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C $Header: /u/gcmpack/MITgcm/pkg/diagnostics/prestopres.F,v 1.3 2005/10/25 16:27:30 molod Exp $ |
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C $Name: $ |
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#include "DIAG_OPTIONS.h" |
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|
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C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-|--+----| |
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CBOP 0 |
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C !ROUTINE: DIAGNOSTICS_INTERP_P2P |
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|
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C !INTERFACE: |
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SUBROUTINE DIAGNOSTICS_INTERP_P2P( |
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O qprs, |
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I qinp,pkz,pksrf,pktop,pk, |
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I undef, pInc,ijm,lm, myThid ) |
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|
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C !DESCRIPTION: |
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C*********************************************************************** |
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C |
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C PURPOSE |
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C To interpolate an arbitrary quantity to Specified Pressure Levels |
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C |
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C INPUT |
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C QINP .. QINP (ijm,lm) Arbitrary Input Quantity |
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C PKZ ... PKZ (ijm,lm) Pressure to the Kappa at Input Levels |
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C PKSRF . PKSRF(ijm) Surface Pressure to the Kappa |
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C PKTOP . Pressure to the Kappa at Input-Level-Edge (1) (top of model) |
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C PK .... Output Pressure to the Kappa Level (mb) |
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C pInc .. if True, assume pressure increases with level index |
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C IJM ... Horizontal Dimension of Input |
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C LM .... Vertical Dimension of Input |
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C |
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C OUTPUT |
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C QPRS .. QPRS (ijm) Arbitrary Quantity at Pressure p |
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C |
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C NOTE |
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C Quantity is interpolated Linear in P**Kappa. |
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C Between PTOP**Kappa and PKZ(1), quantity is extrapolated. |
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C Between PKSRF**Kappa and PKZ(LM), quantity is extrapolated. |
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C Undefined Input quantities are not used. |
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C Finally: This routine assumes that pressure levels are counted |
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C top down -- ie, level 1 is the top, level lm is the bottom |
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C |
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C*********************************************************************** |
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C !USES: |
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IMPLICIT NONE |
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|
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C !INPUT PARAMETERS: |
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INTEGER ijm,lm,myThid |
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_RL qinp (ijm,lm) |
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_RL pkz (ijm,lm) |
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_RL pksrf(ijm) |
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_RL pktop,pk |
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_RL undef |
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LOGICAL pInc |
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|
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C !OUTPUT PARAMETERS: |
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_RL qprs (ijm) |
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CEOP |
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|
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C !LOCAL VARIABLES: |
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INTEGER i,l |
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_RL pkmin,pkmax,temp |
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|
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C---+----1----+----2----+----3----+----4----+----5----+----6----+----7-|--+----| |
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|
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c Initialize to UNDEFINED |
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c ----------------------- |
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DO i=1,ijm |
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qprs(i) = undef |
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ENDDO |
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|
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IF ( pInc ) THEN |
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C--- Case where Levels are orderd by increasing pressure |
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|
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c Interpolate to Pressure Between Input Levels |
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c -------------------------------------------- |
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DO L=1,lm-1 |
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pkmin = pkz(1,L) |
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pkmax = pkz(1,L+1) |
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|
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DO i=2,ijm |
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IF ( pkz(i,L) .LT.pkmin ) pkmin = pkz(i,L) |
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IF ( pkz(i,L+1).GT.pkmax ) pkmax = pkz(i,L+1) |
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ENDDO |
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|
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IF ( pk.LE.pkmax .AND. pk.GE.pkmin ) THEN |
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DO i=1,ijm |
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IF ( pk.GE.pkz(i,L) .AND. pk.LE.pkz(i,L+1) ) THEN |
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temp = ( pk-pkz(i,L) ) / ( pkz(i,L+1)-pkz(i,L) ) |
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|
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IF ( qinp(i,L) .NE.undef .AND. |
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& qinp(i,L+1).NE.undef ) THEN |
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qprs(i) = qinp(i,L+1)*temp + qinp(i,L)*(1.-temp) |
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ELSEIF ( qinp(i,L+1).NE.undef .AND. temp.GE.0.5 ) THEN |
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qprs(i) = qinp(i,L+1) |
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ELSEIF ( qinp(i,L) .NE.undef .AND. temp.LE.0.5 ) THEN |
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qprs(i) = qinp(i,L) |
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ENDIF |
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ENDIF |
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ENDDO |
