!wrf:model_layer:physics ! ! ! MODULE module_fdda_psufddagd CONTAINS ! !------------------------------------------------------------------- ! SUBROUTINE fddagd(itimestep,dx,dt,xtime, & id,analysis_interval, end_fdda_hour, & if_no_pbl_nudging_uv, if_no_pbl_nudging_t, if_no_pbl_nudging_q, & if_zfac_uv, k_zfac_uv, if_zfac_t, k_zfac_t, if_zfac_q, k_zfac_q, & guv, gt, gq, if_ramping, dtramp_min, & grid_sfdda, & analysis_interval_sfc, end_fdda_hour_sfc, guv_sfc, gt_sfc, gq_sfc, & rinblw, & u3d,v3d,th3d,t3d, & qv3d, & p3d,pi3d, & u_ndg_old,v_ndg_old,t_ndg_old,q_ndg_old,mu_ndg_old, & u_ndg_new,v_ndg_new,t_ndg_new,q_ndg_new,mu_ndg_new, & u10_ndg_old, v10_ndg_old, t2_ndg_old, th2_ndg_old, q2_ndg_old, & rh_ndg_old, psl_ndg_old, ps_ndg_old, tob_ndg_old, odis_ndg_old, & u10_ndg_new, v10_ndg_new, t2_ndg_new, th2_ndg_new, q2_ndg_new, & rh_ndg_new, psl_ndg_new, ps_ndg_new, tob_ndg_new, odis_ndg_new, & RUNDGDTEN,RVNDGDTEN,RTHNDGDTEN,RQVNDGDTEN,RMUNDGDTEN,& pblh, ht, regime, znt, z, z_at_w, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte ) !------------------------------------------------------------------- implicit none !------------------------------------------------------------------- ! ! This code was implemented by Aijun Deng (Penn State). The 3-D analysis nudging was comleted ! and released in December 2006. The surface analysis nudging capability was added and ! released in March 2009 with WRFV3.1. ! !-- u3d 3d u-velocity staggered on u points !-- v3d 3d v-velocity staggered on v points !-- th3d 3d potential temperature (k) !-- t3d temperature (k) !-- qv3d 3d water vapor mixing ratio (kg/kg) !-- p3d 3d pressure (pa) !-- pi3d 3d exner function (dimensionless) !-- rundgdten staggered u tendency due to ! fdda grid nudging (m/s/s) !-- rvndgdten staggered v tendency due to ! fdda grid nudging (m/s/s) !-- rthndgdten theta tendency due to ! fdda grid nudging (K/s) !-- rqvndgdten qv tendency due to ! fdda grid nudging (kg/kg/s) !-- rmundgdten mu tendency due to ! fdda grid nudging (Pa/s) !-- ids start index for i in domain !-- ide end index for i in domain !-- jds start index for j in domain !-- jde end index for j in domain !-- kds start index for k in domain !-- kde end index for k in domain !-- ims start index for i in memory !-- ime end index for i in memory !-- jms start index for j in memory !-- jme end index for j in memory !-- kms start index for k in memory !-- kme end index for k in memory !-- its start index for i in tile !-- ite end index for i in tile !-- jts start index for j in tile !-- jte end index for j in tile !-- kts start index for k in tile !-- kte end index for k in tile !------------------------------------------------------------------- ! INTEGER, INTENT(IN) :: itimestep, analysis_interval, end_fdda_hour INTEGER, INTENT(IN) :: analysis_interval_sfc, end_fdda_hour_sfc INTEGER, INTENT(IN) :: grid_sfdda INTEGER, INTENT(IN) :: if_no_pbl_nudging_uv, if_no_pbl_nudging_t, & if_no_pbl_nudging_q INTEGER, INTENT(IN) :: if_zfac_uv, if_zfac_t, if_zfac_q INTEGER, INTENT(IN) :: k_zfac_uv, k_zfac_t, k_zfac_q INTEGER, INTENT(IN) :: if_ramping INTEGER , INTENT(IN) :: id REAL, INTENT(IN) :: DT, dx, xtime, dtramp_min INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(IN) :: qv3d, & p3d, & pi3d, & th3d, & t3d, & z, & z_at_w REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(INOUT) :: rundgdten, & rvndgdten, & rthndgdten, & rqvndgdten REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(INOUT) :: rmundgdten REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(IN) :: u_ndg_old, & v_ndg_old, & t_ndg_old, & q_ndg_old, & u_ndg_new, & v_ndg_new, & t_ndg_new, & q_ndg_new REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN) :: u10_ndg_old, & v10_ndg_old, & t2_ndg_old, & th2_ndg_old, & q2_ndg_old, & rh_ndg_old, & psl_ndg_old, & ps_ndg_old, & u10_ndg_new, & v10_ndg_new, & t2_ndg_new, & th2_ndg_new, & q2_ndg_new, & rh_ndg_new, & psl_ndg_new, & ps_ndg_new REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN) :: tob_ndg_old, & tob_ndg_new REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(INOUT) :: mu_ndg_old, & mu_ndg_new REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN) :: odis_ndg_old, odis_ndg_new REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(IN) :: u3d, & v3d REAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: pblh, & ht, & regime, & znt REAL, INTENT(IN) :: guv, gt, gq REAL, INTENT(IN) :: guv_sfc, gt_sfc, gq_sfc, rinblw INTEGER :: i, j, k, itsu, jtsv, itf, jtf, ktf, i0, k0, j0 REAL :: xtime_old, xtime_new, coef, val_analysis INTEGER :: kpbl, dbg_level REAL :: zpbl, zagl, zagl_bot, zagl_top, tfac, actual_end_fdda_min REAL, DIMENSION( its:ite, kts:kte, jts:jte, 4 ) :: wpbl ! 