From: ilct <> Date: Tue, 29 Nov 2011 13:01:18 +0000 (+0000) Subject: *** empty log message *** X-Git-Tag: LOGILAB~260 X-Git-Url: http://git.salome-platform.org/gitweb/?a=commitdiff_plain;h=a25cccf1fafb2eb62b41611d09504d0a79292d6f;p=tools%2Feficas.git *** empty log message *** --- diff --git a/Carmel3D/Carmel3D_cata_mat.py b/Carmel3D/Carmel3D_cata_mat.py new file mode 100644 index 00000000..19a13c0f --- /dev/null +++ b/Carmel3D/Carmel3D_cata_mat.py @@ -0,0 +1,613 @@ +# -*- coding: utf-8 -*- + +# -------------------------------------------------- +# -------------------------------------------------- + +import os +import sys +from Accas import * +import types + +# -------------------------------------------------- +# definition d une classe pour les materiaux +# definition d une classe pour les groupes de mailles +# definition d une classe pour les lois non lineaires +# -------------------------------------------------- +class materiau ( ASSD ) : pass +class grmaille ( ASSD ) : pass +class loi ( ASSD ) : pass + +#CONTEXT.debug = 1 +# -------------------------------------------------- +# déclaration du jeu de commandes : 1ere instruction du catalogue obligatoire +#--------------------------------------------------- + +JdC = JDC_CATA ( code = 'CARMEL3D', +# execmodul = None, + regles =( +# AU_MOINS_UN ('MATERIALS'), + AU_MOINS_UN ('SOURCES'), +# A_CLASSER ('MATERIALS','SOURCES'), + ), + ) # Fin JDC_CATA + +# -------------------------------------------------- +# definition de groupe de mailles +# et association du nom du materiau au groupe de mailles +#--------------------------------------------------- + +MESH_GR = OPER (nom = "MESH_GR", + op = None, + repetable = 'n', + UIinfo= {"groupes":("Definition",)}, + fr= "definition du groupe de mailles", + ang = " mesh group definition", + sd_prod= grmaille, + + Material = SIMP (statut="o", + typ=(materiau,), + ang="name of the linked material", + fr ="nom du materiau associe", + ), + ) + + +#========================================================= +# le fichier .PHYS contient 3 blocs et jusqu'a 3 niveaux de sous-blocs +# +#================================ +# 1er bloc : bloc VERSION +# ce bloc est volontairement cache dans l IHM +#================================ + +VERSION = PROC ( nom = "VERSION", + op = None, + repetable = 'n', + UIinfo= {"groupes":("CACHE",)}, + ang= "version block definition", + + + NUM = SIMP (statut="o", + typ="I", + defaut=1, + ang="version number of the physical model", + into=( 1,), + ), + FILETYPE = SIMP (statut="o", + typ="TXM", + defaut="PHYS", + ang="file type", + into=( "PHYS",), + ), + +) # Fin PROC VERSION + +#================================ +# 2eme bloc : bloc MATERIALS +#================================ +# definition de matériau non fictif +#------------------------------------ + +MATERIAU = OPER (nom = "MATERIAU", + op = None, + repetable = 'n', +# UIinfo= {"groupes":("Materials",)}, + ang= "non fictitious material definition", + fr= "definition de materiau non fictif", + sd_prod= materiau, + + ISOTROPIC = SIMP (statut="f", + typ="TXM", + defaut="TRUE", + into = ("TRUE","FALSE"), + ang = "the material is isotropic", + fr = "le materiau est isotrope", + ), + b_ISOTROPIC = BLOC (condition = "ISOTROPIC=='TRUE'", + + HOMOGENEOUS = SIMP (statut="f", + typ="TXM", + defaut="TRUE", + into = ("TRUE","FALSE"), + ang = "the material is homogeneous", + fr = "le materiau est homogene", + ), + b_HOMOGENEOUS = BLOC (condition = "HOMOGENEOUS=='TRUE'", + + +#definition des 3 types de matériaux isotropiques et homogenes +#------------------------------------ +# sous bloc niveau 1 : CONDUCTOR +#------------------------------------ +# + CONDUCTOR = FACT ( statut = "f", + ang= "CONDUCTOR block definition", + fr= "definition du bloc CONDUCTOR", +#------------------------------------------------ +# sous bloc niveau 2 : CONDUCTIVITY +#------------------------------------------------ + CONDUCTIVITY = FACT ( statut="o", + ang ="Conductivity properties", + fr ="proprietes du bloc CONDUCTIVITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT CONDUCTIVITY +#------------------------------------------------ +# sous bloc niveau 2 : PERMEABILITY +#------------------------------------------------ + PERMEABILITY = FACT ( statut="o", + ang ="Permeability properties", + fr ="proprietes du bloc PERMEABILITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMEABILITY + + ), # fin FACT CONDUCTOR + +#------------------------------------ +# sous bloc niveau 1 : DIELECTRIC +#------------------------------------ + DIELECTRIC = FACT (statut="f", + ang= "DIELECTRIC block definition", + fr= "definition du bloc DIELECTRIC", + +#------------------------------------------------ +# sous bloc niveau 2 : PERMITTTIVITY +#------------------------------------------------ + PERMITTIVITY = FACT ( statut="o", + ang ="Permittivity properties", + fr ="proprietes du bloc PERMITTIVITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMITTIVITY + +#------------------------------------------------ +# sous bloc niveau 2 : PERMEABILITY +#------------------------------------------------ + PERMEABILITY = FACT ( statut="o", + ang ="Permeability properties", + fr ="proprietes du bloc PERMEABILITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMEABILITY + + ), # fin FACT DIELECTRIC + + +#------------------------------------ +# sous bloc niveau 1 : ZSURFACIC +#------------------------------------ + ZSURFACIC = FACT (statut="f", + ang= "ZSURFACIC block definition", + fr= "definition du bloc ZSURFACIC", + +#------------------------------------------------ +# sous bloc niveau 2 : CONDUCTIVITY +#------------------------------------------------ + CONDUCTIVITY = FACT ( statut="o", + ang ="Conductivity properties", + fr ="proprietes du bloc CONDUCTIVITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT CONDUCTIVITY +#------------------------------------------------ +# sous bloc niveau 2 : PERMEABILITY +#------------------------------------------------ + PERMEABILITY = FACT ( statut="o", + ang ="Permeability properties", + fr ="proprietes du bloc PERMEABILITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMEABILITY + + ), # fin FACT ZSURFACIC + + ), # fin BLOC homogene + +#============================================ +# 1 type de matériau isotropique non homogene +#---------------------------------------- +# sous bloc niveau 1 : EM_ISOTROPIC_FILES +#---------------------------------------- + b_INHOMOGENEOUS= BLOC (condition='HOMOGENEOUS=="FALSE"', + EM_ISOTROPIC = FACT (statut="f", + ang= "EM_ISOTROPIC block definition", + fr= "definition du bloc EM_ISOTROPIC", + + CONDUCTIVITY_File = SIMP (statut="o", + typ=("Fichier",'MED Files (*.med)',), + ang="CONDUCTIVITY MED data file name", + fr ="nom du fichier MED CONDUCTIVITY", + ), + PERMEABILITY_File = SIMP (statut="o", + typ=("Fichier",'MED Files (*.med)',), + ang="PERMEABILITY MED data file name", + fr ="nom du fichier MED PERMEABILITY", + ), + + ) # fin FACT EM_ISOTROPIC + + ), # fin BLOC inhomogene + + ), # fin BLOC isotropique + +#============================================ +# 1 type de matériau non isotropique +#---------------------------------------- +# sous bloc niveau 1 : EM_ANISOTROPIC_FILES +#---------------------------------------- + b_ANISOTROPIC= BLOC (condition='ISOTROPIC=="FALSE"', + EM_ANISOTROPIC = FACT (statut="f", + ang= "EM_ANISOTROPIC block definition", + fr= "definition du bloc EM_ANISOTROPIC", + + CONDUCTIVITY_File = SIMP (statut="o", + typ=("Fichier",'.mater Files (*.mater)',), + ang="CONDUCTIVITY .mater data file name", + fr ="nom du fichier .mater CONDUCTIVITY", + ), + PERMEABILITY_File = SIMP (statut="o", + typ=("Fichier",'.mater Files (*.mater)',), + ang="PERMEABILITY .mater data file name", + fr ="nom du fichier .mater PERMEABILITY", + ), + ) # fin FACT EM_ANISOTROPIC + ), # fin BLOC anisotropique + + ) # fin OPER materiau +#=================================== +# definition d un type de matériau fictif +#------------------------------------ +# sous bloc niveau 1 : NILMAT +#------------------------------------ + +NILMAT = OPER (nom = "NILMAT", + op = None, + repetable = 'n', + ang= "NILMAT block definition", + fr= "definition du bloc NILMAT", + sd_prod= materiau, + + ) # fin OPER nilmat +#================================ +# 3eme bloc : bloc SOURCES +#================================ + +SOURCES = PROC ( nom = "SOURCES", + op = None, + repetable = 'n', + ang = "sources block definition", + + STRANDED_INDUCTOR = FACT (statut="f", + fr="stranded inductor source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + NTURNS = SIMP (statut="o", + typ="I", + defaut=1, + fr="number of tuns in the inductor", + ), + CURJ = SIMP (statut="o", + typ="R", + defaut=0, + fr="intensity", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT + + EPORT = FACT (statut="f", + fr="eport source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + TYPE = SIMP (statut="o", + typ="TXM", + into=("VOLTAGE","CURRENT"), + fr="type of eport source", + ), + AMP = SIMP (statut="o", + typ="R", + defaut=0, + fr="amplitude", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT eport + + HPORT = FACT (statut="f", + fr="hport source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + TYPE = SIMP (statut="o", + typ="TXM", + into=("VOLTAGE","CURRENT"), + fr="type of hport source", + ), + AMP = SIMP (statut="o", + typ="R", + defaut=0, + fr="amplitude", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT hport + + +) # Fin PROC sources + +#========================================================= +# definition des parametres d une loi avec si besoin la constitution du sous bloc NONLINEAR +# +# produit un objet de la class loi +#------------------------------------------------ +LAW = OPER (nom = "LAW", + op = None, + repetable = 'n', + UIinfo= {"groupes":("Definition",)}, + ang= "NONLINEAR block definition", + fr = "definition des parametres de la loi", + sd_prod= loi, + + LINEAR = SIMP (statut="o", + typ="TXM", + defaut="YES", + into = ("YES","NO"), + ang = "linear law or not", + fr = "loi lineaire ou non", + ), + + NonLinearLaw = BLOC (condition="LINEAR=='NO'", + + NATURE = SIMP (statut="o", + typ="TXM", + defaut="SPLINE", + into=("SPLINE","MARROCCO","MARROCCO+SATURATION"), + ang="nature of the law", + fr ="nature de la