 800 of 1920 mtime= 59 20 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 800 GPI f107= 68.647 f107a= 70.791 power from bzimf,swvel= 53.184 4: Step 810 of 1920 mtime= 59 20 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 810 GPI f107= 68.646 f107a= 70.791 power from bzimf,swvel= 33.251 4: Step 820 of 1920 mtime= 59 20 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 820 GPI f107= 68.644 f107a= 70.791 power from bzimf,swvel= 32.504 4: Step 830 of 1920 mtime= 59 20 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 830 GPI f107= 68.643 f107a= 70.791 power from bzimf,swvel= 77.567 4: Step 840 of 1920 mtime= 59 21 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 840 GPI f107= 68.642 f107a= 70.791 power from bzimf,swvel= 74.902 4: Step 850 of 1920 mtime= 59 21 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 850 GPI f107= 68.640 f107a= 70.791 power from bzimf,swvel= 80.017 4: Step 860 of 1920 mtime= 59 21 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 860 GPI f107= 68.639 f107a= 70.791 power from bzimf,swvel= 76.616 4: Step 870 of 1920 mtime= 59 21 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 870 GPI f107= 68.638 f107a= 70.791 power from bzimf,swvel= 70.243 4: Step 880 of 1920 mtime= 59 22 0 0 secs/step (sys) = 0.26 4: GPI+IMF run: istep= 880 GPI f107= 68.636 f107a= 70.791 power from bzimf,swvel= 60.444 4: Step 890 of 1920 mtime= 59 22 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 890 GPI f107= 68.635 f107a= 70.791 power from bzimf,swvel= 35.116 4: Step 900 of 1920 mtime= 59 22 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 900 GPI f107= 68.634 f107a= 70.791 power from bzimf,swvel= 63.528 4: Step 910 of 1920 mtime= 59 22 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 910 GPI f107= 68.632 f107a= 70.791 power from bzimf,swvel= 67.874 4: Step 920 of 1920 mtime= 59 23 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 920 GPI f107= 68.631 f107a= 70.791 power from bzimf,swvel= 63.205 4: Step 930 of 1920 mtime= 59 23 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 930 GPI f107= 68.629 f107a= 70.791 power from bzimf,swvel= 59.849 4: Step 940 of 1920 mtime= 59 23 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 940 GPI f107= 68.628 f107a= 70.790 power from bzimf,swvel= 62.367 4: Step 950 of 1920 mtime= 59 23 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 950 GPI f107= 68.626 f107a= 70.790 power from bzimf,swvel= 61.962 4: Advancing day (previous,present)= 59 2008 60 2008 sfeps= 0.1018E+01 4: Step 960 of 1920 mtime= 60 0 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 960 GPI f107= 68.625 f107a= 70.790 power from bzimf,swvel= 53.425 4: Step 970 of 1920 mtime= 60 0 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 970 GPI f107= 68.624 f107a= 70.790 power from bzimf,swvel= 73.763 4: Step 980 of 1920 mtime= 60 0 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 980 GPI f107= 68.622 f107a= 70.790 power from bzimf,swvel= 74.754 4: Step 990 of 1920 mtime= 60 0 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 990 GPI f107= 68.620 f107a= 70.790 power from bzimf,swvel= 71.128 4: Step 1000 of 1920 mtime= 60 1 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1000 GPI f107= 68.619 f107a= 70.790 power from bzimf,swvel= 58.900 4: Step 1010 of 1920 mtime= 60 1 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1010 GPI f107= 68.617 f107a= 70.790 power from bzimf,swvel= 52.818 4: Step 1020 of 1920 mtime= 60 1 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1020 GPI f107= 68.616 f107a= 70.790 power from bzimf,swvel= 67.278 4: Step 1030 of 1920 mtime= 60 1 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1030 GPI f107= 68.614 f107a= 70.790 power from bzimf,swvel= 39.533 4: Step 1040 of 1920 