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ENDIF |
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|
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ENDDO |
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|
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DO i=1,ijm |
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c Extrapolate to Pressure between Ptop and Highest Input Level |
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c ---------------------------------------------------------- |
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IF ( pk.LE.pkz(i,1) .AND. pk.GE.pktop ) THEN |
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temp = ( pk-pkz(i,1) ) / ( pkz(i,2)-pkz(i,1) ) |
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|
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IF ( qinp(i,1).NE.undef .AND. |
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& qinp(i,2).NE.undef ) THEN |
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qprs(i) = qinp(i,2)*temp + qinp(i,1)*(1.-temp) |
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ELSEIF ( qinp(i,1).NE.undef ) THEN |
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qprs(i) = qinp(i,1) |
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ENDIF |
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|
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ENDIF |
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|
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c Extrapolate to Pressure between Psurf and Lowest Input Level |
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c ------------------------------------------------------------ |
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IF ( pk.GE.pkz(i,lm) .AND. pk.LE.pksrf(i) ) THEN |
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temp = ( pk-pkz(i,lm) ) / ( pkz(i,lm-1)-pkz(i,lm) ) |
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|
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IF ( qinp(i,lm) .NE.undef .AND. |
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& qinp(i,lm-1).NE.undef ) THEN |
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qprs(i) = qinp(i,lm-1)*temp + qinp(i,lm)*(1.-temp) |
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ELSEIF ( qinp(i,lm) .NE.undef ) THEN |
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qprs(i) = qinp(i,lm) |
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ENDIF |
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|
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ENDIF |
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ENDDO |
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|
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ELSE |
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C--- Case where Levels are orderd by decreasing pressure |
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|
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c Interpolate to Pressure Between Input Levels |
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c -------------------------------------------- |
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DO L=1,lm-1 |
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pkmin = pkz(1,L+1) |
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pkmax = pkz(1,L) |
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|
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DO i=2,ijm |
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IF ( pkz(i,L+1).LT.pkmin ) pkmin = pkz(i,L+1) |
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IF ( pkz(i,L) .GT.pkmax ) pkmax = pkz(i,L) |
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ENDDO |
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|
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IF ( pk.LE.pkmax .AND. pk.GE.pkmin ) THEN |
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DO i=1,ijm |
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IF ( pk.LE.pkz(i,L) .AND. pk.GE.pkz(i,L+1) ) THEN |
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temp = ( pk-pkz(i,L) ) / ( pkz(i,L+1)-pkz(i,L) ) |
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|
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IF ( qinp(i,L) .NE.undef .AND. |
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& qinp(i,L+1).NE.undef ) THEN |
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qprs(i) = qinp(i,L+1)*temp + qinp(i,L)*(1.-temp) |
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ELSEIF ( qinp(i,L+1).NE.undef .AND. temp.GE.0.5 ) THEN |
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qprs(i) = qinp(i,L+1) |
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ELSEIF ( qinp(i,L) .NE.undef .AND. temp.LE.0.5 ) THEN |
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qprs(i) = qinp(i,L) |
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ENDIF |
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ENDIF |
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ENDDO |
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ENDIF |
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|
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ENDDO |
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|
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DO i=1,ijm |
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c Extrapolate to Pressure between Ptop and Highest Input Level |
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c ---------------------------------------------------------- |
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IF ( pk.LE.pkz(i,lm) .AND. pk.GE.pktop ) THEN |
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temp = ( pk-pkz(i,lm) ) / ( pkz(i,lm-1)-pkz(i,lm) ) |
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|
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IF ( qinp(i,lm) .NE.undef .AND. |
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& qinp(i,lm-1).NE.undef ) THEN |
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qprs(i) = qinp(i,lm-1)*temp + qinp(i,lm)*(1.-temp) |
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ELSEIF ( qinp(i,lm) .NE.undef ) THEN |
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qprs(i) = qinp(i,lm) |
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ENDIF |
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|
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ENDIF |
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|
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c Extrapolate to Pressure between Psurf and Lowest Input Level |
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c ------------------------------------------------------------ |
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IF ( pk.GE.pkz(i,1) .AND. pk.LE.pksrf(i) ) THEN |
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temp = ( pk-pkz(i,1) ) / ( pkz(i,2)-pkz(i,1) ) |
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|
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IF ( qinp(i,1).NE.undef .AND. |
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& qinp(i,2).NE.undef ) THEN |
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qprs(i) = qinp(i,2)*temp + qinp(i,1)*(1.-temp) |
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ELSEIF ( qinp(i,1).NE.undef ) THEN |
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qprs(i) = qinp(i,1) |
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ENDIF |
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|
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ENDIF |
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ENDDO |
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|
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C--- End case increasing/decreasing pressure |
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ENDIF |
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|
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RETURN |
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END |