loi", + ), + + SplineParam = BLOC (condition="NATURE=='SPLINE'", + + FILENAME = SIMP (statut="o", + typ=("Fichier",'All Files (*)',), + ang="data file name", + fr ="nom du fichier", + ), + APPLIEDTO = SIMP (statut="o", + typ="TXM", + into=("B(H)&H(B)","B(H)","H(B)"), + defaut="B(H)&H(B)", + ang="spline applied to", + fr ="spline appliquee a ", + ), + ), # fin BLOC SplineParam + + MarroccoParam= BLOC (condition="NATURE=='MARROCCO'", + + ALPHA = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="alpha parameter", + fr ="parametre alpha" , + ), + TAU = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="tau parameter", + fr ="parametre tau" , + ), + C = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="c parameter", + fr ="parametre c" , + ), + EPSILON = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="epsilon parameter", + fr ="parametre epsilon" , + ), + ), # fin BLOC MarroccoParam + + MarroSatuParam= BLOC (condition="NATURE=='MARROCCO+SATURATION'", + + ALPHA = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="alpha parameter", + fr ="parametre alpha" , + ), + TAU = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="tau parameter", + fr ="parametre tau" , + ), + C = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="c parameter", + fr ="parametre c" , + ), + EPSILON = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="epsilon parameter", + fr ="parametre epsilon" , + ), + BMAX = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="intersection B", + fr ="intersection B" , + ), + HSAT = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="H value", + fr ="valeur H" , + ), + BSAT = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="B value", + fr ="valeur B" , + ), + JOIN = SIMP (statut="o", + typ="TXM", + defaut="SPLINE", + into= ("SPLINE","PARABOLIC","LINEAR"), + ang="type of join between laws", + fr ="type de jointure entre les 2 lois" , + ), + APPLIEDTO = SIMP (statut="o", + typ="TXM", + into=("B(H)&H(B)","B(H)","H(B)"), + defaut="B(H)&H(B)", + ang="join applied to", + fr ="jointure appliquee a ", + ), + ), # fin BLOC MarroSatuParam + ),# fin BLOC NonLinearLaw + ) # fin OPER diff --git a/Carmel3D/Carmel3D_cata_matloi.py b/Carmel3D/Carmel3D_cata_matloi.py new file mode 100644 index 00000000..48efd0cc --- /dev/null +++ b/Carmel3D/Carmel3D_cata_matloi.py @@ -0,0 +1,625 @@ +# -*- coding: utf-8 -*- + +# -------------------------------------------------- +# -------------------------------------------------- + +import os +import sys +from Accas import * +import types + +# -------------------------------------------------- +# definition d une classe pour les materiaux +# definition d une classe pour les groupes de mailles +# definition d une classe pour les lois non lineaires +# -------------------------------------------------- +class materiau ( ASSD ) : pass +class grmaille ( ASSD ) : pass +class loi ( ASSD ) : pass + +#CONTEXT.debug = 1 +# -------------------------------------------------- +# déclaration du jeu de commandes : 1ere instruction du catalogue obligatoire +#--------------------------------------------------- + +JdC = JDC_CATA ( code = 'CARMEL3D', +# execmodul = None, + regles =( +# AU_MOINS_UN ('MATERIALS'), + AU_MOINS_UN ('SOURCES'), +# A_CLASSER ('MATERIALS','SOURCES'), + ), + ) # Fin JDC_CATA + +#========================================================= +# definition des parametres d une loi avec si besoin la constitution du sous bloc NONLINEAR +# +# produit un objet de la class loi +#------------------------------------------------ +L_LAW = OPER (nom = "L_LAW", + op = None, + repetable = 'n', + UIinfo= {"groupes":("Definition",)}, + ang= "LINEAR block definition", + fr = "definition des parametres de la loi", + sd_prod= loi, + ) + +NL_LAW = OPER (nom = "NL_LAW", + op = None, + repetable = 'n', + UIinfo= {"groupes":("Definition",)}, + ang= "NONLINEAR block definition", + fr = "definition des parametres de la loi", + sd_prod= loi, + + + NATURE = SIMP (statut="o", + typ="TXM", + defaut="SPLINE", + into=("SPLINE","MARROCCO","MARROCCO+SATURATION"), + ang="nature of the law", + fr ="nature de la loi", + ), + + SplineParam = BLOC (condition="NATURE=='SPLINE'", + + FILENAME = SIMP (statut="o", + typ=("Fichier",'All Files (*)',), + ang="data file name", + fr ="nom du fichier", + ), + APPLIEDTO = SIMP (statut="o", + typ="TXM", + into=("B(H)&H(B)","B(H)","H(B)"), + defaut="B(H)&H(B)", + ang="spline applied to", + fr ="spline appliquee a ", + ), + ), # fin BLOC SplineParam + + MarroccoParam= BLOC (condition="NATURE=='MARROCCO'", + + ALPHA = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="alpha parameter", + fr ="parametre alpha" , + ), + TAU = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="tau parameter", + fr ="parametre tau" , + ), + C = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="c parameter", + fr ="parametre c" , + ), + EPSILON = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="epsilon parameter", + fr ="parametre epsilon" , + ), + ), # fin BLOC MarroccoParam + + MarroSatuParam= BLOC (condition="NATURE=='MARROCCO+SATURATION'", + + ALPHA = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="alpha