mtime= 60 2 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1040 GPI f107= 68.612 f107a= 70.790 power from bzimf,swvel= 39.371 4: Step 1050 of 1920 mtime= 60 2 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1050 GPI f107= 68.611 f107a= 70.790 power from bzimf,swvel= 61.607 4: Step 1060 of 1920 mtime= 60 2 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1060 GPI f107= 68.609 f107a= 70.790 power from bzimf,swvel= 75.643 4: Step 1070 of 1920 mtime= 60 2 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1070 GPI f107= 68.607 f107a= 70.790 power from bzimf,swvel= 50.438 4: Step 1080 of 1920 mtime= 60 3 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1080 GPI f107= 68.605 f107a= 70.790 power from bzimf,swvel= 37.732 4: Step 1090 of 1920 mtime= 60 3 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1090 GPI f107= 68.603 f107a= 70.789 power from bzimf,swvel= 37.336 4: Step 1100 of 1920 mtime= 60 3 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1100 GPI f107= 68.601 f107a= 70.789 power from bzimf,swvel= 37.920 4: Step 1110 of 1920 mtime= 60 3 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1110 GPI f107= 68.600 f107a= 70.789 power from bzimf,swvel= 42.394 4: Step 1120 of 1920 mtime= 60 4 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1120 GPI f107= 68.598 f107a= 70.789 power from bzimf,swvel= 53.026 4: Step 1130 of 1920 mtime= 60 4 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1130 GPI f107= 68.595 f107a= 70.789 power from bzimf,swvel= 61.766 4: Step 1140 of 1920 mtime= 60 4 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1140 GPI f107= 68.593 f107a= 70.789 power from bzimf,swvel= 65.719 4: Step 1150 of 1920 mtime= 60 4 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1150 GPI f107= 68.591 f107a= 70.789 power from bzimf,swvel= 58.127 4: Step 1160 of 1920 mtime= 60 5 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1160 GPI f107= 68.589 f107a= 70.789 power from bzimf,swvel= 61.714 4: Step 1170 of 1920 mtime= 60 5 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1170 GPI f107= 68.587 f107a= 70.789 power from bzimf,swvel= 80.960 4: Step 1180 of 1920 mtime= 60 5 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1180 GPI f107= 68.584 f107a= 70.789 power from bzimf,swvel= 79.479 4: Step 1190 of 1920 mtime= 60 5 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1190 GPI f107= 68.582 f107a= 70.789 power from bzimf,swvel= 44.784 4: Step 1200 of 1920 mtime= 60 6 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1200 GPI f107= 68.580 f107a= 70.789 power from bzimf,swvel= 45.571 4: Step 1210 of 1920 mtime= 60 6 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1210 GPI f107= 68.577 f107a= 70.789 power from bzimf,swvel= 79.088 4: Step 1220 of 1920 mtime= 60 6 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1220 GPI f107= 68.575 f107a= 70.789 power from bzimf,swvel= 66.108 4: Step 1230 of 1920 mtime= 60 6 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1230 GPI f107= 68.572 f107a= 70.788 power from bzimf,swvel= 71.504 4: Step 1240 of 1920 mtime= 60 7 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1240 GPI f107= 68.569 f107a= 70.788 power from bzimf,swvel= 44.390 4: Step 1250 of 1920 mtime= 60 7 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1250 GPI f107= 68.567 f107a= 70.788 power from bzimf,swvel= 57.512 4: Step 1260 of 1920 mtime= 60 7 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1260 GPI f107= 68.564 f107a= 70.788 power from bzimf,swvel= 59.273 4: Step 1270 of 1920 mtime= 60 7 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1270 GPI f107= 68.561 f107a= 70.788 power from bzimf,swvel= 61.582 4: Step 1280 of 1920 mtime= 60 8 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1280 GPI f107= 