en/master/Neumann__paroi__rayo__semi__transp__VDF_8cpp_source.html

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#include <Neumann_paroi_rayo_semi_transp_VDF.h>

#include <Pb_rayo_semi_transp.h>

#include <Fluide_Incompressible.h>

#include <Champ_front_uniforme.h>

#include <Schema_Temps_base.h>

#include <Champ_Uniforme.h>

#include <communications.h>

#include <Domaine_VDF.h>


Implemente_instanciable(Neumann_paroi_rayo_semi_transp_VDF, "Paroi_flux_impose_rayo_semi_transp_VDF", Neumann_paroi);


Sortie& Neumann_paroi_rayo_semi_transp_VDF::printOn(Sortie& os) const

{

  return os;

}


Entree& Neumann_paroi_rayo_semi_transp_VDF::readOn(Entree& is)

{

  is >> le_champ_front;

  return is;

}


double Neumann_paroi_rayo_semi_transp_VDF::flux_impose(int i) const

{

  const Domaine_VDF& zvdf = ref_cast(Domaine_VDF, domaine_Cl_dis().domaine_dis());

  const IntTab& face_voisins = zvdf.face_voisins();

  const Front_VF& front_vf = ref_cast(Front_VF, frontiere_dis());

  int ndeb = front_vf.num_premiere_face();


  int elem = face_voisins(ndeb + i, 0);

  if (elem == -1)

    elem = face_voisins(ndeb + i, 1);


  double signe = 1;

  const DoubleTab& flux_radiatif = pb_rayo_semi_transp().flux_radiatif(frontiere_dis().le_nom()).valeurs();


  if (le_champ_front->valeurs().size() == 1)

    return signe * le_champ_front->valeurs()(0, 0) - flux_radiatif(i, 0);

  else if (le_champ_front->valeurs().dimension(1) == 1)

    return signe * (le_champ_front->valeurs()(i, 0) - flux_radiatif(i, 0));

  else

    Cerr << "Neumann_paroi_rayo_semi_transp_VDF::flux_impose erreur" << finl;


  return 0;

}


double Neumann_paroi_rayo_semi_transp_VDF::flux_impose(int i, int j) const

{

  const Domaine_VDF& zvdf = ref_cast(Domaine_VDF, domaine_Cl_dis().domaine_dis());

  const IntTab& face_voisins = zvdf.face_voisins();

  const Front_VF& front_vf = ref_cast(Front_VF, frontiere_dis());

  int ndeb = front_vf.num_premiere_face();


  int elem = face_voisins(ndeb + i, 0);

  if (elem == -1)

    elem = face_voisins(ndeb + i, 1);


  const DoubleTab& flux_radiatif = pb_rayo_semi_transp().flux_radiatif(frontiere_dis().le_nom()).valeurs();


  if (le_champ_front->valeurs().dimension(0) == 1)

    return le_champ_front->valeurs()(0, j) - flux_radiatif(i);

  else

    return le_champ_front->valeurs()(i, j) - flux_radiatif(i);

}


const Cond_lim_base& Neumann_paroi_rayo_semi_transp_VDF::la_cl() const

{

  return (*this);

}


void Neumann_paroi_rayo_semi_transp_VDF::calculer_temperature_bord(double temps)

{

  const Domaine_VDF& zvdf = ref_cast(Domaine_VDF, domaine_Cl_dis().domaine_dis());

  const IntTab& face_voisins = zvdf.face_voisins();

  const Milieu_base& le_milieu = mon_dom_cl_dis->equation().milieu();

