src/2d/equations/euler/rp/rpt2eu.f

c
c
c     =====================================================
      subroutine rpt2eu(ixy,maxm,meqn,mwaves,mbc,mx,
     &                  ql,qr,maux,aux1,aux2,aux3,
     &                  ilr,asdq,bmasdq,bpasdq)
c     =====================================================
c
c     # Riemann solver in the transverse direction for the Euler equations.
c     # Split asdq (= A^* \Delta q, where * = + or -)
c     # into down-going flux difference bmasdq (= B^- A^* \Delta q)
c     #    and up-going flux difference bpasdq (= B^+ A^* \Delta q)
c
c     # Uses Roe averages and other quantities which were 
c     # computed in rpn2eu and stored in the common block comroe.
c
c     Author:  Randall J. LeVeque
c
      implicit double precision (a-h,o-z)
      dimension     ql(1-mbc:maxm+mbc, meqn)
      dimension     qr(1-mbc:maxm+mbc, meqn)
      dimension   asdq(1-mbc:maxm+mbc, meqn)
      dimension bmasdq(1-mbc:maxm+mbc, meqn)
      dimension bpasdq(1-mbc:maxm+mbc, meqn)
c
      common /param/  gamma,gamma1
      dimension waveb(4,3),sb(3)
      parameter (maxm2 = 10005)  !# assumes at most 10000x10000 grid with mbc=5
      parameter (minm2 = -4)     !# assumes at most mbc=5
      common /comroe/ u2v2(minm2:maxm2),
     &                u(minm2:maxm2),v(minm2:maxm2),enth(minm2:maxm2),
     &                a(minm2:maxm2),g1a2(minm2:maxm2),euv(minm2:maxm2) 
c
      if (minm2.gt.1-mbc .or. maxm2.lt.maxm+mbc) then
         write(6,*) 'need to increase maxm2 in rpB'
         stop
      endif
c
      if (ixy.eq.1) then
         mu = 2
         mv = 3
      else
         mu = 3
         mv = 2
      endif
c
      do 20 i = 2-mbc, mx+mbc
         a3 = g1a2(i) * (euv(i)*asdq(i,1) 
     &      + u(i)*asdq(i,mu) + v(i)*asdq(i,mv) - asdq(i,4))
         a2 = asdq(i,mu) - u(i)*asdq(i,1)
         a4 = (asdq(i,mv) + (a(i)-v(i))*asdq(i,1) - a(i)*a3)
     &      / (2.d0*a(i))
         a1 = asdq(i,1) - a3 - a4
c
         waveb(1,1) = a1
         waveb(mu,1) = a1*u(i)
         waveb(mv,1) = a1*(v(i)-a(i))
         waveb(4,1) = a1*(enth(i) - v(i)*a(i))
         sb(1) = v(i) - a(i)
c
         waveb(1,2) = a3
         waveb(mu,2) = a3*u(i) + a2
         waveb(mv,2) = a3*v(i)
         waveb(4,2) = a3*0.5d0*u2v2(i) + a2*u(i)
         sb(2) = v(i)
c
         waveb(1,3) = a4
         waveb(mu,3) = a4*u(i)
         waveb(mv,3) = a4*(v(i)+a(i))
         waveb(4,3) = a4*(enth(i)+v(i)*a(i))
         sb(3) = v(i) + a(i)
c
c        # compute the flux differences bmasdq and bpasdq
c
         do 10 m=1,meqn
            bmasdq(i,m) = 0.d0
            bpasdq(i,m) = 0.d0
            do 10 mw=1,mwaves
               bmasdq(i,m) = bmasdq(i,m) 
     &                     + dmin1(sb(mw), 0.d0) * waveb(m,mw)
               bpasdq(i,m) = bpasdq(i,m)
     &                     + dmax1(sb(mw), 0.d0) * waveb(m,mw)
   10    continue
c                 
   20 continue
c
      return
      end

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