1: u, 2: v, 3: t, 4: q REAL, DIMENSION( kts:kte, 4 ) :: wzfac ! 1: u, 2: v, 3: t, 4: q LOGICAL , EXTERNAL :: wrf_dm_on_monitor CHARACTER (LEN=256) :: message INTEGER :: int4 int4 = 1 ! 1: temporal interpolation. else: target nudging toward *_ndg_new values actual_end_fdda_min = end_fdda_hour*60.0 IF( if_ramping == 1 .AND. dtramp_min > 0.0 ) & actual_end_fdda_min = end_fdda_hour*60.0 + ABS(dtramp_min) IF( xtime > actual_end_fdda_min ) THEN ! If xtime is greater than the end time, no need to calculate tendencies. Just set the tnedencies ! to zero to turn off nudging and return. DO j = jts, jte DO k = kts, kte DO i = its, ite RUNDGDTEN(i,k,j) = 0.0 RVNDGDTEN(i,k,j) = 0.0 RTHNDGDTEN(i,k,j) = 0.0 RQVNDGDTEN(i,k,j) = 0.0 IF( k .EQ. kts ) RMUNDGDTEN(i,j) = 0. ENDDO ENDDO ENDDO RETURN ENDIF IF( analysis_interval <= 0 )CALL wrf_error_fatal('In grid FDDA, gfdda_interval_m must be > 0') xtime_old = FLOOR(xtime/analysis_interval) * analysis_interval * 1.0 xtime_new = xtime_old + analysis_interval IF( int4 == 1 ) THEN coef = (xtime-xtime_old)/(xtime_new-xtime_old) ELSE coef = 1.0 ! Nudging toward a target value (*_ndg_new values) ENDIF IF ( wrf_dm_on_monitor()) THEN CALL get_wrf_debug_level( dbg_level ) IF( xtime-xtime_old < 0.5*dt/60.0 ) THEN IF( xtime < end_fdda_hour*60.0 ) THEN WRITE(message,'(a,i1,a,f10.3,a)') & 'D0',id,' 3-D analysis nudging reads new data at time = ', xtime, ' min.' CALL wrf_message( TRIM(message) ) WRITE(message,'(a,i1,a,2f8.2,a)') & 'D0',id,' 3-D analysis nudging bracketing times = ', xtime_old, xtime_new, ' min.' CALL wrf_message( TRIM(message) ) ENDIF actual_end_fdda_min = end_fdda_hour*60.0 IF( if_ramping == 1 .AND. dtramp_min > 0.0 ) & actual_end_fdda_min = end_fdda_hour*60.0 + ABS(dtramp_min) IF( dbg_level .GE. 10 .AND. xtime <= actual_end_fdda_min ) THEN ! Find the mid point of the tile and print out the sample values i0 = (ite-its)/2+its j0 = (jte-jts)/2+jts IF( guv > 0.0 ) THEN DO k = kts, kte WRITE(message,'(a,i1,a,3i4,a,f10.4,a,f10.4)') & ' D0',id,' sample 3-D analysis values at i,k,j=', i0, k, j0, & ' u_ndg_old=', u_ndg_old(i0,k,j0), ' u_ndg_new=', u_ndg_new(i0,k,j0) CALL wrf_message( TRIM(message) ) ENDDO WRITE(message,'(a,i1,a,3i4,a,f10.4,a,f10.4)') & ' D0',id,' sample 3-D analysis values at i,k,j=', i0, k, j0, & ' mu_ndg_old=', mu_ndg_old(i0,j0), ' mu_ndg_new=', mu_ndg_new(i0,j0) CALL wrf_message( TRIM(message) ) DO k = kts, kte WRITE(message,'(a,i1,a,3i4,a,f10.4,a,f10.4)') & ' D0',id,' sample 3-D analysis values at i,k,j=', i0, k, j0, & ' v_ndg_old=', v_ndg_old(i0,k,j0), ' v_ndg_new=', v_ndg_new(i0,k,j0) CALL wrf_message( TRIM(message) ) ENDDO ENDIF IF( gt > 0.0 ) THEN DO k = kts, kte WRITE(message,'(a,i1,a,3i4,a,f10.4,a,f10.4)') & ' D0',id,' sample 3-D analysis values at i,k,j=', i0, k, j0, & ' t_ndg_old=', t_ndg_old(i0,k,j0), ' t_ndg_new=', t_ndg_new(i0,k,j0) CALL wrf_message( TRIM(message) ) ENDDO ENDIF IF( gq > 0.0 ) THEN DO k = kts, kte WRITE(message,'(a,i1,a,3i4,a,f10.4,a,f10.4)') & ' D0',id,' sample 3-D analysis values at i,k,j=', i0, k, j0, & ' q_ndg_old=', q_ndg_old(i0,k,j0), ' q_ndg_new=', q_ndg_new(i0,k,j0) CALL wrf_message( TRIM(message) ) ENDDO ENDIF IF( int4 == 1 ) then WRITE(message,'(a,i1,a)') ' D0',id, & ' 3-D nudging towards the temporally interpolated analysis' ELSE WRITE(message,'(a,i1,a)') ' D0',id, & ' 3-D nudging towards the target analysis' ENDIF ENDIF ENDIF ENDIF jtsv=MAX0(jts,jds+1) itsu=MAX0(its,ids+1) jtf=MIN0(jte,jde-1) ktf=MIN0(kte,kde-1) itf=MIN0(ite,ide-1) ! ! If the user-defined namelist switches (if_no_pbl_nudging_uv, if_no_pbl_nudging_t, ! if_no_pbl_nudging_q swithes) are set to 1, compute the weighting function, wpbl(:,k,:,:), ! based on the PBL depth. wpbl = 1 above the PBL and wpbl = 0 in the PBL. If all ! the switche are set to zero, wpbl = 1 (default value). ! wpbl(:,:,:,:) = 1.0 IF( if_no_pbl_nudging_uv == 1 .OR. grid_sfdda == 1 ) THEN DO j=jts,jtf DO i=itsu,itf kpbl = 1 zpbl = 0.5 * ( pblh(i-1,j) + pblh(i,j) ) loop_ku: DO k=kts,ktf ! zagl = 0.5 * ( z(i-1,k,j)-ht(i-1,j) + z(i,k,j)-ht(i,j) ) zagl_bot = 0.5 * ( z_at_w(i-1,k, j)-ht(i-1,j) + z_at_w(i,k, j)-ht(i,j) ) zagl_top = 0.5 * ( z_at_w(i-1,k+1,j)-ht(i-1,j) + z_at_w(i,k+1,j)-ht(i,j) ) IF( zpbl >= zagl_bot .AND. zpbl < zagl_top ) THEN kpbl = k EXIT loop_ku ENDIF ENDDO loop_ku DO k=kts,ktf IF( k <= kpbl ) wpbl(i, k, j, 1) = 0.0 IF( k == kpbl+1 ) wpbl(i, k, j, 1) = 0.1 IF( k > kpbl+1 ) wpbl(i, k, j, 1) = 1.0 ENDDO ENDDO ENDDO DO i=its,itf DO j=jtsv,jtf kpbl = 1 zpbl = 0.5 * ( pblh(i,j-1) + pblh(i,j) ) loop_kv: DO k=kts,ktf ! zagl = 0.5 * ( z(i,k,j-1)-ht(i,j-1) + z(i,k,j)-ht(i,j) ) zagl_bot = 0.5 * ( z_at_w(i,k, j-1)-ht(i,j-1) + z_at_w(i,k, j)-ht(i,j) ) zagl_top = 0.5 * ( z_at_w(i,k+1,j-1)-ht(i,j-1) + z_at_w(i,k+1,j)-ht(i,j) ) IF( zpbl >= zagl_bot .AND. zpbl < zagl_top ) THEN kpbl = k EXIT loop_kv ENDIF ENDDO loop_kv DO k=kts,ktf IF( k <= kpbl ) wpbl(i, k, j, 2) = 0.0 IF( k == kpbl+1 ) wpbl(i, k, j, 2) = 0.1 IF( k > kpbl+1 ) wpbl(i, k, j, 2) = 1.0 ENDDO ENDDO ENDDO ENDIF IF( if_no_pbl_nudging_t == 1 .OR. grid_sfdda == 1 ) THEN DO j=jts,jtf DO i=its,itf kpbl = 1 zpbl = pblh(i,j) loop_kt: DO k=kts,ktf ! zagl = z(i,k,j)-ht(i,j) zagl_bot = z_at_w(i,k, j)-ht(i,j) zagl_top = z_at_w(i,k+1,j)-ht(i,j) IF( zpbl >= zagl_bot .AND. zpbl < zagl_top ) THEN kpbl = k EXIT loop_kt ENDIF ENDDO loop_kt DO k=kts,ktf IF( k <= kpbl ) wpbl(i, k, j, 3) = 0.0 IF( k == kpbl+1 ) wpbl(i, k, j, 3) = 0.1 IF( k > kpbl+1 ) wpbl(i, k, j, 3) = 1.0 ENDDO ENDDO ENDDO ENDIF IF( if_no_pbl_nudging_q == 1 .OR. grid_sfdda == 1 ) THEN DO j=jts,jtf DO i=its,itf kpbl = 1 zpbl = pblh(i,j) loop_kq: DO k=kts,ktf ! zagl = z(i,k,j)-ht(i,j) zagl_bot = z_at_w(i,k, j)-ht(i,j) zagl_top = z_at_w(i,k+1,j)-ht(i,j) IF( zpbl >= zagl_bot .AND. zpbl < zagl_top ) THEN kpbl = k EXIT loop_kq ENDIF ENDDO loop_kq DO k=kts,ktf IF( k <= kpbl ) wpbl(i, k, j, 4) = 0.0 IF( k == kpbl+1 ) wpbl(i, k, j, 4) = 0.1 IF( k > kpbl+1 ) wpbl(i, k, j, 4) = 1.0 ENDDO ENDDO ENDDO ENDIF ! ! If the user-defined namelist switches (if_zfac_uv, if_zfac_t, ! if_zfac_q swithes) are set to 1, compute the weighting function, wzfac(k,:), ! based on the namelist specified k values (k_zfac_uv, k_zfac_t and k_zfac_q) below which analysis ! nudging is turned off (wzfac = 1 above k_zfac_x and = 0 in below k_zfac_x). If all ! the switche are set to zero, wzfac = 1 (default value). ! wzfac(:,:) = 1.0 IF( if_zfac_uv == 1 ) THEN DO j=jts,jtf DO i=itsu,itf DO k=kts,ktf IF( k <= k_zfac_uv ) wzfac(k, 1:2) = 0.0 IF( k == k_zfac_uv+1 ) wzfac(k, 1:2) = 0.1 IF( k > k_zfac_uv+1 ) wzfac(k, 1:2) = 1.0 ENDDO ENDDO ENDDO ENDIF IF( if_zfac_t == 1 ) THEN DO j=jts,jtf DO i=itsu,itf DO k=kts,ktf IF( k <= k_zfac_t ) wzfac(k, 3) = 0.0 IF( k == k_zfac_t+1 ) wzfac(k, 3) = 0.1 IF( k > k_zfac_t+1 ) wzfac(k, 3) = 1.0 ENDDO ENDDO ENDDO ENDIF IF( if_zfac_q == 1 ) THEN DO j=jts,jtf DO i=itsu,itf DO k=kts,ktf IF( k <= k_zfac_q ) wzfac(k, 4) = 0.0 IF( k == k_zfac_q+1 ) wzfac(k, 4) = 0.1 IF( k > k_zfac_q+1 ) wzfac(k, 4) = 1.0 ENDDO ENDDO ENDDO ENDIF ! ! If if_ramping and dtramp_min are defined by user, comput a time weighting function, tfac, ! for analysis nudging so that at the end of the nudging period (which has to be at a ! analysis time) we ramp down the nudging coefficient, based on the use-defined sign of dtramp_min. ! ! When dtramp_min is negative, ramping ends at end_fdda_hour and starts at ! end_fdda_hour-ABS(dtramp_min). ! ! When dtramp_min is positive, ramping starts at end_fdda_hour and ends at ! end_fdda_hour+ABS(dtramp_min). In this case, the obs values are extrapolated using ! the obs tendency saved from the previous FDDA wondow. More specifically for extrapolation, ! coef (see codes below) is recalculated to reflect extrapolation during the ramping period. ! tfac = 1.0 IF( if_ramping == 1 .AND. ABS(dtramp_min) > 0.0 ) THEN IF( dtramp_min <= 0.0 ) THEN actual_end_fdda_min = end_fdda_hour*60.0 ELSE actual_end_fdda_min = end_fdda_hour*60.0 + dtramp_min ENDIF IF( xtime < actual_end_fdda_min-ABS(dtramp_min) )THEN tfac = 1.0 ELSEIF( xtime >= actual_end_fdda_min-ABS(dtramp_min) .AND. xtime <= actual_end_fdda_min )THEN tfac = ( actual_end_fdda_min - xtime ) / ABS(dtramp_min) IF( dtramp_min > 0.0 ) coef = (xtime-xtime_old+analysis_interval)/(analysis_interval*1.0) ELSE tfac = 0.0 ENDIF ENDIF ! ! Surface Analysis Nudging ! IF( grid_sfdda == 1 ) THEN CALL SFDDAGD(itimestep,dx,dt,xtime, id, & analysis_interval_sfc, end_fdda_hour_sfc, guv_sfc, gt_sfc, gq_sfc, & rinblw, & u3d,v3d,th3d,t3d, & qv3d, & p3d,pi3d, & u10_ndg_old, v10_ndg_old, t2_ndg_old, th2_ndg_old, q2_ndg_old, & rh_ndg_old, psl_ndg_old, ps_ndg_old, tob_ndg_old, odis_ndg_old, & u10_ndg_new, v10_ndg_new, t2_ndg_new, th2_ndg_new, q2_ndg_new, & rh_ndg_new, psl_ndg_new, ps_ndg_new, tob_ndg_new, odis_ndg_new, & RUNDGDTEN,RVNDGDTEN,RTHNDGDTEN,RQVNDGDTEN,RMUNDGDTEN,& pblh, ht, regime, znt, z, z_at_w, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte, wpbl, wzfac, if_ramping, dtramp_min, & actual_end_fdda_min, tfac ) ENDIF ! ! Compute 3-D nudging tendencies for u, v, t and q ! DO j=jts,jtf DO k=kts,ktf DO i=itsu,itf val_analysis = u_ndg_old(i,k,j) *( 1.0 - coef ) + u_ndg_new(i,k,j) * coef RUNDGDTEN(i,k,j) = RUNDGDTEN(i,k,j) + guv * wpbl(i,k,j,1) * wzfac(k,1) * tfac * & ( val_analysis - u3d(i,k,j) ) ENDDO ENDDO ENDDO DO j=jtsv,jtf DO k=kts,ktf DO i=its,itf val_analysis = v_ndg_old(i,k,j) *( 1.0 - coef ) + v_ndg_new(i,k,j) * coef RVNDGDTEN(i,k,j) = RVNDGDTEN(i,k,j) + guv * wpbl(i,k,j,2) * wzfac(k,2) * tfac * & ( val_analysis - v3d(i,k,j) ) ENDDO ENDDO ENDDO DO j=jts,jtf DO k=kts,ktf DO i=its,itf val_analysis = t_ndg_old(i,k,j) *( 1.0 - coef ) + t_ndg_new(i,k,j) * coef RTHNDGDTEN(i,k,j) = RTHNDGDTEN(i,k,j) + gt * wpbl(i,k,j,3) * wzfac(k,3) * tfac * & ( val_analysis - th3d(i,k,j) + 300.0 ) val_analysis = q_ndg_old(i,k,j) *( 1.0 - coef ) + q_ndg_new(i,k,j) * coef RQVNDGDTEN(i,k,j) = RQVNDGDTEN(i,k,j) + gq * wpbl(i,k,j,4) * wzfac(k,4) * tfac * & ( val_analysis - qv3d(i,k,j) ) ENDDO ENDDO ENDDO END SUBROUTINE fddagd !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! SUBROUTINE sfddagd(itimestep,dx,dt,xtime, & id, analysis_interval_sfc, end_fdda_hour_sfc, & guv_sfc, gt_sfc, gq_sfc, rinblw, & u3d,v3d,th3d,t3d, & qv3d, & p3d,pi3d, & u10_ndg_old, v10_ndg_old, t2_ndg_old, th2_ndg_old, q2_ndg_old, & rh_ndg_old, psl_ndg_old, ps_ndg_old, tob_ndg_old, odis_ndg_old, & u10_ndg_new, v10_ndg_new, t2_ndg_new, th2_ndg_new, q2_ndg_new, & rh_ndg_new, psl_ndg_new, ps_ndg_new, tob_ndg_new, odis_ndg_new, & RUNDGDTEN,RVNDGDTEN,RTHNDGDTEN,RQVNDGDTEN,RMUNDGDTEN, & pblh, ht, regime, znt, z, z_at_w, & ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte, wpbl, wzfac, if_ramping, dtramp_min, & actual_end_fdda_min, tfac) !------------------------------------------------------------------- USE module_model_constants implicit none !------------------------------------------------------------------- ! ! This code was implemented by Aijun Deng (Penn State). The 3-D analysis nudging was comleted ! and released in December 2006. The surface analysis nudging capability was added and ! released in March 2009 with WRFV3.1. ! !-- u3d 3d u-velocity staggered on u points !-- v3d 3d v-velocity staggered on v points !-- th3d 3d potential temperature (k) !-- t3d temperature (k) !-- qv3d 3d water vapor mixing ratio (kg/kg) !-- p3d 3d pressure (pa) !-- pi3d 3d exner function (dimensionless) !-- rundgdten staggered u tendency due to ! fdda grid nudging (m/s/s) !-- rvndgdten staggered v tendency due to ! fdda grid nudging (m/s/s) !-- rthndgdten theta tendency due to ! fdda grid nudging (K/s) !-- rqvndgdten qv tendency due to ! fdda grid nudging (kg/kg/s) !-- rmundgdten mu tendency due to ! fdda grid nudging (Pa/s) !-- ids start index for i in domain !-- ide end index for i in domain !-- jds start index for j in domain !-- jde end index for j in domain !-- kds start index for k in domain !-- kde end index for k in domain !-- ims start index for i in memory !-- ime end index for i in memory !-- jms start index for j in memory !-- jme end index for j in memory !-- kms start index for k in memory !-- kme end index for k in memory !-- its start index for i in tile !-- ite end index for i in tile !-- jts start index for j in tile !-- jte end index for j in tile !-- kts start index for k in tile !-- kte end index for k in tile !------------------------------------------------------------------- ! INTEGER, INTENT(IN) :: itimestep, analysis_interval_sfc, end_fdda_hour_sfc INTEGER , INTENT(IN) :: id REAL, INTENT(IN) :: dx,DT, xtime INTEGER, INTENT(IN) :: ids,ide, jds,jde, kds,kde, & ims,ime, jms,jme, kms,kme, & its,ite, jts,jte, kts,kte REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(IN) :: qv3d, & p3d, & pi3d, & th3d, & t3d, & z, & z_at_w REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(INOUT) :: rundgdten, & rvndgdten, & rthndgdten, & rqvndgdten REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(INOUT) :: rmundgdten REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN) :: u10_ndg_old, & v10_ndg_old, & t2_ndg_old, & th2_ndg_old, & q2_ndg_old, & rh_ndg_old, & psl_ndg_old, & ps_ndg_old, & u10_ndg_new, & v10_ndg_new, & t2_ndg_new, & th2_ndg_new, & q2_ndg_new, & rh_ndg_new, & psl_ndg_new, & ps_ndg_new REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN) :: tob_ndg_old, & tob_ndg_new REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), & INTENT(IN) :: u3d, & v3d REAL, DIMENSION( ims:ime, jms:jme ), & INTENT(IN) :: odis_ndg_old, odis_ndg_new REAL, DIMENSION( ims:ime, jms:jme ), INTENT(IN) :: pblh, & ht, & regime, & znt REAL, INTENT(IN) :: guv_sfc, gt_sfc, gq_sfc, rinblw INTEGER :: i, j, k, itsu, jtsv, itf, jtf, ktf, i0, j0 REAL :: xtime_old_sfc, xtime_new_sfc, coef, val_analysis, es INTEGER :: kpbl, dbg_level REAL :: zpbl, zagl, zagl_bot, zagl_top, tfac, actual_end_fdda_min REAL, DIMENSION( its:ite, kts:kte, jts:jte, 4 ), & INTENT(IN) :: wpbl ! 