! ! $Id: inidissip.F90 2641 2016-09-29 21:26:46Z aborella $ ! SUBROUTINE inidissip ( lstardis,nitergdiv,nitergrot,niterh , & tetagdiv,tetagrot,tetatemp, vert_prof_dissip) !======================================================================= ! initialisation de la dissipation horizontale !======================================================================= !----------------------------------------------------------------------- ! declarations: ! ------------- USE control_mod, only : dissip_period,iperiod USE comconst_mod, ONLY: dissip_deltaz, dissip_factz, dissip_zref, & dtdiss, dtvr, rad USE comvert_mod, ONLY: preff, presnivs IMPLICIT NONE include "dimensions.h" include "paramet.h" include "comdissipn.h" include "iniprint.h" LOGICAL,INTENT(in) :: lstardis INTEGER,INTENT(in) :: nitergdiv,nitergrot,niterh REAL,INTENT(in) :: tetagdiv,tetagrot,tetatemp integer, INTENT(in):: vert_prof_dissip ! Vertical profile of horizontal dissipation ! Allowed values: ! 0: rational fraction, function of pressure ! 1: tanh of altitude ! Local variables: REAL fact,zvert(llm),zz REAL zh(ip1jmp1),zu(ip1jmp1), gx(ip1jmp1), divgra(ip1jmp1) real zv(ip1jm), gy(ip1jm), deltap(ip1jmp1,llm) REAL ullm,vllm,umin,vmin,zhmin,zhmax REAL zllm INTEGER l,ij,idum,ii REAL tetamin REAL pseudoz character (len=80) :: abort_message REAL ran1 !----------------------------------------------------------------------- ! ! calcul des valeurs propres des operateurs par methode iterrative: ! ----------------------------------------------------------------- crot = -1. cdivu = -1. cdivh = -1. ! calcul de la valeur propre de divgrad: ! -------------------------------------- idum = 0 DO l = 1, llm DO ij = 1, ip1jmp1 deltap(ij,l) = 1. ENDDO ENDDO idum = -1 zh(1) = RAN1(idum)-.5 idum = 0 DO ij = 2, ip1jmp1 zh(ij) = RAN1(idum) -.5 ENDDO CALL filtreg (zh,jjp1,1,2,1,.TRUE.,1) CALL minmax(iip1*jjp1,zh,zhmin,zhmax ) IF ( zhmin .GE. zhmax ) THEN write(lunout,*)' Inidissip zh min max ',zhmin,zhmax abort_message='probleme generateur alleatoire dans inidissip' call abort_gcm('inidissip',abort_message,1) ENDIF zllm = ABS( zhmax ) DO l = 1,50 IF(lstardis) THEN CALL divgrad2(1,zh,deltap,niterh,divgra) ELSE CALL divgrad (1,zh,niterh,divgra) ENDIF zllm = ABS(maxval(divgra)) zh = divgra / zllm ENDDO IF(lstardis) THEN cdivh = 1./ zllm ELSE cdivh = zllm ** ( -1./niterh ) ENDIF ! calcul des valeurs propres de gradiv (ii =1) et nxgrarot(ii=2) ! ----------------------------------------------------------------- write(lunout,*)'inidissip: calcul des valeurs propres' DO ii = 1, 2 ! DO ij = 1, ip1jmp1 zu(ij) = RAN1(idum) -.5 ENDDO CALL filtreg (zu,jjp1,1,2,1,.TRUE.,1) DO ij = 1, ip1jm zv(ij) = RAN1(idum) -.5 ENDDO CALL filtreg (zv,jjm,1,2,1,.FALSE.,1) CALL minmax(iip1*jjp1,zu,umin,ullm ) CALL minmax(iip1*jjm, zv,vmin,vllm ) ullm = ABS ( ullm ) vllm = ABS ( vllm ) DO l = 1, 50 IF(ii.EQ.1) THEN !cccc CALL covcont( 1,zu,zv,zu,zv ) IF(lstardis) THEN CALL gradiv2( 1,zu,zv,nitergdiv,gx,gy ) ELSE CALL gradiv ( 1,zu,zv,nitergdiv,gx,gy ) ENDIF ELSE IF(lstardis) THEN CALL nxgraro2( 1,zu,zv,nitergrot,gx,gy ) ELSE CALL nxgrarot( 1,zu,zv,nitergrot,gx,gy ) ENDIF ENDIF zllm = max(abs(maxval(gx)), abs(maxval(gy))) zu = gx / zllm zv = gy / zllm end DO IF ( ii.EQ.1 ) THEN IF(lstardis) THEN cdivu = 1./zllm ELSE cdivu = zllm **( -1./nitergdiv ) ENDIF ELSE IF(lstardis) THEN crot = 1./ zllm ELSE crot = zllm **( -1./nitergrot ) ENDIF ENDIF end DO ! petit test pour les operateurs non star: ! ---------------------------------------- ! IF(.NOT.lstardis) THEN fact = rad*24./REAL(jjm) fact = fact*fact write(lunout,*)'inidissip: coef u ', fact/cdivu, 1./cdivu write(lunout,*)'inidissip: coef r ', fact/crot , 1./crot write(lunout,*)'inidissip: coef h ', fact/cdivh, 1./cdivh ! ENDIF !----------------------------------------------------------------------- ! variation verticale du coefficient de dissipation: ! -------------------------------------------------- if (vert_prof_dissip == 1) then do l=1,llm pseudoz=8.*log(preff/presnivs(l)) zvert(l)=1+ & (tanh((pseudoz-dissip_zref)/dissip_deltaz)+1.)/2. & *(dissip_factz-1.) enddo else DO l=1,llm zvert(l)=1. ENDDO fact=2. DO l = 1, llm zz = 1. - preff/presnivs(l) zvert(l)= fact -( fact-1.)/( 1.+zz*zz ) ENDDO endif write(lunout,*)'inidissip: Constantes de temps de la diffusion horizontale' tetamin = 1.e+6 DO l=1,llm tetaudiv(l) = zvert(l)/tetagdiv tetaurot(l) = zvert(l)/tetagrot tetah(l) = zvert(l)/tetatemp IF( tetamin.GT. (1./tetaudiv(l)) ) tetamin = 1./ tetaudiv(l) IF( tetamin.GT. (1./tetaurot(l)) ) tetamin = 1./ tetaurot(l) IF( tetamin.GT. (1./ tetah(l)) ) tetamin = 1./ tetah(l) ENDDO ! If dissip_period=0 calculate value for dissipation period, else keep value read from gcm.def IF (dissip_period == 0) THEN dissip_period = INT( tetamin/( 2.*dtvr*iperiod) ) * iperiod write(lunout,*)'inidissip: tetamin dtvr iperiod dissip_period(intermed) ',tetamin,dtvr,iperiod,dissip_period dissip_period = MAX(iperiod,dissip_period) END IF dtdiss = dissip_period * dtvr write(lunout,*)'inidissip: dissip_period=',dissip_period,' dtdiss=',dtdiss,' dtvr=',dtvr DO l = 1,llm write(lunout,*)zvert(l),dtdiss*tetaudiv(l),dtdiss*tetaurot(l), & dtdiss*tetah(l) ENDDO END SUBROUTINE inidissip