  ////const Champ_Uniforme& Lambda = ref_cast(Champ_Uniforme,le_milieu.conductivite());

  const Front_VF& front_vf = ref_cast(Front_VF, frontiere_dis());

  int nb_faces = front_vf.nb_faces();

  int ndeb = front_vf.num_premiere_face();

  const DoubleTab& rho = le_milieu.masse_volumique().valeurs();

  const DoubleTab& Cp = le_milieu.capacite_calorifique().valeurs();

  const DoubleTab& Lambda = le_milieu.conductivite().valeurs();


  assert(le_milieu.capacite_calorifique().nb_comp() == 1);

  assert(le_milieu.masse_volumique().nb_comp() == 1);

  double d_Cp, d_rho, d_Lambda;

  if (Cp.get_md_vector() || rho.get_md_vector() || Lambda.get_md_vector())

    {

      // L'un des champs n'est pas uniforme

      ArrOfDouble tmp(3);

      tmp[0] = local_max_vect(Cp);

      tmp[1] = local_max_vect(rho);

      tmp[2] = local_max_vect(Lambda);

      mp_max_for_each_item(tmp);

      d_Cp = tmp[0];

      d_rho = tmp[1];

      d_Lambda = tmp[2];

    }

  else

    {

      // Tous les champs sont uniforme. Raccourci car mp_max penalisant

      d_Cp = Cp(0, 0);

      d_rho = rho(0, 0);

      d_Lambda = Lambda(0, 0);

    }


  Schema_Temps_base& sch = mon_dom_cl_dis->equation().probleme().schema_temps();

  double dt = sch.pas_de_temps();


  //  Cerr<<"Nom du bord : "<<front_vf.le_nom()<<finl;

  ////double d_Lambda = Lambda(0,0);


  const DoubleTab& T_f = mon_dom_cl_dis->equation().inconnue().valeurs();

  DoubleTab& T_b = temperature_bord_->valeurs_au_temps(temps);


  const DoubleTab& flux_radiatif = pb_rayo_semi_transp().flux_radiatif(frontiere_dis().le_nom()).valeurs();


  int face = 0;

  int num_face;

  for (face = 0; face < nb_faces; face++)

    {

      num_face = face + ndeb;

      double eF = zvdf.dist_norm_bord(num_face);

      int elem = face_voisins(num_face, 0);

      if (elem < 0)

        elem = face_voisins(num_face, 1);

      // Pour eviter division par 0 au 1er pas de temps:

      // double omega=1./(1.+eF*eF*d_rho*d_Cp/d_Lambda/dt);

      double omega = d_Lambda * dt / (d_Lambda * dt + eF * eF * d_rho * d_Cp);

      //      Cerr << "omega=" << omega << finl;

      if (sub_type(Champ_front_uniforme, le_champ_front.valeur()))

        {

          T_b(face, 0) = omega * (T_f(elem) + (le_champ_front->valeurs()(0, 0) - flux_radiatif(face, 0)) / (d_Lambda / eF)) + (1 - omega) * T_b(face, 0);

        }

      else

        T_b(face, 0) = omega * (T_f(elem) + (le_champ_front->valeurs()(face, 0) - flux_radiatif(face, 0)) / (d_Lambda / eF)) + (1 - omega) * T_b(face, 0);

    }

}


int Neumann_paroi_rayo_semi_transp_VDF::compatible_avec_eqn(const Equation_base& eqn) const

{

  Motcle dom_app = eqn.domaine_application();

  Motcle Thermique = "Thermique";

  Motcle indetermine = "indetermine";

  if ((dom_app == Thermique) || (dom_app == indetermine))

    return 1;

  else

    {

      err_pas_compatible(eqn);

      return 0;

    }

}


void Neumann_paroi_rayo_semi_transp_VDF::completer()

{

  Neumann_paroi::completer();


  // On type et on dimmensionne le champ_front temperature_bord_

  //  const Milieu_base& mil=mon_dom_cl_dis->equation().milieu();

  const Front_VF& front_vf = ref_cast(Front_VF, frontiere_dis());

  int nb_comp = 1;

  temperature_bord_.typer("Champ_front_fonc");

  temperature_bord_->fixer_nb_comp(nb_comp);

