en/master/Force__Centrifuge__VDF__Face__Axi_8cpp_source.html

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#include <Force_Centrifuge_VDF_Face_Axi.h>

#include <Domaine_VDF.h>

#include <Domaine_Cl_VDF.h>

#include <Champ_Face_VDF.h>

#include <Neumann_sortie_libre.h>

#include <Dirichlet.h>

#include <Dirichlet_homogene.h>

#include <Symetrie.h>

#include <TRUSTTrav.h>

#include <Equation_base.h>

#include <Milieu_base.h>


Implemente_instanciable(Force_Centrifuge_VDF_Face_Axi,"Force_Centrifuge_VDF_Face_Axi",Source_base);


//// printOn

//


Sortie& Force_Centrifuge_VDF_Face_Axi::printOn(Sortie& s ) const

{

  return s << que_suis_je() ;

}


//// readOn

//


Entree& Force_Centrifuge_VDF_Face_Axi::readOn(Entree& s )

{

  return s ;

}


/////////////////////////////////////////////////////////////////////

//

//                    Implementation des fonctions

//

//               de la classe Force_Centrifuge_VDF_Face_Axi

//

////////////////////////////////////////////////////////////////////


void Force_Centrifuge_VDF_Face_Axi::associer_pb(const Probleme_base& )

{

  Cerr << "Force_Centrifuge_VDF_Face_Axi::associer_pb" << finl;

}


void Force_Centrifuge_VDF_Face_Axi::associer_domaines(const Domaine_dis_base& domaine_dis,

                                                      const Domaine_Cl_dis_base& domaine_Cl_dis)

{

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

  const Domaine_Cl_VDF& zclvdf = ref_cast(Domaine_Cl_VDF, domaine_Cl_dis);

  le_dom_VDF = zvdf;

  le_dom_Cl_VDF = zclvdf;

  elem_faces.ref(zvdf.elem_faces());

  orientation.ref(zvdf.orientation());

  xp.ref(zvdf.xp());

  xv.ref(zvdf.xv());

  volume_entrelaces.ref(zvdf.volumes_entrelaces());

  porosite_surf.ref(le_dom_Cl_VDF->equation().milieu().porosite_face());

}


void Force_Centrifuge_VDF_Face_Axi::ajouter_blocs(matrices_t matrices, DoubleTab& secmem, const tabs_t& semi_impl) const

{

  const Domaine_VDF& zvdf = le_dom_VDF.valeur();

  const Domaine_Cl_VDF& zclvdf = le_dom_Cl_VDF.valeur();

  const DoubleTab& vitesse = la_vitesse->valeurs();


  int nb_elem = zvdf.nb_elem();

  int nb_faces = zvdf.nb_faces();

  DoubleTrav vit_sum(nb_faces);

  vit_sum =0;

  double U,V,coef;

  int fac0,fac1,fac2,fac3;


  // Boucle sur les elements pour calculer vit_sum


  for (int num_elem=0; num_elem<nb_elem; num_elem++)

    {

      fac0 = elem_faces(num_elem,0);

      fac1 = elem_faces(num_elem,1);

      fac2 = elem_faces(num_elem,dimension);

      fac3 = elem_faces(num_elem,1+dimension);


      V = 0.5*(vitesse(fac1)+vitesse(fac3));

      U = 0.5*(vitesse(fac0)+vitesse(fac2));


      vit_sum(fac0) += 0.5*(V*V);

      vit_sum(fac2) += 0.5*(V*V);


      vit_sum(fac1) += 0.5*(U*V);

      vit_sum(fac3) += 0.5*(U*V);

    }


  // Boucle sur les conditions limites pour traiter les faces de bord


  int ndeb,nfin,ori,num_face;


  for (int n_bord=0; n_bord<zvdf.nb_front_Cl(); n_bord++)

    {


      // pour chaque Condition Limite on regarde son type

      // Si face de Dirichlet ou de Symetrie on ne fait rien

      // Si face de Neumann on calcule la contribution au terme source


      const Cond_lim& la_cl = zclvdf.les_conditions_limites(n_bord);


      if (sub_type(Neumann_sortie_libre,la_cl.valeur()))