68.558 f107a= 70.788 power from bzimf,swvel= 85.206 4: Step 1290 of 1920 mtime= 60 8 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1290 GPI f107= 68.555 f107a= 70.788 power from bzimf,swvel= 74.613 4: Step 1300 of 1920 mtime= 60 8 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1300 GPI f107= 68.552 f107a= 70.788 power from bzimf,swvel= 47.633 4: Step 1310 of 1920 mtime= 60 8 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1310 GPI f107= 68.549 f107a= 70.788 power from bzimf,swvel= 44.480 4: Step 1320 of 1920 mtime= 60 9 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1320 GPI f107= 68.546 f107a= 70.788 power from bzimf,swvel= 44.503 4: Step 1330 of 1920 mtime= 60 9 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1330 GPI f107= 68.542 f107a= 70.788 power from bzimf,swvel= 46.088 4: Step 1340 of 1920 mtime= 60 9 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1340 GPI f107= 68.539 f107a= 70.788 power from bzimf,swvel= 47.193 4: Step 1350 of 1920 mtime= 60 9 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1350 GPI f107= 68.535 f107a= 70.788 power from bzimf,swvel= 48.652 4: Step 1360 of 1920 mtime= 60 10 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1360 GPI f107= 68.532 f107a= 70.788 power from bzimf,swvel= 47.973 4: Step 1370 of 1920 mtime= 60 10 15 0 secs/step (sys) = 0.25 4: GPI+IMF run: istep= 1370 GPI f107= 68.528 f107a= 70.788 power from bzimf,swvel= 52.025 4: Step 1380 of 1920 mtime= 60 10 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1380 GPI f107= 68.524 f107a= 70.787 power from bzimf,swvel= 81.523 4: Step 1390 of 1920 mtime= 60 10 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1390 GPI f107= 68.521 f107a= 70.787 power from bzimf,swvel= 76.363 4: Step 1400 of 1920 mtime= 60 11 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1400 GPI f107= 68.517 f107a= 70.787 power from bzimf,swvel= 90.551 4: Step 1410 of 1920 mtime= 60 11 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1410 GPI f107= 68.513 f107a= 70.787 power from bzimf,swvel= 62.048 4: Step 1420 of 1920 mtime= 60 11 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1420 GPI f107= 68.508 f107a= 70.787 power from bzimf,swvel= 53.090 4: Step 1430 of 1920 mtime= 60 11 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1430 GPI f107= 68.504 f107a= 70.787 power from bzimf,swvel= 47.372 4: Step 1440 of 1920 mtime= 60 12 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1440 GPI f107= 68.500 f107a= 70.787 power from bzimf,swvel= 57.200 4: Step 1450 of 1920 mtime= 60 12 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1450 GPI f107= 68.489 f107a= 70.787 power from bzimf,swvel= 53.260 4: Step 1460 of 1920 mtime= 60 12 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1460 GPI f107= 68.477 f107a= 70.787 power from bzimf,swvel= 66.156 4: Step 1470 of 1920 mtime= 60 12 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1470 GPI f107= 68.466 f107a= 70.787 power from bzimf,swvel= 69.107 4: Step 1480 of 1920 mtime= 60 13 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1480 GPI f107= 68.454 f107a= 70.787 power from bzimf,swvel= 60.051 4: Step 1490 of 1920 mtime= 60 13 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1490 GPI f107= 68.442 f107a= 70.787 power from bzimf,swvel= 46.506 4: Step 1500 of 1920 mtime= 60 13 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1500 GPI f107= 68.431 f107a= 70.787 power from bzimf,swvel= 55.118 4: Step 1510 of 1920 mtime= 60 13 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1510 GPI f107= 68.419 f107a= 70.787 power from bzimf,swvel= 56.889 4: Step 1520 of 1920 mtime= 60 14 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1520 GPI f107= 68.407 f107a= 70.787 power from bzimf,swvel= 49.198 4: Step 1530 