  DoubleTab& tab = temperature_bord_->valeurs();

  tab.resize(front_vf.nb_faces(), nb_comp);


  // On initialise le tableau des temperatures de bord egale a la

  // temperature initiale du milieu courant

  const Domaine_VDF& zvdf = ref_cast(Domaine_VDF, domaine_Cl_dis().domaine_dis());

  int ndeb = front_vf.num_premiere_face();

  const IntTab& face_voisins = zvdf.face_voisins();

  const DoubleTab& T = mon_dom_cl_dis->equation().inconnue().valeurs();

  int face = 0;

  //

  // Debut de la boucle sur les faces de bord

  //


  for (face = 0; face < front_vf.nb_faces(); face++)

    {

      int elem = face_voisins(face + ndeb, 0);

      if (elem < 0)

        elem = face_voisins(face + ndeb, 1);

      tab(face, 0) = T(elem);

    }

}


Champ_Don_base::valeurs
DoubleTab & valeurs() override
Surcharge Champ_base::valeurs() Renvoie le tableau des valeurs.
Definition Champ_Don_base.h:49

Champ_Proto::valeurs
virtual DoubleTab & valeurs()=0

Champ_front_base::valeurs
virtual DoubleTab & valeurs() override
Renvoie le tableau des valeurs du champ.
Definition Champ_front_base.h:148

Champ_front_uniforme
classe Champ_front_uniforme Classe derivee de Champ_front_base qui represente les
Definition Champ_front_uniforme.h:32

Cond_lim_base
classe Cond_lim_base Classe de base pour la hierarchie des classes qui representent les differentes c...
Definition Cond_lim_base.h:40

Cond_lim_base::err_pas_compatible
void err_pas_compatible(const Equation_base &) const
Cette methode est appelee quand la condition aux limites n'est pas compatible avec l'equation sur laq...
Definition Cond_lim_base.cpp:200

Cond_lim_base::domaine_Cl_dis
Domaine_Cl_dis_base & domaine_Cl_dis()
Renvoie le domaine des conditions aux limites discretisee dont l'objet fait partie.
Definition Cond_lim_base.h:121

Cond_lim_base::completer
virtual void completer()
NE FAIT RIEN A surcharger dans les classes derivees.
Definition Cond_lim_base.cpp:31

Cond_lim_base::frontiere_dis
virtual Frontiere_dis_base & frontiere_dis()
Renvoie la frontiere discretisee a laquelle les conditions aux limites s'appliquent.
Definition Cond_lim_base.h:101

Cond_lim_rayo_semi_transp::pb_rayo_semi_transp
const Pb_rayo_semi_transp & pb_rayo_semi_transp() const
Definition Cond_lim_rayo_semi_transp.h:35

Domaine_VDF
class Domaine_VDF
Definition Domaine_VDF.h:64

Domaine_VDF::dist_norm_bord
double dist_norm_bord(int num_face) const override
Definition Domaine_VDF.h:382

Domaine_VF::face_voisins
int face_voisins(int num_face, int i) const
renvoie l'element voisin de numface dans la direction i.
Definition Domaine_VF.h:418

Entree
Class defining operators and methods for all reading operation in an input flow (file,...
Definition Entree.h:42

Equation_base
classe Equation_base Le role d'une equation est le calcul d'un ou plusieurs champs....
Definition Equation_base.h:76

Equation_base::milieu
virtual const Milieu_base & milieu() const =0

Equation_base::domaine_application
virtual const Motcle & domaine_application() const
Renvoie "indetermine" Navier_Stokes_standard par exemple surcharge cette methode.
Definition Equation_base.cpp:1373

Field_base::nb_comp
virtual int nb_comp() const
Definition Field_base.h:56

Front_VF
class Front_VF
Definition Front_VF.h:36

Front_VF::nb_faces
int nb_faces() const
Definition Front_VF.h:53

Front_VF::num_premiere_face
int num_premiere_face() const
Definition Front_VF.h:63