        {

          const Front_VF& le_bord = ref_cast(Front_VF,la_cl->frontiere_dis());

          ndeb = le_bord.num_premiere_face();

          nfin = ndeb + le_bord.nb_faces();


          for (num_face=ndeb; num_face<nfin; num_face++)

            {

              ori = orientation(num_face);

              if (ori == 0)

                {

                  coef = volume_entrelaces(num_face)*porosite_surf(num_face)/xv(num_face,0);

                  secmem(num_face) += 0.5*(vit_sum(num_face)*coef);

                }

              else if (ori == 1)

                {

                  coef = volume_entrelaces(num_face)*porosite_surf(num_face)/xv(num_face,0);

                  secmem(num_face) -= 0.5*(vit_sum(num_face)*coef);

                }

            }

        }

      else if (sub_type(Symetrie,la_cl.valeur()))

        { /* Do nothing */}

      else if ((sub_type(Dirichlet, la_cl.valeur())) || (sub_type(Dirichlet_homogene, la_cl.valeur())))

        { /* Do nothing */}

    }


  // Boucle sur les faces internes


  ndeb = zvdf.premiere_face_int();

  nfin = zvdf.nb_faces();


  for (num_face=ndeb; num_face<nfin; num_face++)

    {

      ori = orientation(num_face);

      if (ori == 0)

        {

          coef = volume_entrelaces(num_face)*porosite_surf(num_face)/xv(num_face,0);

          secmem(num_face) += 0.5*(vit_sum(num_face)*coef);

        }

      else if (ori == 1)

        {

          coef = volume_entrelaces(num_face)*porosite_surf(num_face)/xv(num_face,0);

          secmem(num_face) -= 0.5*(vit_sum(num_face)*coef);

        }

    }

}


DoubleTab& Force_Centrifuge_VDF_Face_Axi::calculer(DoubleTab& resu) const

{

  resu=0;

  ajouter(resu);

  return resu;

}


void Force_Centrifuge_VDF_Face_Axi::completer()

{

  Source_base::completer();

  la_vitesse = ref_cast(Champ_Face_VDF,equation().inconnue());


}


Champ_Face_VDF
class Champ_Face_VDF Cette classe sert a representer un champ vectoriel dont on ne calcule
Definition Champ_Face_VDF.h:42

Cond_lim
classe Cond_lim Classe generique servant a representer n'importe quelle classe
Definition Cond_lim.h:31

Dirichlet_homogene
Classe Dirichlet_homogene Cette classe est la classe de base de la hierarchie des conditions aux limi...
Definition Dirichlet_homogene.h:31

Dirichlet
classe Dirichlet Cette classe est la classe de base de la hierarchie des conditions aux limites de ty...
Definition Dirichlet.h:31

Domaine_Cl_VDF
class Domaine_Cl_VDF
Definition Domaine_Cl_VDF.h:63

Domaine_Cl_dis_base
classe Domaine_Cl_dis_base Les objets Domaine_Cl_dis_base representent les conditions aux limites
Definition Domaine_Cl_dis_base.h:37

Domaine_Cl_dis_base::les_conditions_limites
const Cond_lim & les_conditions_limites(int) const
Renvoie la i-ieme condition aux limites.
Definition Domaine_Cl_dis_base.cpp:386

Domaine_VDF
class Domaine_VDF
Definition Domaine_VDF.h:64

Domaine_VDF::orientation
int orientation(int) const override
inline DoubleVect& Domaine_VDF::porosite_face() {
Definition Domaine_VDF.h:297

Domaine_VF::nb_faces
int nb_faces() const
renvoie le nombre global de faces.
Definition Domaine_VF.h:471

Domaine_VF::volumes_entrelaces
DoubleVect & volumes_entrelaces()
Definition Domaine_VF.h:99

Domaine_VF::xv
double xv(int num_face, int k) const
Definition Domaine_VF.h:76

Domaine_VF::elem_faces
int elem_faces(int i, int j) const
renvoie le numero de le ieme face de la maille num_elem la facon dont ces faces sont numerotees est
Definition Domaine_VF.h:543

