subroutine state (t, s, rho, js, je, is, ie) #if defined O_mom !======================================================================= ! state computes normalized densities by using a 3rd ! order polynomial fit to the knudsen formula, for each level ! subtract normalizing constants from temperature and salinity ! and compute polynomial approximation of knudsen density. ! note.. for precision purposes, there is a depth dependent ! constant subtracted from the density returned by this routine. ! so... this routine should be used only for horizontal gradients ! of density. ! inputs: ! t = the input row of temperatures (potential deg C) ! s = the input row of salinities (units: (ppt-35)/1000) ! js = starting row for computing density within the MW ! je = ending row for computing density within the MW ! is = starting longitude index for computing density within the MW ! ie = ending longitude index for computing density within the MW ! output: ! rho = normalized densities ! These densities are in cgs units(g/cm3) and represent ! the in situ density at a level minus a depth dependent ! normalization. The complete in situ density is given by ! rho_complete(i,k,j) = dens (t(i,k,j)-to(k), s(i,k,j)-so(k), k, c) ! + rho_norm(k)*10-3, ! where rho_norm(k) are the depth dependent normalization densities ! [in sigma units (density-1)*1000] given at the bottom of dncoef.h !======================================================================= implicit none integer k, j, js, je, i, is, ie, ind, l real dens, tq, sq, drodt, drods include "size.h" include "param.h" include "pconst.h" include "stdunits.h" include "state.h" real t(imt,km,jmw), s(imt,km,jmw), rho(imt,km,jsmw:jmw) include "dens.h" do j=js,je do k=1,km do i=is,ie rho(i,k,j) = dens (t(i,k,j)-to(k), s(i,k,j)-so(k), k) enddo enddo enddo return entry statec (t, s, rho, js, je, is, ie, ind) !======================================================================= ! statec computes, for one row, the normalized densities by using ! a 3rd order polynomial fit to the knudsen formula. For ! purposes of checking vertical stability between adjacent ! levels, the reference depth for pressure dependence in ! the knudsen formula must be held constant. that level is ! determined by "ind". ! inputs: ! t = the input row of temperatures (potential deg C) ! s = the input row of salinities (units: (ppt-35)/1000) ! js = starting row for computing density within the MW ! je = ending row for computing density within the MW ! is = starting longitude index for computing density within the MW ! ie = ending longitude index for computing density within the MW ! ind = 1 for comparing levels 1 to 2, 3 to 4, etc. ! (coefficients for the lower of the 2 levels are used) ! 2 for comparing levels 2 to 3, 4 to 5, etc. ! (coefficients for the lower of the 2 levels are used) ! output: ! rho = normalized densities ! These densities are in cgs units(g/cm3) and represent ! the in situ density at a level minus a depth dependent ! normalization. The complete in situ density is given by ! rho_complete(i,k,j) = dens (t(i,k,j)-to(k), s(i,k,j)-so(k), k, c) ! + rho_norm(k)*10-3, ! where rho_norm(k) are the depth dependent normalization densities ! [in sigma units (density-1)*1000] given at the bottom of dncoef.h !======================================================================= if (ind .lt. 1 .or. ind .gt. 2) then write (stderr,99) ind stop '=>statec' endif do j=js,je do l=1,km,2 if (ind .eq. 1) then k = min(l+1,km) else k = l endif do i=is,ie rho(i,l,j) = dens (t(i,l,j)-to(k), s(i,l,j)-so(k), k) enddo enddo enddo do j=js,je do l=2,km,2 if (ind .eq. 1) then k = l else k = min(l+1,km) endif do i=is,ie rho(i,l,j) = dens (t(i,l,j)-to(k), s(i,l,j)-so(k), k) enddo enddo enddo return 99 format(/' error => bad "ind" in statec: ind =',i10) end subroutine state_ref (t, s, rho, js, je, is, ie, kr) !======================================================================= ! Construct potential density referenced to the level kr. !======================================================================= implicit none integer j, js, je, i, is, ie, kr, k real dens, tq, sq, drodt, drods include "size.h" include "param.h" include "pconst.h" include "stdunits.h" include "state.h" real t(imt,km,jmw), s(imt,km,jmw), rho(imt,km,jsmw:jmw) include "dens.h" do j=js,je do k=1,km do i=is,ie rho(i,k,j) = dens (t(i,k,j)-to(kr), s(i,k,j)-so(kr), kr) enddo enddo enddo #endif return end