Milieu_base
classe Milieu_base Cette classe est la base de la hierarchie des milieux (physiques)
Definition Milieu_base.h:50

Milieu_base::equation
virtual const Equation_base & equation(const std::string &nom_inc) const
Definition Milieu_base.cpp:958

Milieu_base::capacite_calorifique
virtual const Champ_Don_base & capacite_calorifique() const
Renvoie la capacite calorifique du milieu.
Definition Milieu_base.cpp:867

Milieu_base::conductivite
virtual const Champ_Don_base & conductivite() const
Renvoie la conductivite du milieu.
Definition Milieu_base.cpp:847

Milieu_base::masse_volumique
virtual const Champ_base & masse_volumique() const
Renvoie la masse volumique du milieu.
Definition Milieu_base.cpp:797

Motcle
Une chaine de caractere (Nom) en majuscules.
Definition Motcle.h:26

Neumann_paroi_rayo_semi_transp_VDF
Definition Neumann_paroi_rayo_semi_transp_VDF.h:23

Neumann_paroi_rayo_semi_transp_VDF::completer
void completer() override
NE FAIT RIEN A surcharger dans les classes derivees.
Definition Neumann_paroi_rayo_semi_transp_VDF.cpp:169

Neumann_paroi_rayo_semi_transp_VDF::flux_impose
double flux_impose(int i) const override
Renvoie la valeur du flux impose sur la i-eme composante du champ representant le flux a la frontiere...
Definition Neumann_paroi_rayo_semi_transp_VDF.cpp:38

Neumann_paroi_rayo_semi_transp_VDF::compatible_avec_eqn
int compatible_avec_eqn(const Equation_base &) const override
Definition Neumann_paroi_rayo_semi_transp_VDF.cpp:155

Neumann_paroi_rayo_semi_transp_VDF::calculer_temperature_bord
void calculer_temperature_bord(double temps)
Definition Neumann_paroi_rayo_semi_transp_VDF.cpp:86

Neumann_paroi_rayo_semi_transp_VDF::la_cl
const Cond_lim_base & la_cl() const override
Definition Neumann_paroi_rayo_semi_transp_VDF.cpp:81

Neumann_paroi
Classe Neumann_paroi Cette condition limite correspond a un flux impose pour l'equation de.
Definition Neumann_paroi.h:29

Objet_U::readOn
virtual Entree & readOn(Entree &)
Lecture d'un Objet_U sur un flot d'entree Methode a surcharger.
Definition Objet_U.cpp:293

Objet_U::le_nom
virtual const Nom & le_nom() const
Donne le nom de l'Objet_U Methode a surcharger : renvoie "neant" dans cette implementation.
Definition Objet_U.cpp:319

Objet_U::printOn
virtual Sortie & printOn(Sortie &) const
Ecriture de l'objet sur un flot de sortie Methode a surcharger.
Definition Objet_U.cpp:282

Pb_rayo_semi_transp::flux_radiatif
const Champ_front_base & flux_radiatif(const Nom &nom_bord) const
Definition Pb_rayo_semi_transp.cpp:189

Process::mp_max_for_each_item
static void mp_max_for_each_item(TRUSTArray< _TYPE_ > &x, int n=-1)
Definition Process.cpp:196

Schema_Temps_base
class Schema_Temps_base
Definition Schema_Temps_base.h:67

Schema_Temps_base::pas_de_temps
double pas_de_temps() const
Renvoie le pas de temps (delta_t) courant.
Definition Schema_Temps_base.h:393

Sortie
Classe de base des flux de sortie.
Definition Sortie.h:52

TRUSTTab::resize
void resize(_SIZE_ n, RESIZE_OPTIONS opt=RESIZE_OPTIONS::COPY_INIT)
Definition TRUSTTab.tpp:469

TRUSTVect::get_md_vector
virtual const MD_Vector & get_md_vector() const
Definition TRUSTVect.h:123