subroutine mtlm_tavg_def (fname, imt, jmt, NPFT, NTYPE, xt, yt &, calendar, expnam, runstamp) #if defined O_mtlm !======================================================================= ! definition routine for land time averages ! inputs: ! fname = file name ! imt, jmt ... = global array dimensions ! xt, yt ... = global axes ! calendar = calendar ! expnam = experiment name ! runstamp = run stamp !======================================================================= implicit none character(*) :: fname, calendar, expnam, runstamp integer iou, j, imt, jmt, igs, ige, ig, jgs, jge, jg integer id_time, id_xt, id_yt, id_pft, id_type integer id_xt_e, id_yt_e, id_pft_e, id_type_e integer it(10) integer NPFT, NTYPE real xt(imt), yt(jmt) real c0, c1, c1e6, c1e20 c0 = 0. c1 = 1. c1e6 = 1.e6 c1e20 = 1.e20 !----------------------------------------------------------------------- ! open file !----------------------------------------------------------------------- call openfile (fname, iou) !----------------------------------------------------------------------- ! set global write domain size (may be less than global domain) !----------------------------------------------------------------------- igs = 1 ige = imt if (xt(1) + 360. lt. xt(imt)) then ! assume cyclic boundary igs = 2 ige = imt-1 endif ig = ige-igs+1 jgs = 1 jge = jmt do j=2,jmt if (yt(j-1) .lt. -90. .and. yt(j) .gt. -90.) jgs = j if (yt(j-1) .lt. 90. .and. yt(j) .gt. 90.) jge = j-1 enddo jg = jge-jgs+1 !----------------------------------------------------------------------- ! start definitions !----------------------------------------------------------------------- call redef (iou) !----------------------------------------------------------------------- ! write global attributes !----------------------------------------------------------------------- call putatttext (iou, 'global', 'Conventions', 'CF-1.0') call putatttext (iou, 'global', 'experiment_name', expnam) call putatttext (iou, 'global', 'run_stamp', runstamp) !----------------------------------------------------------------------- ! define dimensions !----------------------------------------------------------------------- call defdim ('time', iou, 0, id_time) call defdim ('longitude', iou, ig, id_xt) call defdim ('latitude', iou, jg, id_yt) call defdim ('pft', iou, NPFT, id_pft) call defdim ('type', iou, NTYPE, id_type) call defdim ('longitude_edges', iou, ig+1, id_xt_e) call defdim ('latitude_edges', iou, jg+1, id_yt_e) call defdim ('pft_edges', iou, NPFT+1, id_pft_e) call defdim ('type_edges', iou, NTYPE+1, id_type_e) !----------------------------------------------------------------------- ! define 1d data (t) !----------------------------------------------------------------------- it(1) = id_time call defvar ('time', iou, 1, it, c0, c0, 'T', 'D' # if defined O_units_time_years # if !defined O_save_time_relyear0 &, 'time', 'time', 'years since 1-1-1') # else &, 'time', 'time', 'years since 0-1-1') # endif # else # if !defined O_save_time_relyear0 &, 'time', 'time', 'days since 1-1-1') # else &, 'time', 'time', 'days since 0-1-1') # endif # endif call putatttext (iou, 'time', 'calendar', calendar) call defvar ('T_avgper', iou, 1, it, c0, c0, ' ', 'F' &, 'averaging period', ' ','day') !----------------------------------------------------------------------- ! define 1d data (x, y or n) !