1: u, 2: v, 3: t, 4: q REAL, DIMENSION( kts:kte, 4 ), & INTENT(IN) :: wzfac ! 1: u, 2: v, 3: t, 4: q REAL, DIMENSION( its:ite, jts:jte) :: wndcor_u, wndcor_v REAL, DIMENSION( its-2:ite+1, jts-2:jte+1) :: blw_old, blw_new REAL, DIMENSION( its:ite, kts:kte, jts:jte) :: qsat REAL :: m, b=1.8, blw, rindx, x REAL :: difz, wr14, wr1z, wr24, wr2z, wndfac, reg, znt0 INTEGER, INTENT(IN) :: if_ramping REAL, INTENT(IN) :: dtramp_min LOGICAL , EXTERNAL :: wrf_dm_on_monitor CHARACTER (LEN=256) :: message INTEGER :: iwinds, idd, iqsat, int4 iwinds = 1 ! 1: Scale the surface wind analysis to the lowest model level, ! if the first model half-layer is greater than 10 meters ! and we are in the free convection regime (REGIME=4.0). else: no idd = 1 ! 1: Obs data density correction is applied. else: no iqsat = 1 ! 1: Remove super saturation. eles: no int4 = 1 ! 1: temporal ionterpolation. else: target nudging toward *_ndg_new values IF( analysis_interval_sfc <= 0 )CALL wrf_error_fatal('In grid sfc FDDA, sgfdda_interval_m must be > 0') xtime_old_sfc = FLOOR(xtime/analysis_interval_sfc) * analysis_interval_sfc * 1.0 xtime_new_sfc = xtime_old_sfc + analysis_interval_sfc IF( int4 == 1 ) THEN coef = (xtime-xtime_old_sfc)/(xtime_new_sfc-xtime_old_sfc) ! Temporal interpolation ELSE coef = 1.0 ! Nudging toward a target value (*_ndg_new values) ENDIF IF ( wrf_dm_on_monitor()) THEN CALL get_wrf_debug_level( dbg_level ) IF( xtime-xtime_old_sfc < 0.5*dt/60.0 ) THEN IF( xtime < end_fdda_hour_sfc*60.0 ) THEN WRITE(message,'(a,i1,a,f10.3,a)') & 'D0',id,' surface analysis nudging reads new data at time = ', xtime, ' min.' CALL wrf_message( TRIM(message) ) WRITE(message,'(a,i1,a,2f8.2,a)') & 'D0',id,' surface analysis nudging bracketing times = ', xtime_old_sfc, xtime_new_sfc, ' min.' CALL wrf_message( TRIM(message) ) ENDIF IF( dbg_level .GE. 10 .AND. xtime <= actual_end_fdda_min ) THEN ! Find the mid point of the tile and print out the sample values i0 = (ite-its)/2+its j0 = (jte-jts)/2+jts IF( guv_sfc > 0.0 ) THEN WRITE(message,'(a,i1,a,2i4,a,f10.4,a,f10.4)') & ' D0',id,' sample surface analysis values at i,j=', i0, j0, & ' u10_ndg_old=', u10_ndg_old(i0,j0), ' u10_ndg_new=', u10_ndg_new(i0,j0) CALL wrf_message( TRIM(message) ) WRITE(message,'(a,i1,a,2i4,a,f10.4,a,f10.4)') & ' D0',id,' sample surface analysis values at i,j=', i0, j0, & ' v10_ndg_old=', v10_ndg_old(i0,j0), ' v10_ndg_new=', v10_ndg_new(i0,j0) CALL wrf_message( TRIM(message) ) ENDIF IF( gt_sfc > 0.0 ) THEN WRITE(message,'(a,i1,a,2i4,a,f10.4,a,f10.4)') & ' D0',id,' sample surface analysis values at i,j=', i0, j0, & ' th2_ndg_old=', th2_ndg_old(i0,j0), ' th2_ndg_new=', th2_ndg_new(i0,j0) CALL wrf_message( TRIM(message) ) ENDIF IF( gq_sfc > 0.0 ) THEN WRITE(message,'(a,i1,a,2i4,a,f10.4,a,f10.4)') & ' D0',id,' sample surface analysis values at i,j=', i0, j0, & ' q2_ndg_old=', q2_ndg_old(i0,j0), ' q2_ndg_new=', q2_ndg_new(i0,j0) CALL wrf_message( TRIM(message) ) ENDIF IF( iwinds == 1 ) & WRITE(message,'(a,i1,a)') ' D0',id, & ' surface wind analysis s scaled to the lowest model level, if dz1 > 10m and REGIME=4.' IF( idd == 1 ) & WRITE(message,'(a,i1,a)') ' D0',id, & ' obs data density is used for additional weighting function' IF( iqsat == 1 ) & WRITE(message,'(a,i1,a)') ' D0',id, & ' super saturation is not allowed for q analysis' IF( int4 == 1 ) then WRITE(message,'(a,i1,a)') ' D0',id, & ' surface nudging towards the temporally interpolated analysis' ELSE WRITE(message,'(a,i1,a)') ' D0',id, & ' surface nudging towards the target analysis' ENDIF ENDIF ENDIF ENDIF jtsv=MAX0(jts,jds+1) itsu=MAX0(its,ids+1) jtf=MIN0(jte,jde-1) ktf=MIN0(kte,kde-1) itf=MIN0(ite,ide-1) ! ! Compute the vertical weighting function to scale the surface wind analysis to ! the lowest model level, if the first model half-layer is greater ! than 10 meters and we are in the free convection regime (REGIME=4.0). ! IF( iwinds == 1 ) THEN wndcor_u(:,:) = 1.0 DO j=jts,jtf DO i=itsu,itf reg = 0.5 * ( regime(i-1, j) + regime(i, j) ) difz = 0.5 * ( z(i-1,1,j) - ht(i-1,j) & + z(i, 1,j) - ht(i, j) ) IF( reg > 3.5 .AND. difz > 10.0 ) THEN znt0 = 0.5 * ( znt(i-1, j) + znt(i, j) ) IF( znt0 <= 0.2) THEN wndcor_u(i,j) = 1.0+0.320*znt0**0.2 ELSE wndcor_u(i,j) = 1.169+0.315*znt0 ENDIF wr14 = log(40.0/0.05) wr1z = log(difz/0.05) wr24 = log(40.0/1.0) wr2z = log(difz/1.0) wndfac = 0.5*(WR1Z/WR14+WR2Z/WR24) wndcor_u(i,j) = wndfac*wndcor_u(i,j) ENDIF ENDDO ENDDO IF ( wrf_dm_on_monitor()) THEN IF( xtime-xtime_old_sfc < 0.5*dt/60.0 ) THEN IF( dbg_level .GE. 10 .AND. xtime <= actual_end_fdda_min ) THEN i0 = (ite-its)/2+its j0 = (jte-jts)/2+jts WRITE(message,'(a,i1,a,2i4,a,f10.4)') & ' D0',id,' sample wndcor_u values at i,j=', i0, j0, & ' wndcor_u=', wndcor_u(i0,j0) CALL wrf_message( TRIM(message) ) ENDIF ENDIF ENDIF ELSE wndcor_u(:,:) = 1.0 ENDIF IF( iwinds == 1 ) THEN wndcor_v(:,:) = 1.0 DO j=jtsv,jtf DO i=its,itf reg = 0.5 * ( regime(i, j-1) + regime(i, j) ) difz = 0.5 * ( z(i,1,j-1) - ht(i,j-1) & + z(i,1,j ) - ht(i,j ) ) IF( reg > 3.5 .AND. difz > 10.0 ) THEN znt0 = 0.5 * ( znt(i, j-1) + znt(i, j) ) IF( znt0 <= 0.2) THEN wndcor_v(i,j) = 1.0+0.320*znt0**0.2 ELSE wndcor_v(i,j) = 1.169+0.315*znt0 ENDIF wr14 = log(40.0/0.05) wr1z = log(difz/0.05) wr24 = log(40.0/1.0) wr2z = log(difz/1.0) wndfac = 0.5*(WR1Z/WR14+WR2Z/WR24) wndcor_v(i,j) = wndfac*wndcor_v(i,j) ENDIF ENDDO ENDDO IF ( wrf_dm_on_monitor()) THEN IF( xtime-xtime_old_sfc < 0.5*dt/60.0 ) THEN IF( dbg_level .GE. 10 .AND. xtime <= actual_end_fdda_min ) THEN i0 = (ite-its)/2+its j0 = (jte-jts)/2+jts WRITE(message,'(a,i1,a,2i4,a,f10.4)') & ' D0',id,' sample wndcor_v values at i,j=', i0, j0, & ' wndcor_v=', wndcor_v(i0,j0) CALL wrf_message( TRIM(message) ) ENDIF ENDIF ENDIF ELSE wndcor_v(:,:) = 1.0 ENDIF ! ! Compute saturation mixing ratio so that nudging to a super-saturated state ! is not allowed. ! IF( iqsat == 1 ) THEN DO j=jts,jtf DO k=kts,ktf DO i=its,itf es = SVP1*EXP(SVP2*(t3d(i,k,j)-SVPT0)/(t3d(i,k,j)-SVP3)) * 10.0 ! mb qsat(i,k,j) = EP_2*es/(p3d(i,k,j)/100.0-es) ENDDO ENDDO ENDDO IF ( wrf_dm_on_monitor()) THEN IF( xtime-xtime_old_sfc < 0.5*dt/60.0 ) THEN IF( dbg_level .GE. 10 .AND. xtime <= actual_end_fdda_min ) THEN i0 = (ite-its)/2+its j0 = (jte-jts)/2+jts DO k = kts, kte WRITE(message,'(a,i1,a,3i4,a,f10.4,a,f10.4)') & ' D0',id,' sample moisture values (g/kg) at i,k,j=', i0, k, j0, & ' qv3d=', qv3d(i0,k,j0)*1000.0, ' qsat=', qsat(i0,k,j0)*1000.0 CALL wrf_message( TRIM(message) ) ENDDO ENDIF ENDIF ENDIF ENDIF ! ! Obs data density weighting. ! IF( idd == 1 ) THEN IF( rinblw < 0.001 ) THEN IF ( wrf_dm_on_monitor()) THEN WRITE(message,'(a)') 'Error in rinblw, please specify a reasonable value ***' CALL wrf_message( TRIM(message) ) ENDIF CALL wrf_error_fatal('In grid FDDA') ENDIF rindx = rinblw*1000.0/dx m = -0.8*2.0/rindx DO j=MAX(jts-2,jds),MIN(jtf+1,jde-1) DO i=MAX(its-2,ids),MIN(itf+1,ide-1) IF( odis_ndg_old(i,j) < 0.5*rinblw ) THEN blw_old(i,j) = 1.0 ELSE x = min( odis_ndg_old(i,j)*1000./dx, rindx ) blw_old(i,j) = m * x + b ENDIF IF( odis_ndg_new(i,j) < 0.5*rinblw ) THEN blw_new(i,j) = 1.0 ELSE x = min( odis_ndg_new(i,j)*1000./dx, rindx ) blw_new(i,j) = m * x + b ENDIF ENDDO ENDDO ! Smoother applies one point outside the tile, but one point in from boundaries CALL smther(blw_old, its-2,itf+1, jts-2,jtf+1, 1, & MAX(its-2,ids+1), MIN(ite+1,ide-2), MAX(jts-2,jds+1), MIN(jte+1,jde-2)) CALL smther(blw_new, its-2,itf+1, jts-2,jtf+1, 1, & MAX(its-2,ids+1), MIN(ite+1,ide-2), MAX(jts-2,jds+1), MIN(jte+1,jde-2)) WHERE ( blw_old > 1.0) blw_old = 1.0 END WHERE WHERE ( blw_new > 1.0) blw_new = 1.0 END WHERE WHERE ( blw_old < 0.0) blw_old = 0.0 END WHERE WHERE ( blw_new < 0.0) blw_new = 0.0 END WHERE IF ( wrf_dm_on_monitor()) THEN IF( xtime-xtime_old_sfc < 0.5*dt/60.0 ) THEN IF( dbg_level .GE. 10 .AND. xtime <= actual_end_fdda_min ) THEN i0 = (ite-its)/2+its j0 = (jte-jts)/2+jts WRITE(message,'(a,i1,a,2i4,4(a,f10.4))') & ' D0',id,' sample blw values at i,j=', i0, j0, & ' odis_ndg_old=', odis_ndg_old(i0,j0), ' km odis_ndg_new=', odis_ndg_new(i0,j0), & ' km blw_old=', blw_old(i0,j0), ' blw_new=', blw_new(i0,j0) CALL wrf_message( TRIM(message) ) ENDIF ENDIF ENDIF ENDIF ! ! TFAC for surface analysis nudging ! IF( xtime >= actual_end_fdda_min-ABS(dtramp_min) .AND. xtime <= actual_end_fdda_min & .AND. dtramp_min > 0.0 .AND. if_ramping == 1 ) & coef = (xtime-xtime_old_sfc+analysis_interval_sfc)/(analysis_interval_sfc*1.0) ! print*, 'coef =', xtime_old_sfc, xtime, xtime_new_sfc, coef ! ! Compute surface analysis nudging tendencies for u, v, t and q ! DO j=jts,jtf DO k=kts,ktf DO i=itsu,itf IF( idd == 1 ) THEN blw = 0.5* (blw_old(i-1,j)+blw_old(i,j)) * ( 1.0 - coef ) & + 0.5* (blw_new(i-1,j)+blw_new(i,j)) * coef ELSE blw = 1.0 ENDIF val_analysis = u10_ndg_old(i,j) *( 1.0 - coef ) + u10_ndg_new(i,j) * coef val_analysis = val_analysis * wndcor_u(i,j) RUNDGDTEN(i,k,j) = guv_sfc * (1.0-wpbl(i,k,j,1)) * wzfac(k,1) * tfac * blw * & ( val_analysis - u3d(i,1,j) ) ENDDO ENDDO ENDDO DO j=jtsv,jtf DO k=kts,ktf DO i=its,itf IF( idd == 1 ) THEN blw = 0.5* (blw_old(i,j-1)+blw_old(i,j)) * ( 1.0 - coef ) & + 0.5* (blw_new(i,j-1)+blw_new(i,j)) * coef ELSE blw = 1.0 ENDIF val_analysis = v10_ndg_old(i,j) *( 1.0 - coef ) + v10_ndg_new(i,j) * coef val_analysis = val_analysis * wndcor_v(i,j) RVNDGDTEN(i,k,j) = guv_sfc * (1.0-wpbl(i,k,j,2)) * wzfac(k,2) * tfac * blw * & ( val_analysis - v3d(i,1,j) ) ENDDO ENDDO ENDDO DO j=jts,jtf DO k=kts,ktf DO i=its,itf IF( idd == 1 ) THEN blw = blw_old(i,j) * ( 1.0 - coef ) + blw_new(i,j) * coef ELSE blw = 1.0 ENDIF val_analysis = th2_ndg_old(i,j) *( 1.0 - coef ) + th2_ndg_new(i,j) * coef RTHNDGDTEN(i,k,j) = gt_sfc * (1.0-wpbl(i,k,j,3)) * wzfac(k,3) * tfac * blw * & ( val_analysis - th3d(i,1,j)) val_analysis = q2_ndg_old(i,j) *( 1.0 - coef ) + q2_ndg_new(i,j) * coef IF( iqsat == 1 .AND. val_analysis > qsat(i,k,j) ) val_analysis = qsat(i,k,j) RQVNDGDTEN(i,k,j) = gq_sfc * (1.0-wpbl(i,k,j,4)) * wzfac(k,4) * tfac * blw * & ( val_analysis - qv3d(i,k,j) ) ENDDO ENDDO ENDDO END SUBROUTINE sfddagd !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! SUBROUTINE fddagdinit(id,rundgdten,rvndgdten,rthndgdten,rqvndgdten,rmundgdten,& run_hours, & if_no_pbl_nudging_uv, if_no_pbl_nudging_t, if_no_pbl_nudging_q, & if_zfac_uv, k_zfac_uv, if_zfac_t, k_zfac_t, if_zfac_q, k_zfac_q, & guv, gt, gq, if_ramping, dtramp_min, end_fdda_hour, & grid_sfdda, guv_sfc, gt_sfc, gq_sfc, & restart, allowed_to_read, & ids, ide, jds, jde, kds, kde, & ims, ime, jms, jme, kms, kme, & its, ite, jts, jte, kts, kte ) !------------------------------------------------------------------- IMPLICIT NONE !------------------------------------------------------------------- ! INTEGER , INTENT(IN) :: id LOGICAL, INTENT(IN) :: restart, allowed_to_read INTEGER, INTENT(IN) :: ids, ide, jds, jde, kds, kde, & ims, ime, jms, jme, kms, kme, & its, ite, jts, jte, kts, kte REAL, DIMENSION( ims:ime , kms:kme , jms:jme ), INTENT(OUT) :: & rundgdten, & rvndgdten, & rthndgdten, & rqvndgdten INTEGER, INTENT(IN) :: run_hours INTEGER, INTENT(IN) :: if_no_pbl_nudging_uv, if_no_pbl_nudging_t, & if_no_pbl_nudging_q, end_fdda_hour INTEGER, INTENT(IN) :: if_zfac_uv, if_zfac_t, if_zfac_q INTEGER, INTENT(IN) :: k_zfac_uv, k_zfac_t, k_zfac_q INTEGER, INTENT(IN) :: if_ramping, grid_sfdda REAL, INTENT(IN) :: dtramp_min REAL, INTENT(IN) :: guv, gt, gq REAL, INTENT(IN) :: guv_sfc, gt_sfc, gq_sfc REAL :: actual_end_fdda_min REAL, DIMENSION( ims:ime , jms:jme ), INTENT(OUT) :: rmundgdten INTEGER :: i, j, k LOGICAL , EXTERNAL :: wrf_dm_on_monitor CHARACTER (LEN=256) :: message IF ( wrf_dm_on_monitor() ) THEN IF( guv > 0.0 ) THEN WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' 3-D analysis nudging for wind is applied and Guv= ', guv CALL wrf_message(TRIM(message)) ELSE IF( guv < 0.0 ) THEN CALL wrf_error_fatal('In grid FDDA, Guv must be positive.') ELSE WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' 3-D analysis nudging for wind is not applied and Guv= ', guv CALL wrf_message(TRIM(message)) ENDIF IF( gt > 0.0 ) THEN WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' 3-D analysis nudging for temperature is applied and Gt= ', gt CALL wrf_message(TRIM(message)) ELSE IF( gt < 0.0 ) THEN CALL wrf_error_fatal('In grid FDDA, Gt must be positive.') ELSE WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' 3-D analysis nudging for temperature is not applied and Gt= ', gt CALL wrf_message(TRIM(message)) ENDIF IF( gq > 0.0 ) THEN WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' 3-D analysis nudging for water vapor mixing ratio is applied and Gq= ', gq CALL wrf_message(TRIM(message)) ELSE IF( gq < 0.0 ) THEN CALL wrf_error_fatal('In grid FDDA, Gq must be positive.') ELSE WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' 3-D analysis nudging for water vapor mixing ratio is not applied and Gq= ', gq CALL wrf_message(TRIM(message)) ENDIF IF( guv > 0.0 .AND. if_no_pbl_nudging_uv == 1 ) THEN WRITE(message,'(a,i1,a)') & 'D0',id,' 3-D analysis