vtf-logo

src/2d/equations/euler/rprhok/rpn2eurhokvlg.f

c
c =========================================================
      subroutine rpn2eurhok(ixy,maxm,meqn,mwaves,mbc,mx,ql,qr,maux,
     &     auxl,auxr,wave,s,amdq,apdq)
c =========================================================
c
c     # solve Riemann problems for the 2D Euler equations of multiple 
c     # thermally perfect gases  using van Leer's Flux-Vector-Splitting 
c     # following Shuen's approach
c
c     # On input, ql contains the state vector at the left edge of each cell
c     #           qr contains the state vector at the right edge of each cell
c     # On output, wave contains the waves, 
c     #            s the speeds, 
c     #            amdq the positive flux
c     #            apdq the negative flux
c     #            (the fluxes are stored twice to be consistent with the
c     #             flux-difference splitting formulation)
c
c     # Note that the i'th Riemann problem has left state qr(i-1,:)
c     #                                    and right state ql(i,:)
c     # From the basic clawpack routine step1, rp is called with ql = qr = q.
c
c     # Copyright (C) 2002 Ralf Deiterding
c     # Brandenburgische Universitaet Cottbus
c
      implicit double precision (a-h,o-z)
      dimension   ql(1-mbc:maxm+mbc, meqn)
      dimension   qr(1-mbc:maxm+mbc, meqn)
      dimension    s(1-mbc:maxm+mbc, mwaves)
      dimension wave(1-mbc:maxm+mbc, meqn, mwaves)
      dimension amdq(1-mbc:maxm+mbc, meqn)
      dimension apdq(1-mbc:maxm+mbc, meqn)
c
c     define local arrays
c
      include "ck.i"
      dimension Yl(LeNsp), Yr(LeNsp), el(3), er(3)
      dimension fvl(LeNsp+4), fvr(LeNsp+4), rkl(LeNsp), rkr(LeNsp)
      double precision Ml, Mr
c
c     # Riemann solver returns fluxes
c     ------------
      common /rpnflx/ mrpnflx
      mrpnflx = 1
c
c     # set mu to point to  the component of the system that corresponds
c     # to momentum in the direction of this slice, mv to the orthogonal
c     # momentum:
c
      if (ixy.eq.1) then
         mu = Nsp+1
         mv = Nsp+2
      else
         mu = Nsp+2
         mv = Nsp+1
      endif
      mE = Nsp+3
      mT = Nsp+4
c
      do 10 i=2-mbc,mx+mbc
         rhol  = 0.d0
         rhor  = 0.d0
         rhoWl = 0.d0
         rhoWr = 0.d0
         do k = 1, Nsp
            rkl(k) = qr(i-1,k)
            rkr(k) = ql(i  ,k)
            rhol  = rhol  + qr(i-1,k)
            rhor  = rhor  + ql(i  ,k)
            rhoWl = rhoWl + qr(i-1,k)/Wk(k)
            rhoWr = rhoWr + ql(i  ,k)/Wk(k)
         enddo
         do k = 1, Nsp
            Yl(k) = qr(i-1,k)/rhol
            Yr(k) = ql(i  ,k)/rhor
         enddo
         rhoul = qr(i-1,mu)
         rhour = ql(i  ,mu)
         ul = rhoul/rhol
         ur = rhour/rhor
         vl = qr(i-1,mv)/rhol
         vr = ql(i  ,mv)/rhor
c
c        # left/right Temperatures already calculated
c
         rhoel = qr(i-1,mE)-0.5d0*rhol*(ul**2+vl**2)
         call SolveTrhok(qr(i-1,mT),rhoel,rhoWl,rkl,Nsp,ifail) 
         if (ifail.ne.0) write(6,600) i-1,qr(i-1,mT)
         rhoer = ql(i  ,mE)-0.5d0*rhor*(ur**2+vr**2)