----------------------------------------------------------------------- it(1) = id_xt call defvar ('longitude', iou, 1, it, c0, c0, 'X', 'D' &, 'longitude', 'longitude', 'degrees_east') call defvar ('G_dxt', iou, 1, it, c0, c0, ' ', 'D' &, 'width t grid', ' ', 'm') it(1) = id_yt call defvar ('latitude', iou, 1, it, c0, c0, 'Y', 'D' &, 'latitude', 'latitude', 'degrees_north') call defvar ('G_dyt', iou, 1, it, c0, c0, ' ', 'D' &, 'height t grid', ' ', 'm') it(1) = id_pft call defvar ('pft', iou, 1, it, c0, c0, 'Z', 'F' &, 'plant functional type', ' ', ' ') it(1) = id_type call defvar ('type', iou, 1, it, c0, c0, 'Z', 'F' &, 'land type', ' ', ' ') it(1) = id_xt_e call defvar ('longitude_edges', iou, 1, it, c0, c0, 'X', 'D' &, 'longitude edges', 'longitude', 'degrees_east') it(1) = id_yt_e call defvar ('latitude_edges', iou, 1, it, c0, c0, 'Y', 'D' &, 'latitude edges', 'longitude', 'degrees_east') it(1) = id_pft_e call defvar ('pft_edges', iou, 1, it, c0, c0, 'Z', 'F' &, 'plant functional type', ' ', ' ') it(1) = id_type_e call defvar ('type_edges', iou, 1, it, c0, c0, 'Z' &, 'F', 'land type', ' ', ' ') !----------------------------------------------------------------------- ! define 2d data (x,y) !----------------------------------------------------------------------- it(1) = id_xt it(2) = id_yt call defvar ('G_latT', iou, 2, it, -c1e6, c1e6, ' ', 'F' &, 'tracer grid latitude', 'latitude', 'degrees_north') call defvar ('G_lonT', iou, 2, it, -c1e6, c1e6, ' ', 'F' &, 'tracer grid longitude', 'longitude', 'degrees_east') call defvar ('G_areaT', iou, 2, it, -c1e6, c1e6, ' ', 'F' &, 'tracer grid area', ' ', 'm2') !----------------------------------------------------------------------- ! define 3d data (x,y,t) !----------------------------------------------------------------------- it(1) = id_xt it(2) = id_yt it(3) = id_time call defvar ('L_soiltemp', iou , 3, it, -c1e20, c1e20, ' ', 'F' # if defined O_units_temperature_Celsius &, 'soil temperature', 'soil_temperature', 'C') # else &, 'soil temperature', 'soil_temperature', 'K') # endif call defvar ('L_soilcarb', iou , 3, it, -c1e20, c1e20, ' ', 'F' &, 'soil carbon', 'soil_carbon_content', 'kg m-2 ') call defvar ('L_soilresp', iou , 3, it, -c1e20, c1e20, ' ', 'F' &, 'soil respiration', 'soil_respiration_carbon_flux' &, 'kg m-2 s-1') call defvar ('L_veglit', iou , 3, it, -c1e20, c1e20, ' ', 'F' &, 'total leaf litter', 'leaf_litter_carbon_flux' &, 'kg m-2 s-1') call defvar ('L_vegburn', iou , 3, it, -c1e20, c1e20, ' ', 'F' &, 'total vegetation burning', 'burning_carbon_flux' &, 'kg m-2 s-1') # if !defined O_embm call defvar ('L_skintemp', iou , 3, it, -c1e20, c1e20, ' ', 'F' # if defined O_units_temperature_Celsius &, 'surface temperature', 'surface_temperature', 'C') # else &, 'surface temperature', 'surface_temperature', 'K') # endif call defvar ('A_albsurL', iou , 3, it, -c1e20, c1e20, ' ', 'F' &, 'surface albedo', 'surface_albedo', '1') call defvar ('F_evapLtrans', iou , 3, it, -c1e20, c1e20, ' ', 'F' &, 'evapotranspiration', 'evapotranspiration', 'kg m-2 s-1') call defvar ('L_soilmois', iou , 3, it, -c1e20, c1e20, ' ', 'F' &, 'soil moisture', 'soil_moisture_content', 'kg m-2') # endif !----------------------------------------------------------------------- ! define 4d data (x,y,pft,t) !