nudging for wind is turned off within the PBL.' CALL wrf_message(TRIM(message)) ENDIF IF( gt > 0.0 .AND. if_no_pbl_nudging_t == 1 ) THEN WRITE(message,'(a,i1,a)') & 'D0',id,' 3-D analysis nudging for temperature is turned off within the PBL.' CALL wrf_message(TRIM(message)) ENDIF IF( gq > 0.0 .AND. if_no_pbl_nudging_q == 1 ) THEN WRITE(message,'(a,i1,a)') & 'D0',id,' 3-D analysis nudging for water vapor mixing ratio is turned off within the PBL.' CALL wrf_message(TRIM(message)) ENDIF IF( guv > 0.0 .AND. if_zfac_uv == 1 ) THEN WRITE(message,'(a,i1,a,i3)') & 'D0',id,' 3-D analysis nudging for wind is turned off below layer', k_zfac_uv CALL wrf_message(TRIM(message)) ENDIF IF( gt > 0.0 .AND. if_zfac_t == 1 ) THEN WRITE(message,'(a,i1,a,i3)') & 'D0',id,' 3-D analysis nudging for temperature is turned off below layer', k_zfac_t CALL wrf_message(TRIM(message)) ENDIF IF( gq > 0.0 .AND. if_zfac_q == 1 ) THEN WRITE(message,'(a,i1,a,i3)') & 'D0',id,' 3-D analysis nudging for water vapor mixing ratio is turned off below layer', & k_zfac_q CALL wrf_message(TRIM(message)) ENDIF IF( grid_sfdda ==1 ) THEN IF( guv_sfc > 0.0 ) THEN WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' surface analysis nudging for wind is applied and Guv_sfc= ', guv_sfc CALL wrf_message(TRIM(message)) ELSE IF( guv_sfc < 0.0 ) THEN CALL wrf_error_fatal('In grid FDDA, Guv_sfc must be positive.') ELSE WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' surface analysis nudging for wind is not applied and Guv_sfc= ', guv_sfc CALL wrf_message(TRIM(message)) ENDIF IF( gt_sfc > 0.0 ) THEN WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' surface analysis nudging for temperature is applied and Gt_sfc= ', gt_sfc CALL wrf_message(TRIM(message)) ELSE IF( gt_sfc < 0.0 ) THEN CALL wrf_error_fatal('In grid FDDA, Gt_sfc must be positive.') ELSE WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' surafce analysis nudging for temperature is not applied and Gt_sfc= ', gt_sfc CALL wrf_message(TRIM(message)) ENDIF IF( gq_sfc > 0.0 ) THEN WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' surface analysis nudging for water vapor mixing ratio is applied and Gq_sfc= ', gq_sfc CALL wrf_message(TRIM(message)) ELSE IF( gq_sfc < 0.0 ) THEN CALL wrf_error_fatal('In grid FDDA, Gq_sfc must be positive.') ELSE WRITE(message,'(a,i1,a,e12.4)') & 'D0',id,' surface analysis nudging for water vapor mixing ratio is not applied and Gq_sfc= ', gq_sfc CALL wrf_message(TRIM(message)) ENDIF ENDIF IF( if_ramping == 1 .AND. ABS(dtramp_min) > 0.0 ) THEN IF( dtramp_min <= 0.0 ) THEN actual_end_fdda_min = end_fdda_hour*60.0 ELSE actual_end_fdda_min = end_fdda_hour*60.0 + ABS(dtramp_min) ENDIF IF( actual_end_fdda_min <= run_hours*60. ) THEN WRITE(message,'(a,i1,a)') & 'D0',id,' analysis nudging is ramped down near the end of the nudging period,' CALL wrf_message(TRIM(message)) WRITE(message,'(a,f6.2,a,f6.2,a)') & ' starting at ', (actual_end_fdda_min - ABS(dtramp_min))/60.0, & 'h, ending at ', actual_end_fdda_min/60.0,'h.' CALL wrf_message(TRIM(message)) ENDIF ENDIF ENDIF IF(.not.restart) THEN DO j = jts,jte DO k = kts,kte DO i = its,ite rundgdten(i,k,j) = 0. rvndgdten(i,k,j) = 0. rthndgdten(i,k,j) = 0. rqvndgdten(i,k,j) = 0. if(k.eq.kts) rmundgdten(i,j) = 0. ENDDO ENDDO ENDDO ENDIF END SUBROUTINE fddagdinit !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! SUBROUTINE smther(slab, idimst, idimnd, jdimst, jdimnd, npass, ist, ind, jst, jnd) ! ! PURPOSE: SPATIALLY SMOOTH DATA IN SLAB TO DAMPEN SHORT ! WAVELENGTH COMPONENTS. ! ! Implemented based on the same smoothing subroutine used in MM5, with modifications to ! remove the extra loop that causes unneccessary desmoothing. Aijun Deng (Penn State), ! December 2008 ! IMPLICIT NONE INTEGER :: idimst, idimnd, jdimst, jdimnd, npass, ist, ind, jst, jnd INTEGER :: i, j, k, kp REAL :: asv, aplus, cell REAL, DIMENSION(idimst:idimnd, jdimst:jdimnd) :: SLAB REAL, DIMENSION(2) :: XNU IF(NPASS.EQ.0)RETURN XNU(1)=0.50 XNU(2)=-0.52 DO K=1,NPASS ! FIRST, SMOOTH IN THE J DIRECTION DO J=JST,JND ASV=SLAB(IST-1,J) DO I=IST,IND APLUS=SLAB(I+1,J) CELL=SLAB(I,J) SLAB(I,J)=SLAB(I,J)+XNU(K)*((ASV+APLUS)/2.0-SLAB(I,J)) ASV=CELL ENDDO ENDDO ! NOW, SMOOTH IN THE I DIRECTION DO I=IST,IND ASV=SLAB(I,JST-1) DO J=JST,JND APLUS=SLAB(I,J+1) CELL=SLAB(I,J) SLAB(I,J)=SLAB(I,J)+XNU(K)*((ASV+APLUS)/2.0-SLAB(I,J)) ASV=CELL ENDDO ENDDO ENDDO END SUBROUTINE smther !------------------------------------------------------------------- END MODULE module_fdda_psufddagd