parameter", + fr ="parametre alpha" , + ), + TAU = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="tau parameter", + fr ="parametre tau" , + ), + C = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="c parameter", + fr ="parametre c" , + ), + EPSILON = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="epsilon parameter", + fr ="parametre epsilon" , + ), + BMAX = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="intersection B", + fr ="intersection B" , + ), + HSAT = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="H value", + fr ="valeur H" , + ), + BSAT = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="B value", + fr ="valeur B" , + ), + JOIN = SIMP (statut="o", + typ="TXM", + defaut="SPLINE", + into= ("SPLINE","PARABOLIC","LINEAR"), + ang="type of join between laws", + fr ="type de jointure entre les 2 lois" , + ), + APPLIEDTO = SIMP (statut="o", + typ="TXM", + into=("B(H)&H(B)","B(H)","H(B)"), + defaut="B(H)&H(B)", + ang="join applied to", + fr ="jointure appliquee a ", + ), + ), # fin BLOC MarroSatuParam + ) # fin OPER + + #============================================== + # création d objet de type L_LAW + #---------------------------------- +LINEAR = L_LAW() +# -------------------------------------------------- +# definition de groupe de mailles +# et association du nom du materiau au groupe de mailles +#--------------------------------------------------- + +MESH_GR = OPER (nom = "MESH_GR", + op = None, + repetable = 'n', + UIinfo= {"groupes":("Definition",)}, + fr= "definition du groupe de mailles", + ang = " mesh group definition", + sd_prod= grmaille, + + Material = SIMP (statut="o", + typ=(materiau,), + ang="name of the linked material", + fr ="nom du materiau associe", + ), + ) + + +#========================================================= +# le fichier .PHYS contient 3 blocs et jusqu'a 3 niveaux de sous-blocs +# +#================================ +# 1er bloc : bloc VERSION +# ce bloc est volontairement cache dans l IHM +#================================ + +VERSION = PROC ( nom = "VERSION", + op = None, + repetable = 'n', + UIinfo= {"groupes":("CACHE",)}, + ang= "version block definition", + + + NUM = SIMP (statut="o", + typ="I", + defaut=1, + ang="version number of the physical model", + into=( 1,), + ), + FILETYPE = SIMP (statut="o", + typ="TXM", + defaut="PHYS", + ang="file type", + into=( "PHYS",), + ), + +) # Fin PROC VERSION + +#================================ +# 2eme bloc : bloc MATERIALS +#================================ +# definition de matériau non fictif +#------------------------------------ + +MATERIAU = OPER (nom = "MATERIAU", + op = None, + repetable = 'n', +# UIinfo= {"groupes":("Materials",)}, + ang= "non fictitious material definition", + fr= "definition de materiau non fictif", + sd_prod= materiau, + + ISOTROPIC = SIMP (statut="f", + typ="TXM", + defaut="TRUE", + into = ("TRUE","FALSE"), + ang = "the material is isotropic", + fr = "le materiau est isotrope", + ), + b_ISOTROPIC = BLOC (condition = "ISOTROPIC=='TRUE'", + + HOMOGENEOUS = SIMP (statut="f", + typ="TXM", + defaut="TRUE", + into = ("TRUE","FALSE"), + ang = "the material is homogeneous", + fr = "le materiau est homogene", + ), + b_HOMOGENEOUS = BLOC (condition = "HOMOGENEOUS=='TRUE'", + regles =( AU_MOINS_UN ('CONDUCTOR','DIELECTRIC','ZSURFACIC'), + ), + + +#definition des 3 types de matériaux isotropiques et homogenes +#------------------------------------ +# sous bloc niveau 1 : CONDUCTOR +#------------------------------------ +# + CONDUCTOR = FACT ( statut = "f", + ang= "CONDUCTOR block definition", + fr= "definition du bloc CONDUCTOR", +#------------------------------------------------ +# sous bloc niveau 2 : CONDUCTIVITY +#------------------------------------------------ + CONDUCTIVITY = FACT ( statut="o", + ang ="Conductivity properties", + fr ="proprietes du bloc CONDUCTIVITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + defaut=LINEAR, + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT CONDUCTIVITY +#------------------------------------------------ +# sous bloc niveau 2 : PERMEABILITY +#------------------------------------------------ + PERMEABILITY = FACT ( statut="o", + ang ="Permeability properties", + fr ="proprietes du bloc PERMEABILITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + defaut=LINEAR, + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMEABILITY + + ), # fin FACT CONDUCTOR + +#------------------------------------ +# sous bloc niveau 1 : DIELECTRIC +#------------------------------------ + DIELECTRIC = FACT (statut="f", + ang= "DIELECTRIC block definition", + fr= "definition du bloc DIELECTRIC", + +#------------------------------------------------ +# sous bloc niveau 2 : PERMITTTIVITY +#------------------------------------------------ + PERMITTIVITY = FACT ( statut="o", + ang ="Permittivity properties", + fr ="proprietes du bloc PERMITTIVITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + defaut=LINEAR, + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMITTIVITY + +#------------------------------------------------ +# sous bloc niveau 2 : PERMEABILITY +#------------------------------------------------ + PERMEABILITY = FACT ( statut="o", + ang ="Permeability properties", + fr ="proprietes du bloc PERMEABILITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + defaut=LINEAR, + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMEABILITY + + ), # fin FACT DIELECTRIC + + +#------------------------------------ +# sous bloc niveau 1 : ZSURFACIC +#------------------------------------ + ZSURFACIC = FACT (statut="f", + ang= "ZSURFACIC block definition", + fr= "definition du bloc ZSURFACIC", + +#------------------------------------------------ +# sous bloc niveau 2 : CONDUCTIVITY +#------------------------------------------------ + CONDUCTIVITY = FACT ( statut="o", + ang ="Conductivity properties", + fr ="proprietes du bloc CONDUCTIVITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + defaut=LINEAR, + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT CONDUCTIVITY +#------------------------------------------------ +# sous bloc niveau 2 : PERMEABILITY +#------------------------------------------------ + PERMEABILITY = FACT ( statut="o", + ang ="Permeability properties", + fr ="proprietes du bloc PERMEABILITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ= (loi,), + defaut=LINEAR, + ang = "Choice of law", + fr = "Choix d une loi", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMEABILITY + + ), # fin FACT ZSURFACIC + + ), # fin BLOC homogene + +#============================================ +# 1 type de matériau isotropique non homogene +#---------------------------------------- +# sous bloc niveau 1 : EM_ISOTROPIC_FILES +#---------------------------------------- + b_INHOMOGENEOUS= BLOC (condition='HOMOGENEOUS=="FALSE"', + EM_ISOTROPIC = FACT (statut="f", + ang= "EM_ISOTROPIC block definition", + fr= "definition du bloc EM_ISOTROPIC", + + CONDUCTIVITY_File = SIMP (statut="o", + typ=("Fichier",'MED Files (*.med)',), + ang="CONDUCTIVITY MED data file name", + fr ="nom du fichier MED CONDUCTIVITY", + ), + PERMEABILITY_File = SIMP (statut="o", + typ=("Fichier",'MED Files (*.med)',), + ang="PERMEABILITY MED data file name", + fr ="nom du fichier MED PERMEABILITY", + ), + + ) # fin FACT EM_ISOTROPIC + + ), # fin BLOC inhomogene + + ), # fin BLOC isotropique + +#============================================ +# 1 type de matériau non isotropique +#---------------------------------------- +# sous bloc niveau 1 : EM_ANISOTROPIC_FILES +#---------------------------------------- + b_ANISOTROPIC= BLOC (condition='ISOTROPIC=="FALSE"', + EM_ANISOTROPIC = FACT (statut="f", + ang= "EM_ANISOTROPIC block definition", + fr= "definition du bloc EM_ANISOTROPIC", + + CONDUCTIVITY_File = SIMP (statut="o", + typ=("Fichier",'.mater Files (*.mater)',), + ang="CONDUCTIVITY .mater data file name", + fr ="nom du fichier .mater CONDUCTIVITY", + ), + PERMEABILITY_File = SIMP (statut="o", + typ=("Fichier",'.mater Files (*.mater)',), + ang="PERMEABILITY .mater data file name", + fr ="nom du fichier .mater PERMEABILITY", + ), + ) # fin FACT EM_ANISOTROPIC + ), # fin BLOC anisotropique + + ) # fin OPER materiau +#=================================== +# definition d un type de matériau fictif +#------------------------------------ +# sous bloc niveau 1 : NILMAT +#------------------------------------ + +NILMAT = OPER (nom = "NILMAT", + op = None, + repetable = 'n', + ang= "NILMAT block definition", + fr= "definition du bloc NILMAT", + sd_prod= materiau, + + ) # fin OPER nilmat +#================================ +# 3eme bloc : bloc SOURCES +#================================ + +SOURCES = PROC ( nom = "SOURCES", + op = None, + repetable = 'n', + ang = "sources block definition", + + STRANDED_INDUCTOR = FACT (statut="f", + fr="stranded inductor source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + NTURNS = SIMP (statut="o", + typ="I", + defaut=1, + fr="number of tuns in the inductor", + ), + CURJ = SIMP (statut="o", + typ="R", + defaut=0, + fr="intensity", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT + + EPORT = FACT (statut="f", + fr="eport source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + TYPE = SIMP (statut="o", + typ="TXM", + into=("VOLTAGE","CURRENT"), + fr="type of eport source", + ), + AMP = SIMP (statut="o", + typ="R", + defaut=0, + fr="amplitude", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT eport + + HPORT = FACT (statut="f", + fr="hport source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + TYPE = SIMP (statut="o", + typ="TXM", + into=("VOLTAGE","CURRENT"), + fr="type of hport source", + ), + AMP = SIMP (statut="o", + typ="R", + defaut=0, + fr="amplitude", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT hport + + +) # Fin PROC sources + diff --git a/Carmel3D/Carmel3D_cata_pa.py b/Carmel3D/Carmel3D_cata_pa.py new file mode 100644 index 00000000..35e198dd --- /dev/null +++ b/Carmel3D/Carmel3D_cata_pa.py @@ -0,0 +1,702 @@ +# -*- coding: utf-8 -*- + +# -------------------------------------------------- +# -------------------------------------------------- + +import os +import sys +from Accas import * +import types + +# -------------------------------------------------- +# definition d une