----------------------------------------------------------------------- it(1) = id_xt it(2) = id_yt it(3) = id_pft it(4) = id_time call defvar ('L_veggpp', iou , 4, it, -c1e20, c1e20, ' ', 'F' &, 'gross primary productivity' &, 'gross_primary_productivity_of_carbon', 'kg m-2 s-1') call defvar ('L_vegnpp', iou , 4, it, -c1e20, c1e20, ' ', 'F' &, 'net primary productivity' &, 'net_primary_productivity_of_carbon', 'kg m-2 s-1') call defvar ('L_veghgt', iou , 4, it, -c1e20, c1e20, ' ', 'F' &, 'canopy height', 'canopy_height', 'L_soilmois') call defvar ('L_veglai', iou , 4, it, -c1e20, c1e20, ' ', 'F' &, 'leaf area index ', 'leaf_area_index', '1') call defvar ('L_vegcarb', iou , 4, it, -c1e20, c1e20, ' ', 'F' &, 'vegetation carbon', 'vegetation_carbon_content', 'kg m-2 ') !----------------------------------------------------------------------- ! define 4d data (x,y,type,t) !----------------------------------------------------------------------- it(1) = id_xt it(2) = id_yt it(3) = id_type it(4) = id_time call defvar ('L_vegfra', iou , 4, it, -c1e20, c1e20, ' ', 'F' &, 'areal coverage', 'vegetation_area_fraction', '1') !----------------------------------------------------------------------- ! end definitions !----------------------------------------------------------------------- call enddef (iou) return end subroutine mtlm_tavg_out (fname, ids, ide, jds, jde, imt, jmt &, POINTS, NPFT, NTYPE, xt, yt, xu, yu &, dxt, dyt, dxu, dyu, avgper, time &, stamp, land_map, TS1, CS, RESP_S &, LIT_C_T, BURN, FRAC, GPP, NPP, HT, LAI &, C_VEG #if !defined O_embm &, TSTAR_GB, ALBLAND, ET, M #endif &, tlat, tlon, tgarea, ntrec) !======================================================================= ! output routine for land time averages ! data may be sized differently in x and y from the global fields. ! fields may be written with or without a time dimension. data ! should be defined with the routine defvar and written with putvar. ! if no time dimension, then data is only written once per file. ! make sure the it, iu, ib, and ic arrays and are defining the ! correct dimensions. ln may also need to be recalculated. ! inputs: ! fname = file name ! ids, ide ... = start and end index for data domain ! imt, jmt ... = global array dimensions ! xt, yt ... = global axes ! dxt, dyt ... = grid widths ! avgper = length of averaging period ! time = time in years ! stamp = time stamp ! land_map = land map ! TS1, ... = data to be written ! outputs: ! ntrec = number of time record in file !======================================================================= implicit none character(*) :: fname, stamp integer iou, j, ln, n, ntrec, imt, jmt, ids, ide, jds, jde, igs integer ige, ig, jgs, jge, jg, ils, ile, jls, jle, ib(10), ic(10) integer nyear, nmonth, nday, nhour, nmin, nsec integer POINTS, NPFT, NTYPE, land_map(imt,jmt) real xt(imt), xu(imt), yt(jmt), yu(jmt) real dxt(imt), dxu(imt), dyt(jmt), dyu(jmt) real tmpmask(imt,jmt), data(imt,jmt), pft(NPFT), type(NTYPE) real xt_e(imt+1), yt_e(jmt+1), pft_e(NPFT+1), type_e(NTYPE+1) real avgper, time, tmp, c0, c1, c100, c1e4, C2K # if !defined O_embm real TSTAR_GB(POINTS), ALBLAND(POINTS), ET(POINTS), M(POINTS) # endif real TS1(POINTS), CS(POINTS), RESP_S(POINTS), LIT_C_T(POINTS) real BURN(POINTS), FRAC(POINTS,NTYPE), GPP(POINTS,NPFT) real NPP(POINTS,NPFT), HT(POINTS,NPFT), LAI(POINTS,NPFT) real C_VEG(POINTS,NPFT) real tlat(ids:ide,jds:jde), tlon(ids:ide,jds:jde) real tgarea(ids:ide,jds:jde) real, allocatable :: tmpij(:,:), tmpijm(:,:) real, allocatable :: tmpi(:), tmpj(:) real, allocatable :: tmpie(:), tmpje(:) c0 = 0. c1 = 1. c100 = 100. c1e4 = 1.e4 C2K = 273.15 !----------------------------------------------------------------------- ! open file and get latest record number !