         call SolveTrhok(ql(i  ,mT),rhoer,rhoWr,rkr,Nsp,ifail) 
         if (ifail.ne.0) write(6,601) i  ,ql(i  ,mT)
c
         Tl = qr(i-1,mT)
         Tr = ql(i  ,mT)
c
         pl = rhoWl*RU*Tl 
         pr = rhoWr*RU*Tr
         Hl = (qr(i-1,mE)+pl)/rhol
         Hr = (ql(i  ,mE)+pr)/rhor
c
c        # Evaluate temperature depended gamma for left/right mixture
c
         Cpl = avgtabip(Tl,Yl,cpk,Nsp)
         gamma1l = RU / ( rhol/rhoWl*Cpl - RU )
         gammal  = gamma1l + 1.d0
         Cpr = avgtabip(Tr,Yr,cpk,Nsp)
         gamma1r = RU / ( rhor/rhoWr*Cpr - RU )
         gammar  = gamma1r + 1.d0
c
         al2 = gammal*pl/rhol
         al  = dsqrt(al2)
         ar2 = gammar*pr/rhor
         ar  = dsqrt(ar2)
c
         Ml = ul/al
         Mr = ur/ar
c
         el(1) = ul-al
         el(2) = ul
         el(3) = ul+al
         er(1) = ur-ar
         er(2) = ur
         er(3) = ur+ar
c
         if (Ml.gt.1.d0) then
            do k = 1, Nsp
               fvl(k) = Yl(k)*rhoul
            enddo
            fvl(mu) = rhoul*ul+pl
            fvl(mv) = rhoul*vl
            fvl(mE) = rhoul*Hl
         else if (Ml.lt.-1.d0) then
            do m = 1, Nsp+3
               fvl(m) = 0.d0
            enddo
         else
            fl  = 0.25d0*rhol*al*(Ml+1.d0)**2
            fhl = avgtabip(Tl,Yl,hms,Nsp)/al2
            xl  = fhl/(1.d0+2.d0*fhl)
            do k = 1, Nsp
               fvl(k) = fl*Yl(k)
            enddo
            fvl(mu) = fl*(ul-(ul-2.d0*al)/gammal)
            fvl(mv) = fl* vl
            fvl(mE) = fl*(Hl-xl*(ul-al)**2)
         endif
         fvl(mT) = 0.d0
c
         if (Mr.lt.-1.d0) then
            do k = 1, Nsp
               fvr(k) = Yr(k)*rhour
            enddo
            fvr(mu) = rhour*ur+pr
            fvr(mv) = rhour*vr
            fvr(mE) = rhour*Hr
         else if (Mr.gt.1.d0) then
            do m = 1, Nsp+3
               fvr(m) = 0.d0
            enddo
         else
            fr  = -0.25d0*rhor*ar*(Mr-1.d0)**2
            fhr = avgtabip(Tr,Yr,hms,Nsp)/ar2
            xr  = fhr/(1.d0+2.d0*fhr)
            do k = 1, Nsp
               fvr(k) = fr*Yr(k)
            enddo
            fvr(mu) = fr*(ur-(ur+2.d0*ar)/gammar)
            fvr(mv) = fr* vr
            fvr(mE) = fr*(Hr-xr*(ur+ar)**2)
         endif
         fvr(mT) = 0.d0
c
         do 20 m = 1,meqn
            amdq(i,m) = fvl(m) + fvr(m)
            apdq(i,m) = -amdq(i,m)
 20      continue
c
         if (dabs(Ml).lt.1.d0) then
            fl = (gammal+3.d0)/(2.d0*gammal+dabs(Ml)*(3.d0-gammal))
         else
            fl = 1.d0
         endif
         if (dabs(Mr).lt.1.d0) then
            fr = (gammar+3.d0)/(2.d0*gammar+dabs(Mr)*(3.d0-gammar))
         else
            fr = 1.d0
         endif
c
         do 10 mw=1,mwaves
            s(i,mw) = dmax1(dabs(fl*el(mw)),dabs(fr*er(mw)))
            do 10 m=1,meqn
               wave(i,m,mw) = 0.d0
 10   continue
c
 600  format('rpn2eurhok qr(',i2,'): T out of range using: ',f16.8)
 601  format('rpn2eurhok ql(',i2,'): T out of range using: ',f16.8)
      return
      end
c

<