classe pour les materiaux +# definition d une classe pour les groupes de mailles +# definition d une classe pour les laws non lineaires +# -------------------------------------------------- +class materiau ( ASSD ) : pass +class grmaille ( ASSD ) : pass +class law ( ASSD ) : pass + + +#CONTEXT.debug = 1 +# -------------------------------------------------- +# déclaration du jeu de commandes : 1ere instruction du catalogue obligatoire +#--------------------------------------------------- + +JdC = JDC_CATA ( code = 'CARMEL3D', +# execmodul = None, + regles =( +# AU_MOINS_UN ('MATERIALS'), +# AU_MOINS_UN ('SOURCES'), +# A_CLASSER ('MATERIALS','SOURCES'), + ), + ) # Fin JDC_CATA +##========================================================= +## definition des parametres d une law +## +## Constitution de sous bloc NONLINEAR +## produit un objet "bloc NONLINEAR" de type (classe) lawNL +##------------------------------------------------ + +L_LAW = OPER (nom = "L_LAW", + op = None, + repetable = 'n', + ang= "", + fr= "", + sd_prod= law, + UIinfo= {"groupes":("CACHE",)}, +) +NL_LAW = OPER (nom = "NL_LAW", + op = None, + repetable = 'n', + ang= "", + fr= "", + sd_prod= law, + + NATURE = SIMP (statut="o", + typ="TXM", + defaut="SPLINE", + into=("SPLINE","MARROCCO","MARROCCO+SATURATION"), + ang="nature of the law", + fr ="nature de la law", + ), + + SplineParam = BLOC (condition="NATURE=='SPLINE'", + + FILENAME = SIMP (statut="o", + typ=("Fichier",'All Files (*)',), + ang="data file name", + fr ="nom du fichier", + ), + APPLIEDTO = SIMP (statut="o", + typ="TXM", + into=("B(H)&H(B)","B(H)","H(B)"), + defaut="B(H)&H(B)", + ang="spline applied to", + fr ="spline appliquee a ", + ), + ), # fin BLOC SplineParam + + MarroccoParam= BLOC (condition="NATURE=='MARROCCO'", + + ALPHA = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="alpha parameter", + fr ="parametre alpha" , + ), + TAU = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="tau parameter", + fr ="parametre tau" , + ), + C = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="c parameter", + fr ="parametre c" , + ), + EPSILON = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="epsilon parameter", + fr ="parametre epsilon" , + ), + ), # fin BLOC MarroccoParam + + MarroSatuParam= BLOC (condition="NATURE=='MARROCCO+SATURATION'", + + ALPHA = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="alpha parameter", + fr ="parametre alpha" , + ), + TAU = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="tau parameter", + fr ="parametre tau" , + ), + C = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="c parameter", + fr ="parametre c" , + ), + EPSILON = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="epsilon parameter", + fr ="parametre epsilon" , + ), + BMAX = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="intersection B", + fr ="intersection B" , + ), + HSAT = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="H value", + fr ="valeur H" , + ), + BSAT = SIMP (statut="o", + typ="R", + defaut=0, + val_min=0, + ang="B value", + fr ="valeur B" , + ), + JOIN = SIMP (statut="o", + typ="TXM", + defaut="SPLINE", + into= ("SPLINE","PARABOLIC","LINEAR"), + ang="type of join between laws", + fr ="type de jointure entre les 2 law" , + ), + APPLIEDTO = SIMP (statut="o", + typ="TXM", + into=("B(H)&H(B)","B(H)","H(B)"), + defaut="B(H)&H(B)", + ang="join applied to", + fr ="jointure appliquee a ", + ), + ), # fin BLOC MarroSatuParam + ) # fin OPER LAW +LINEAR=L_LAW(), + +# -------------------------------------------------- +# definition de groupe de mailles +# et association du nom du materiau au groupe de mailles +#--------------------------------------------------- + +MESH_GROUPE = OPER (nom = "MESH_GROUPE", + op = None, + repetable = 'n', + UIinfo= {"groupes":("Definition",)}, + fr= "definition du groupe de mailles", + ang = " mesh group definition", + sd_prod= grmaille, + + Material = SIMP (statut="f", + typ=(materiau,), + ang="name of the linked material", + fr ="nom du materiau associe", + ), + ) + + +#========================================================= +# le fichier .PHYS contient 3 blocs et jusqu'a 3 niveaux de sous-blocs +# +#================================ +# 1er bloc : bloc VERSION +# ce bloc est volontairement cache dans l IHM +#================================ + +VERSION = PROC ( nom = "VERSION", + op = None, + repetable = 'n', + UIinfo= {"groupes":("CACHE",)}, + ang= "version block definition", + +#---------------------- +# Liste des parametres +#---------------------- + + NUM = SIMP (statut="o", + typ="I", + defaut=1, + ang="version number of the physical model", + into=( 1,), + ), + FILETYPE = SIMP (statut="o", + typ="TXM", + defaut="PHYS", + ang="file type", + into=( "PHYS",), + ), + +) # Fin PROC VERSION + +#================================ +# 2eme bloc : bloc MATERIALS +#================================ +#definition des 3 types de matériaux isotropiques et homogenes +#------------------------------------ +# sous bloc niveau 1 : CONDUCTOR +#------------------------------------ +# +MATERIAU = OPER (nom = "MATERIAU", + op = None, + repetable = 'n', + ang= "CONDUCTOR block