----------------------------------------------------------------------- call opennext (fname, time, ntrec, iou) if (ntrec .le. 0) ntrec = 1 !----------------------------------------------------------------------- ! set global write domain size (may be less than global domain) !----------------------------------------------------------------------- igs = 1 ige = imt if (xt(1) + 360. lt. xt(imt)) then ! assume cyclic boundary igs = 2 ige = imt-1 endif ig = ige-igs+1 jgs = 1 jge = jmt do j=2,jmt if (yt(j-1) .lt. -90. .and. yt(j) .gt. -90.) jgs = j if (yt(j-1) .lt. 90. .and. yt(j) .gt. 90.) jge = j-1 enddo jg = jge-jgs+1 !----------------------------------------------------------------------- ! local domain size (minimum of data domain and global write domain) !----------------------------------------------------------------------- ils = max(ids,igs) ile = min(ide,ige) jls = max(jds,jgs) jle = min(jde,jge) allocate ( tmpij(ils:ile,jls:jle) ) allocate ( tmpijm(ils:ile,jls:jle) ) !----------------------------------------------------------------------- ! write 1d data (t) !----------------------------------------------------------------------- call putvars ('time', iou, ntrec, time, c1, c0) call rdstmp (stamp, nyear, nmonth, nday, nhour, nmin, nsec) call putvars ('T_avgper', iou, ntrec, avgper, c1, c0) if (ntrec .eq. 1) then !----------------------------------------------------------------------- ! write 1d data (x, y or z) !----------------------------------------------------------------------- allocate ( tmpi(igs:ige) ) allocate ( tmpj(jgs:jge) ) allocate ( tmpie(igs:ige+1) ) allocate ( tmpje(jgs:jge+1) ) ib(1) = 1 ic(1) = ig tmpi(igs:ige) = xt(igs:ige) call putvara ('longitude', iou, ig, ib, ic, tmpi, c1, c0) tmpi(igs:ige) = dxt(igs:ige) call putvara ('G_dxt', iou, ig, ib, ic, tmpi, c100, c0) ic(1) = jg tmpj(jgs:jge) = yt(jgs:jge) call putvara ('latitude', iou, jg, ib, ic, tmpj, c1, c0) tmpj(jgs:jge) = dyt(jgs:jge) call putvara ('G_dyt', iou, jg, ib, ic, tmpj, c100, c0) ic(1) = ig + 1 call edge_maker (1, xt_e, xt, dxt, xu, dxu, imt) tmpie(igs:ige+1) = xt_e(igs:ige+1) call putvara ('longitude_edges', iou, ig+1, ib, ic, tmpie &, c1, c0) ic(1) = jg + 1 call edge_maker (1, yt_e, yt, dyt, yu, dyu, jmt) tmpje(jgs:jge+1) = yt_e(jgs:jge+1) call putvara ('latitude_edges', iou, jg+1, ib, ic, tmpje &, c1, c0) deallocate ( tmpi ) deallocate ( tmpj ) deallocate ( tmpie ) deallocate ( tmpje ) do n=1, NPFT pft(n) = n pft_e(n) = pft(n) - 0.5 enddo pft_e(NPFT+1) = pft(NPFT) + 0.5 ic(1) = NPFT call putvara ('pft', iou, NPFT, ib, ic, pft, c1, c0) ic(1) = NPFT + 1 call putvara ('pft_edges', iou, NPFT+1, ib, ic, pft_e, c1, c0) do n=1, NTYPE type(n) = float(n) type_e(n) = type(n) - 0.5 enddo type_e(NTYPE+1) = type(NTYPE) + 0.5 ic(1) = NTYPE call putvara ('type', iou, NTYPE, ib, ic, type, c1, c0) ic(1) = NTYPE + 1 call putvara ('type_edges', iou, NTYPE+1, ib, ic, type_e &, c1, c0) !----------------------------------------------------------------------- ! write 2d data (x,y) !----------------------------------------------------------------------- ib(1) = ils-igs+1 ic(1) = ile-ils+1 ib(2) = jls-jgs+1 ic(2) = jle-jls+1 ln = ic(1)*ic(2) tmpij(ils:ile,jls:jle) = tlat(ils:ile,jls:jle) call putvara ('G_latT', iou, ln, ib, ic, tmpij, c1, c0) tmpij(ils:ile,jls:jle) = tlon(ils:ile,jls:jle) call putvara ('G_lonT', iou, ln, ib, ic, tmpij, c1, c0) tmpij(ils:ile,jls:jle) = tgarea(ils:ile,jls:jle) call putvara ('G_areaT', iou, ln, ib, ic, tmpij, c1e4, c0) endif !