of 1920 mtime= 60 14 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1530 GPI f107= 68.395 f107a= 70.787 power from bzimf,swvel= 49.687 4: Step 1540 of 1920 mtime= 60 14 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1540 GPI f107= 68.383 f107a= 70.787 power from bzimf,swvel= 47.520 4: Step 1550 of 1920 mtime= 60 14 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1550 GPI f107= 68.371 f107a= 70.787 power from bzimf,swvel= 71.557 4: Step 1560 of 1920 mtime= 60 15 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1560 GPI f107= 68.358 f107a= 70.787 power from bzimf,swvel= 80.698 4: Step 1570 of 1920 mtime= 60 15 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1570 GPI f107= 68.346 f107a= 70.788 power from bzimf,swvel= 96.909 4: Step 1580 of 1920 mtime= 60 15 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1580 GPI f107= 68.334 f107a= 70.788 power from bzimf,swvel= 90.753 4: Step 1590 of 1920 mtime= 60 15 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1590 GPI f107= 68.321 f107a= 70.788 power from bzimf,swvel= 96.942 4: Step 1600 of 1920 mtime= 60 16 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1600 GPI f107= 68.309 f107a= 70.788 power from bzimf,swvel= 96.725 4: Step 1610 of 1920 mtime= 60 16 15 0 secs/step (sys) = 0.25 4: GPI+IMF run: istep= 1610 GPI f107= 68.296 f107a= 70.788 power from bzimf,swvel= 100.737 4: Step 1620 of 1920 mtime= 60 16 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1620 GPI f107= 68.284 f107a= 70.788 power from bzimf,swvel= 90.439 4: Step 1630 of 1920 mtime= 60 16 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1630 GPI f107= 68.271 f107a= 70.788 power from bzimf,swvel= 82.862 4: Step 1640 of 1920 mtime= 60 17 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1640 GPI f107= 68.259 f107a= 70.788 power from bzimf,swvel= 73.494 4: Step 1650 of 1920 mtime= 60 17 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1650 GPI f107= 68.246 f107a= 70.788 power from bzimf,swvel= 72.287 4: Step 1660 of 1920 mtime= 60 17 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1660 GPI f107= 68.233 f107a= 70.788 power from bzimf,swvel= 75.161 4: Step 1670 of 1920 mtime= 60 17 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1670 GPI f107= 68.221 f107a= 70.788 power from bzimf,swvel= 90.957 4: Step 1680 of 1920 mtime= 60 18 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1680 GPI f107= 68.208 f107a= 70.788 power from bzimf,swvel= 64.765 4: Step 1690 of 1920 mtime= 60 18 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1690 GPI f107= 68.195 f107a= 70.788 power from bzimf,swvel= 52.196 4: Step 1700 of 1920 mtime= 60 18 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1700 GPI f107= 68.182 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1710 of 1920 mtime= 60 18 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1710 GPI f107= 68.169 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1720 of 1920 mtime= 60 19 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1720 GPI f107= 68.156 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1730 of 1920 mtime= 60 19 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1730 GPI f107= 68.144 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1740 of 1920 mtime= 60 19 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1740 GPI f107= 68.131 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1750 of 1920 mtime= 60 19 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1750 GPI f107= 68.118 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1760 of 1920 mtime= 60 20 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1760 GPI f107= 68.105 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1770 of 1920 mtime= 60 20 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1770 