definition", + fr= "definition d un materiau", + sd_prod= materiau, + TYPE = SIMP(statut='o',typ='TXM',into=("CONDUCTOR","DIELECTRIC","ZSURFACIC","NILMAT","EM_ISOTROPIC_FILES","EM_ANISOTROPIC_FILES") ), + +#------------------------------------------------ +# sous bloc niveau 2 : CONDUCTIVITY +#------------------------------------------------ + b_conductor=BLOC(condition="TYPE=='CONDUCTOR'", + + CONDUCTIVITY = FACT ( statut="o", + ang ="Conductivity properties", + fr ="proprietes du bloc CONDUCTIVITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ=law, + defaut=LINEAR, + ang = "type of law", + fr = "type de law", + ), + + HOMOGENEOUS = SIMP (statut="o", + typ="TXM", + defaut="TRUE", + into = ("TRUE","FALSE"), + ang = "the material is homogeneous", + fr = "le materiau est homogene", + ), + ISOTROPIC = SIMP (statut="f", + typ="TXM", + defaut="TRUE", + into = ("TRUE","FALSE"), + ang = "the material is isotropic", + fr = "le materiau est isotrope", + ), + + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT CONDUCTIVITY + +#------------------------------------------------ +# sous bloc niveau 2 : PERMEABILITY +#------------------------------------------------ + PERMEABILITY = FACT ( statut="o", + ang ="Permeability properties", + fr ="proprietes du bloc PERMEABILITY", + regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), + ), + + LAW = SIMP (statut="o", + typ=law, + defaut=LINEAR, + ang = "type of law", + ), + HOMOGENEOUS = SIMP (statut="f", + typ="TXM", + defaut="TRUE", + into = ("TRUE","FALSE"), + ang = "the material is homogeneous", + fr = "le materiau est homogene", + ), + ISOTROPIC = SIMP (statut="f", + typ="TXM", + defaut="TRUE", + into = ("TRUE","FALSE"), + ang = "the material is isotropic", + fr = "le materiau est isotrope", + ), + VALUE_REAL = SIMP (statut="f", + typ="R", + ang = "enter a real value", + fr = "entrer un reel", + ), + VALUE_COMPLEX = SIMP (statut="f", + typ="C", + ang = "enter a complex value", + fr = "entrer un complexe", + ), + + ), # fin FACT PERMEABILITY + + + ) # fin BLOC conductor + ) # fin OPER Materiau +# +##------------------------------------ +## sous bloc niveau 1 : DIELECTRIC +##------------------------------------ +#DIELECTRIC = OPER (nom = "DIELECTRIC", +# op = None, +# repetable = 'n', +# UIinfo= {"groupes":("Isotropic Homogeneous Materials",)}, +# ang= "DIELECTRIC block definition", +# fr= "definition du bloc DIELECTRIC", +# sd_prod= materiau, +# +# +##------------------------------------------------ +## sous bloc niveau 2 : PERMITTTIVITY +##------------------------------------------------ +# PERMITTIVITY = FACT ( statut="o", +# ang ="Permittivity properties", +# fr ="proprietes du bloc PERMITTIVITY", +# regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), +# ), +# +# LAW = SIMP (statut="o", +# typ="TXM", +# defaut="LINEAR", +# into = ("LINEAR","NONLINEAR"), +# ang = "type of law", +# ), +# HOMOGENEOUS = SIMP (statut="f", +# typ="TXM", +# defaut="TRUE", +# into = ("TRUE","FALSE"), +# ang = "the material is homogeneous", +# fr = "le materiau est homogene", +# ), +# ISOTROPIC = SIMP (statut="f", +# typ="TXM", +# defaut="TRUE", +# into = ("TRUE","FALSE"), +# ang = "the material is isotropic", +# fr = "le materiau est isotrope", +# ), +# VALUE_REAL = SIMP (statut="f", +# typ="R", +# ang = "enter a real value", +# fr = "entrer un reel", +# ), +# VALUE_COMPLEX = SIMP (statut="o", +# typ="C", +# ang = "enter a complex value", +# fr = "entrer un complexe", +# ), +# +# ), # fin FACT PERMITTIVITY +# +##------------------------------------------------ +## sous bloc niveau 2 : PERMEABILITY +##------------------------------------------------ +# PERMEABILITY = FACT ( statut="o", +# ang ="Permeability properties", +# fr ="proprietes du bloc PERMEABILITY", +# regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), +# ), +# +# LAW = SIMP (statut="o", +# typ="TXM", +# defaut="LINEAR", +# into = ("LINEAR","NONLINEAR"), +# ang = "type of law", +# ), +# HOMOGENEOUS = SIMP (statut="f", +# typ="TXM", +# defaut="TRUE", +# into = ("TRUE","FALSE"), +# ang = "the material is homogeneous", +# fr = "le materiau est homogene", +# ), +# ISOTROPIC = SIMP (statut="f", +# typ="TXM", +# defaut="TRUE", +# into = ("TRUE","FALSE"), +# ang = "the material is isotropic", +# fr = "le materiau est isotrope", +# ), +# VALUE_REAL = SIMP (statut="f", +# typ="R", +# ang = "enter a real value", +# fr = "entrer un reel", +# ), +# VALUE_COMPLEX = SIMP (statut="o", +# typ="C", +# ang = "enter a complex value", +# fr = "entrer un complexe", +# ), +# +# NonLinearCond = BLOC (condition="LAW=='NONLINEAR'", +# NONLINEAR = SIMP (statut="o", +# typ= (law,), +# ang = "enter a complex value", +# fr = "parametres de la law non lineaire", +# ), +# ), +# +# ), # fin FACT PERMEABILITY +# +# +# ) # fin OPER DIELECTRIC +# +# +##------------------------------------ +## sous bloc niveau 1 : ZSURFACIC +##------------------------------------ +#ZSURFACIC = OPER (nom = "ZSURFACIC", +# op = None, +# repetable = 'n', +# UIinfo= {"groupes":("Isotropic Homogeneous Materials",)}, +# ang= "ZSURFACIC block definition", +# fr= "definition du bloc