----------------------------------------------------------------------- ! write 3d data (x,y,t) !----------------------------------------------------------------------- ib(1) = ils-igs+1 ic(1) = ile-ils+1 ib(2) = jls-jgs+1 ic(2) = jle-jls+1 ib(3) = ntrec ic(3) = 1 ln = ic(1)*ic(2)*ic(3) tmpmask(:,:) = 0. where (land_map(:,:) .gt. 0) tmpmask(:,:) = 1. tmpijm(ils:ile,jls:jle) = tmpmask(ils:ile,jls:jle) call unloadland (POINTS, TS1, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_soiltemp', iou, ln, ib, ic, tmpij, tmpijm # if defined O_units_temperature_Celsius &, c1, C2K) # else &, c1, c0) # endif call unloadland (POINTS, CS, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_soilcarb', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, RESP_S, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_soilresp', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, LIT_C_T, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_veglit', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, BURN, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_vegburn', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) # if !defined O_embm call unloadland (POINTS, TSTAR_GB, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_skintemp', iou, ln, ib, ic, tmpij, tmpijm # if defined O_units_temperature_Celsius &, c1, C2K) # else &, c1, c0) # endif call unloadland (POINTS, ALBLAND, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('A_albsurL', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, ET, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('F_evapLtrans', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, M, imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_soilmois', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) # endif !----------------------------------------------------------------------- ! write 4d data (x,y,pft,t) !----------------------------------------------------------------------- ib(1) = ils-igs+1 ic(1) = ile-ils+1 ib(2) = jls-jgs+1 ic(2) = jle-jls+1 ic(3) = 1 ib(4) = ntrec ic(4) = 1 ln = ic(1)*ic(2)*ic(3)*ic(4) do n=1,npft ib(3) = n call unloadland (POINTS, GPP(1,n), imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_veggpp', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, NPP(1,n), imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_vegnpp', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, HT(1,n), imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_veghgt', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, LAI(1,n), imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_veglai', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) call unloadland (POINTS, C_VEG(1,n), imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) call putvaramsk ('L_vegcarb', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) enddo !----------------------------------------------------------------------- ! write 4d data (x,y,type,t) !----------------------------------------------------------------------- ib(1) = ils-igs+1 ic(1) = ile-ils+1 ib(2) = jls-jgs+1 ic(2) = jle-jls+1 ic(3) = 1 ib(4) = ntrec ic(4) = 1 do n=1,ntype ib(3) = n call unloadland (POINTS, FRAC(1,n), imt, jmt, land_map, data) tmpij(ils:ile,jls:jle) = data(ils:ile,jls:jle) where (tmpij(ils:ile,jls:jle) .lt. 0.) & tmpij(ils:ile,jls:jle) = c0 call putvaramsk ('L_vegfra', iou, ln, ib, ic, tmpij, tmpijm &, c1, c0) enddo deallocate ( tmpij ) deallocate ( tmpijm ) #endif return end