GPI f107= 68.092 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1780 of 1920 mtime= 60 20 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1780 GPI f107= 68.079 f107a= 70.788 power from bzimf,swvel= 82.732 4: Step 1790 of 1920 mtime= 60 20 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1790 GPI f107= 68.066 f107a= 70.788 power from bzimf,swvel= 95.632 4: Step 1800 of 1920 mtime= 60 21 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1800 GPI f107= 68.053 f107a= 70.788 power from bzimf,swvel= 91.216 4: Step 1810 of 1920 mtime= 60 21 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1810 GPI f107= 68.040 f107a= 70.788 power from bzimf,swvel= 50.000 4: Step 1820 of 1920 mtime= 60 21 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1820 GPI f107= 68.028 f107a= 70.789 power from bzimf,swvel= 50.000 4: Step 1830 of 1920 mtime= 60 21 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1830 GPI f107= 68.015 f107a= 70.789 power from bzimf,swvel= 50.000 4: Step 1840 of 1920 mtime= 60 22 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1840 GPI f107= 68.002 f107a= 70.789 power from bzimf,swvel= 50.000 4: Step 1850 of 1920 mtime= 60 22 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1850 GPI f107= 67.989 f107a= 70.789 power from bzimf,swvel= 64.259 4: Step 1860 of 1920 mtime= 60 22 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1860 GPI f107= 67.976 f107a= 70.789 power from bzimf,swvel= 85.053 4: Step 1870 of 1920 mtime= 60 22 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1870 GPI f107= 67.963 f107a= 70.789 power from bzimf,swvel= 62.345 4: Step 1880 of 1920 mtime= 60 23 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1880 GPI f107= 67.951 f107a= 70.789 power from bzimf,swvel= 50.000 4: Step 1890 of 1920 mtime= 60 23 15 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1890 GPI f107= 67.938 f107a= 70.789 power from bzimf,swvel= 50.000 4: Step 1900 of 1920 mtime= 60 23 30 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1900 GPI f107= 67.925 f107a= 70.789 power from bzimf,swvel= 83.563 4: Step 1910 of 1920 mtime= 60 23 45 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1910 GPI f107= 67.913 f107a= 70.789 power from bzimf,swvel= 95.795 4: Advancing day (previous,present)= 60 2008 61 2008 sfeps= 0.1018E+01 4: Step 1920 of 1920 mtime= 61 0 0 0 secs/step (sys) = 0.24 4: GPI+IMF run: istep= 1920 GPI f107= 67.900 f107a= 70.789 power from bzimf,swvel= 93.683 4: 4: MPI run with ntask = 8 4: nstep= 1920 step= 90 4: Model simulation time = 172800 secs 4: (minutes= 2880.00, hours= 48.00, days= 2.000000) 4: Cpu time for run = 598.60 4: 4: ------------------------------------------------------------------------ 4: TIMER (system_clock): 4: Elapsed run time = 600.38 (secs) 10.01 (mins) 0.17 (hrs) 4: 4: Elapsed init time = 1.55 secs, 0.000 hrs, 0.3% (includes source i/o) 4: Elapsed step time = 471.02 secs, 0.131 hrs, 78.5% 4: Elapsed prep time = 561.07 secs, 0.156 hrs, 93.5% 4: Elapsed dynamics = 215.55 secs, 0.060 hrs, 35.9% 4: Elapsed qrj = 28.78 secs, 0.008 hrs, 4.8% 4: Elapsed oplus = 25.31 secs, 0.007 hrs, 4.2% 4: Elapsed cmpminor = 28.93 secs, 0.008 hrs, 4.8% (n4s,n2d,no) 4: Elapsed cmpmajor = 15.87 secs, 0.004 hrs, 2.6% (o2, o) 4: Elapsed dt = 8.18 secs, 0.002 hrs, 1.4% 4: Elapsed duv = 17.50 secs, 0.005 hrs, 2.9% 4: Elapsed dynamo = 17.19 secs, 0.005 hrs, 2.9% 4: Elapsed i/o = 8.53 secs, 0.002 hrs, 1.4% 4: Elapsed Primary io = 1.81 secs, 0.001 hrs, 0.3% 4: Elapsed Secondary = 6.71 secs, 0.002 hrs, 1.1% 4: 4: Average secs/step = 0.25 4: Average mins/simulated day = 5.00 4: ------------------------------------------------------------------------ 4: 4: End execution of tiegcm1.95 at 01/12/14 12:59:55 4: NORMAL EXIT