Exemple #1
0
/* ********************************************************************* */
double CompEquil (double N, double T, double *v0)
/*!
 *  Compute the equilibrium ionization balance for (rho,T)
 *
 *
 *********************************************************************** */
{
    int nlev, ind_start, i,j, k, nv, nrt;
    double d, n_el, n_el_old, sT;
    double v[NVAR];
    static double **M;
    static double *rhs;
    static int *p;

    /* ----  start index in the ions matrix for each element ---- */

    int ind_starts[] = {X_HI, X_HeI, X_CI, X_NI, X_OI, X_NeI, X_SI, X_SI+S_IONS};

    /* ----  number of ions for each element  ---- */

    int nlevs[]      = {1, 2, C_IONS, N_IONS, O_IONS, Ne_IONS, S_IONS, Fe_IONS};

    /* -- Copy solution vector before any modification -- */

    VAR_LOOP(nv) v[nv] = v0[nv];

    sT = sqrt(T);
    /*   N  = find_N(rho);   -- Total number density -- */

    if (M == NULL) {     /* -- Allocate matrices for the linear eq system -- */
        M   = ARRAY_2D(MAX_NLEVEL, MAX_NLEVEL, double);
        rhs = ARRAY_1D(MAX_NLEVEL, double);
        p   = ARRAY_1D(MAX_NLEVEL, int);
    }
Exemple #2
0
/* ********************************************************************* */
void EntropyOhmicHeating (const Data *d, Data_Arr UU, double dt, Grid *grid)
/*! 
 * Add Ohmic heating term to the conservative entropy equation when
 * RESISTIVITY is set to YES.
 *
 * \return  This function has no return value.
 *********************************************************************** */
{
#if PHYSICS == MHD && (RESISTIVITY == EXPLICIT) /* at the moment ... remove later ! */
  int    i,j,k,nv;
  double rho, rhog, gm1, vc[NVAR];
  double Jc[3], eta[3], J2eta;
  double ***Jx1, *x1, *dx1;
  double ***Jx2, *x2, *dx2;
  double ***Jx3, *x3, *dx3;
  Data_Arr V;

/* ---------------------------------------------
   1. Set pointer shortcuts 
   --------------------------------------------- */
  
  V   = d->Vc;
  Jx1 = d->J[IDIR]; x1 = grid[IDIR].x ; dx1 = grid[IDIR].dx;
  Jx2 = d->J[JDIR]; x2 = grid[JDIR].x ; dx2 = grid[JDIR].dx;
  Jx3 = d->J[KDIR]; x3 = grid[KDIR].x ; dx3 = grid[KDIR].dx;

  gm1 = g_gamma - 1.0;
  Jc[IDIR] = Jc[JDIR] = Jc[KDIR] = 0.0;
  
/* ---------------------------------------------
   2. Main spatial loop
   --------------------------------------------- */
  
  DOM_LOOP(k,j,i){

  /* ---------------------------------
     2a. compute currents at cell center
     --------------------------------- */

    #ifdef STAGGERED_MHD  /* Staggered MHD */

     #if COMPONENTS == 3
      Jc[IDIR] = AVERAGE_YZ(Jx1,k-1,j-1,i);
      Jc[JDIR] = AVERAGE_XZ(Jx2,k-1,j,i-1);
     #endif
     Jc[KDIR] = AVERAGE_XY(Jx3,k,j-1,i-1);

    #else               /* Cell-centered MHD */

     #if COMPONENTS == 3
      Jc[IDIR] = CDIFF_X2(V[BX3],k,j,i)/dx2[j] - CDIFF_X3(V[BX2],k,j,i)/dx3[k];
      Jc[JDIR] = CDIFF_X3(V[BX1],k,j,i)/dx3[k] - CDIFF_X1(V[BX3],k,j,i)/dx1[i];
     #endif
     Jc[KDIR] = CDIFF_X1(V[BX2],k,j,i)/dx1[i] - CDIFF_X2(V[BX1],k,j,i)/dx2[j];

     #if GEOMETRY != CARTESIAN
      print1 ("! EntropyOhmicHeating: only CT supported in this geometry.\n")
      QUIT_PLUTO(1);
     #endif

    #endif

  /* ----------------------------------------
     2b. compute resistivity at cell center.
     ---------------------------------------- */

    VAR_LOOP(nv) vc[nv] = V[nv][k][j][i];
    rho  = vc[RHO];
    rhog = pow(rho,-gm1);

    Resistive_eta (vc, x1[i], x2[j], x3[k], Jc, eta);
    J2eta = 0.0;
    for (nv = 0; nv < 3; nv++) J2eta += Jc[nv]*Jc[nv]*eta[nv];

  /* ----------------------------------------
     2c. Update conserved entropy
     ---------------------------------------- */
     
    UU[k][j][i][ENTR] += dt*rhog*gm1*J2eta;
  }
Exemple #3
0
/* ********************************************************************** */
void States (const State_1D *state, int beg, int end, Grid *grid)
/*!
 * 
 * \param [in]      state pointer to State_1D structure
 * \param [in]      beg   initial index of computation
 * \param [in]      end   final   index of computation
 * \param [in]      grid  pointer to an array of Grid structures
 *
 ************************************************************************ */
{
  int   i, nv;
  double dv, **v;
  double dvp, cp, *wp, *hp, **vp;
  double dvm, cm, *wm, *hm, **vm;
  PPM_Coeffs ppm_coeffs;
  PLM_Coeffs plm_coeffs;
  
/* ---------------------------------------------------------
   1. Set pointers, compute geometrical coefficients
   --------------------------------------------------------- */

  v  = state->v;
  vm = state->vm;
  vp = state->vp;