Domaine_VF::xp
double xp(int num_elem, int k) const
Definition Domaine_VF.h:77

Domaine_VF::premiere_face_int
int premiere_face_int() const
une face est interne ssi elle separe deux elements.
Definition Domaine_VF.h:463

Domaine_dis_base
classe Domaine_dis_base Cette classe est la base de la hierarchie des domaines discretisees.
Definition Domaine_dis_base.h:39

Domaine_dis_base::nb_elem
int nb_elem() const
Definition Domaine_dis_base.h:49

Domaine_dis_base::nb_front_Cl
int nb_front_Cl() const
Definition Domaine_dis_base.h:53

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

Force_Centrifuge_VDF_Face_Axi
class Force_Centrifuge_VDF_Face_Axi
Definition Force_Centrifuge_VDF_Face_Axi.h:37

Force_Centrifuge_VDF_Face_Axi::completer
void completer() override
Met a jour les references internes a l'objet Source_base.
Definition Force_Centrifuge_VDF_Face_Axi.cpp:176

Force_Centrifuge_VDF_Face_Axi::associer_domaines
void associer_domaines(const Domaine_dis_base &, const Domaine_Cl_dis_base &) override
Definition Force_Centrifuge_VDF_Face_Axi.cpp:61

Force_Centrifuge_VDF_Face_Axi::xv
DoubleTab xv
Definition Force_Centrifuge_VDF_Face_Axi.h:61

Force_Centrifuge_VDF_Face_Axi::volume_entrelaces
DoubleVect volume_entrelaces
Definition Force_Centrifuge_VDF_Face_Axi.h:62

Force_Centrifuge_VDF_Face_Axi::associer_pb
void associer_pb(const Probleme_base &) override
Definition Force_Centrifuge_VDF_Face_Axi.cpp:56

Force_Centrifuge_VDF_Face_Axi::porosite_surf
DoubleVect porosite_surf
Definition Force_Centrifuge_VDF_Face_Axi.h:63

Force_Centrifuge_VDF_Face_Axi::xp
DoubleTab xp
Definition Force_Centrifuge_VDF_Face_Axi.h:60

Force_Centrifuge_VDF_Face_Axi::orientation
IntVect orientation
Definition Force_Centrifuge_VDF_Face_Axi.h:59

Force_Centrifuge_VDF_Face_Axi::elem_faces
IntTab elem_faces
Definition Force_Centrifuge_VDF_Face_Axi.h:58

Force_Centrifuge_VDF_Face_Axi::ajouter_blocs
void ajouter_blocs(matrices_t matrices, DoubleTab &secmem, const tabs_t &semi_impl) const override
Definition Force_Centrifuge_VDF_Face_Axi.cpp:76

Force_Centrifuge_VDF_Face_Axi::calculer
DoubleTab & calculer(DoubleTab &) const override
Definition Force_Centrifuge_VDF_Face_Axi.cpp:169

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

MorEqn::equation
const Equation_base & equation() const
Renvoie la reference sur l'equation pointe par MorEqn::mon_equation.
Definition MorEqn.h:62

Neumann_sortie_libre
classe Neumann_sortie_libre Cette classe represente une frontiere ouverte sans vitesse imposee
Definition Neumann_sortie_libre.h:34

Objet_U::dimension
static int dimension
Definition Objet_U.h:99

Objet_U::que_suis_je
const Nom & que_suis_je() const
renvoie la chaine identifiant la classe.
Definition Objet_U.cpp:104

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

Probleme_base
classe Probleme_base C'est un Probleme_U qui n'est pas un couplage.
Definition Probleme_base.h:55

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

Source_base
classe Source_base Un objet Source_base est un terme apparaissant au second membre d'une
Definition Source_base.h:42

Source_base::completer
virtual void completer()
Met a jour les references internes a l'objet Source_base.
Definition Source_base.cpp:88

Source_base::ajouter
virtual DoubleTab & ajouter(DoubleTab &) const
Definition Source_base.cpp:225

Symetrie
classe Symetrie Sur les faces de symetrie on a les proprietes suivantes:
Definition Symetrie.h:37