  PPM_CoefficientsGet(&ppm_coeffs, g_dir);
  #if SHOCK_FLATTENING == MULTID
   PLM_CoefficientsGet(&plm_coeffs, g_dir);
  #endif

  hp = ppm_coeffs.hp;
  hm = ppm_coeffs.hm;

/* ---------------------------------------------------------
   2. Define unlimited left and right interface values and
      make sure they lie between adjacent cell averages.
   --------------------------------------------------------- */

  #if PPM_VERSION == PPM3 || PPM_VERSION == PPM5
   for (i = beg; i <= end; i++) {
     wp = ppm_coeffs.wp[i];
     wm = ppm_coeffs.wm[i];
     VAR_LOOP(nv){
       #if PPM_VERSION == PPM3
        vp[i][nv] = wp[-1]*v[i-1][nv] + wp[0]*v[i][nv] + wp[1]*v[i+1][nv];
        vm[i][nv] = wm[-1]*v[i-1][nv] + wm[0]*v[i][nv] + wm[1]*v[i+1][nv];
       #elif PPM_VERSION == PPM5
        vp[i][nv] = wp[-2]*v[i-2][nv] + wp[-1]*v[i-1][nv] +  
                    wp[ 0]*v[i][nv]   + wp[ 1]*v[i+1][nv] + wp[ 2]*v[i+2][nv]; 

        vm[i][nv] =  wm[-2]*v[i-2][nv] + wm[-1]*v[i-1][nv] + wm[0]*v[i][nv]
                   + wm[ 1]*v[i+1][nv] + wm[ 2]*v[i+2][nv];
       #endif
       dvp = vp[i][nv] - v[i][nv];
       dvm = vm[i][nv] - v[i][nv];

       dv  = v[i+1][nv] - v[i][nv];
       vp[i][nv] = v[i][nv] + MINMOD(dvp, dv);

       dv  = v[i][nv] - v[i-1][nv];
       vm[i][nv] = v[i][nv] + MINMOD(dvm, -dv);
     }
   }
  #elif PPM_VERSION == PPM4  /* -- set a unique interface value -- */
   for (i = beg-1; i <= end; i++) {
     wp = ppm_coeffs.wp[i];
     VAR_LOOP(nv){
       vp[i][nv] =  wp[-1]*v[i-1][nv] + wp[0]*v[i][nv]
                  + wp[ 1]*v[i+1][nv] + wp[2]*v[i+2][nv];

       dv  = v[i+1][nv] - v[i][nv];
       dvp = vp[i][nv] - v[i][nv];
       vp[i][nv] = v[i][nv] + MINMOD(dvp, dv);
     }
   }
   for (i = beg; i <= end; i++) VAR_LOOP(nv) vm[i][nv] = vp[i-1][nv];
  #endif

/* ---------------------------------------------------------
   3. Apply parabolic limiter: no new extrema should appear
      in the parabola defined by vp, vm and v.
   --------------------------------------------------------- */

  for (i = beg; i <= end; i++) {
    #if SHOCK_FLATTENING == MULTID    
     if (CheckZone (i, FLAG_MINMOD)) {
       wp = plm_coeffs.wp;
       wm = plm_coeffs.wm;
       VAR_LOOP(nv) {
         dvp = (v[i+1][nv] - v[i][nv])*wp[i];
         dvm = (v[i][nv] - v[i-1][nv])*wm[i];
         dv  = MINMOD(dvp, dvm);
         vp[i][nv] = v[i][nv] + dv*plm_coeffs.dp[i];
         vm[i][nv] = v[i][nv] - dv*plm_coeffs.dm[i];
       }
       #if PHYSICS == RHD || PHYSICS == RMHD
        VelocityLimiter (v[i], vp[i], vm[i]);
       #endif
       continue;
     }
    #endif

    #if PPM_VERSION == PPM0
     cm = cp = 2.0;
    #else
     cm = (hm[i] + 1.0)/(hp[i] - 1.0);
     cp = (hp[i] + 1.0)/(hm[i] - 1.0);
    #endif

    for (nv = 0; nv < NVAR; nv++){
      dvp = vp[i][nv] - v[i][nv];
      dvm = vm[i][nv] - v[i][nv];

      if (dvp*dvm >= 0.0) dvp = dvm = 0.0;
      else{
        if      (fabs(dvp) >= cm*fabs(dvm)) dvp = -cm*dvm;
        else if (fabs(dvm) >= cp*fabs(dvp)) dvm = -cp*dvp;
      }
      vp[i][nv] = v[i][nv] + dvp; 
      vm[i][nv] = v[i][nv] + dvm;
    }
    #if PHYSICS == RHD || PHYSICS == RMHD
     VelocityLimiter (v[i], vp[i], vm[i]);
    #endif
  }

/* --------------------------------------------------------
          1D shock flattening
   -------------------------------------------------------- */

  #if SHOCK_FLATTENING == YES
   Flatten (state, beg, end, grid);
  #endif

/*  -------------------------------------------
      Assign face-centered magnetic field
    -------------------------------------------  */

  #ifdef STAGGERED_MHD
   for (i = beg-1; i <= end; i++) {
     state->vR[i][BXn] = state->vL[i][BXn] = state->bn[i];
   }
  #endif

  #if TIME_STEPPING == CHARACTERISTIC_TRACING
   CharTracingStep(state, beg, end, grid);
  #endif

/* -------------------------------------------
    compute states in conservative variables
   ------------------------------------------- */

  PrimToCons (state->vp, state->up, beg, end);
  PrimToCons (state->vm, state->um, beg, end);
}