ZSURFACIC", +# sd_prod= materiau, +# +##------------------------------------------------ +## sous bloc niveau 2 : CONDUCTIVITY +##------------------------------------------------ +# CONDUCTIVITY = FACT ( statut="o", +# ang ="Conductivity properties", +# fr ="proprietes du bloc CONDUCTIVITY", +# regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), +# ), +# +# LAW = SIMP (statut="o", +# typ="TXM", +# defaut="LINEAR", +# into = ("LINEAR","NONLINEAR"), +# ang = "type of law", +# fr = "type de law", +# ), +# HOMOGENEOUS = SIMP (statut="f", +# typ="TXM", +# defaut="TRUE", +# into = ("TRUE","FALSE"), +# ang = "the material is homogeneous", +# fr = "le materiau est homogene", +# ), +# ISOTROPIC = SIMP (statut="f", +# typ="TXM", +# defaut="TRUE", +# into = ("TRUE","FALSE"), +# ang = "the material is isotropic", +# fr = "le materiau est isotrope", +# ), +# VALUE_REAL = SIMP (statut="f", +# typ="R", +# ang = "enter a real value", +# fr = "entrer un reel", +# ), +# VALUE_COMPLEX = SIMP (statut="o", +# typ="C", +# ang = "enter a complex value", +# fr = "entrer un complexe", +# ), +# +# +# ), # fin FACT CONDUCTIVITY +# +##------------------------------------------------ +## sous bloc niveau 2 : PERMEABILITY +##------------------------------------------------ +# PERMEABILITY = FACT ( statut="o", +# ang ="Permeability properties", +# fr ="proprietes du bloc PERMEABILITY", +# regles = ( UN_PARMI ('VALUE_REAL','VALUE_COMPLEX'), +# ), +# +# LAW = SIMP (statut="o", +# typ="TXM", +# defaut="LINEAR", +# into = ("LINEAR","NONLINEAR"), +# ang = "type of law", +# fr = "type de law", +# ), +# HOMOGENEOUS = SIMP (statut="f", +# typ="TXM", +# defaut="TRUE", +# into = ("TRUE","FALSE"), +# ang = "the material is homogeneous", +# fr = "le materiau est homogene", +# ), +# ISOTROPIC = SIMP (statut="f", +# typ="TXM", +# defaut="TRUE", +# into = ("TRUE","FALSE"), +# ang = "the material is isotropic", +# fr = "le materiau est isotrope", +# ), +# VALUE_REAL = SIMP (statut="f", +# typ="R", +# ang = "enter a real value", +# fr = "entrer un reel", +# ), +# VALUE_COMPLEX = SIMP (statut="o", +# typ="C", +# ang = "enter a complex value", +# fr = "entrer un complexe", +# ), +# +# ), # fin FACT PERMEABILITY +# +# ) # fin OPER ZSURFACIC +# +# +##=================================== +## definition d un type de matériau fictif +##------------------------------------ +## sous bloc niveau 1 : NILMAT +##------------------------------------ +#NILMAT = OPER (nom = "NILMAT", +# op = None, +# repetable = 'n', +# UIinfo= {"groupes":("Fictitious Materials",)}, +# ang= "NILMAT block definition", +# fr= "definition du bloc NILMAT", +# sd_prod= materiau, +# +# ) # fin OPER NILMAT +# +# +##============================================ +## 1 type de matériau isotropique non homogene +##---------------------------------------- +## sous bloc niveau 1 : EM_ISOTROPIC_FILES +##---------------------------------------- +#EM_ISOTROPIC = PROC (nom = "EM_ISOTROPIC", +# op = None, +# repetable = 'n', +# UIinfo= {"groupes":("Isotropic Inhomogeneous Materials",)}, +# ang= "EM_ISOTROPIC block definition", +# fr= "definition du bloc EM_ISOTROPIC", +# +# CONDUCTIVITY_File = SIMP (statut="o", +# typ=("Fichier",'MED Files (*.med)',), +# ang="CONDUCTIVITY MED data file name", +# fr ="nom du fichier MED CONDUCTIVITY", +# ), +# PERMEABILITY_File = SIMP (statut="o", +# typ=("Fichier",'MED Files (*.med)',), +# ang="PERMEABILITY MED data file name", +# fr ="nom du fichier MED PERMEABILITY", +# ), +# +# ) # fin PROC EM_ISOTROPIC +# +##============================================ +## 1 type de matériau non isotropique +##---------------------------------------- +## sous bloc niveau 1 : EM_ANISOTROPIC_FILES +##---------------------------------------- +#EM_ANISOTROPIC = PROC (nom = "EM_ANISOTROPIC", +# op = None, +# repetable = 'n', +# UIinfo= {"groupes":("Anisotropic Materials",)}, +# ang= "EM_ANISOTROPIC block definition", +# fr= "definition du bloc EM_ANISOTROPIC", +# +# CONDUCTIVITY_File = SIMP (statut="o", +# typ=("Fichier",'.mater Files (*.mater)',), +# ang="CONDUCTIVITY .mater data file name", +# fr ="nom du fichier .mater CONDUCTIVITY", +# ), +# PERMEABILITY_File = SIMP (statut="o", +# typ=("Fichier",'.mater Files (*.mater)',), +# ang="PERMEABILITY .mater data file name", +# fr ="nom du fichier .mater PERMEABILITY", +# ), +# ) # fin PROC EM_ANISOTROPIC +# +#================================ +# 3eme bloc : bloc SOURCES +#================================ + +SOURCES = PROC ( nom = "SOURCES", + op = None, + repetable = 'n', + ang = "sources block definition", + + STRANDED_INDUCTOR = FACT (statut="f", + fr="stranded inductor source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + NTURNS = SIMP (statut="o", + typ="I", + defaut=1, + fr="number of tuns in the inductor", + ), + CURJ = SIMP (statut="o", + typ="R", + defaut=0, + fr="intensity", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT + + EPORT = FACT (statut="f", + fr="eport source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + TYPE = SIMP (statut="o", + typ="TXM", + into=("VOLTAGE","CURRENT"), + fr="type of eport source", + ), + AMP = SIMP (statut="o", + typ="R", + defaut=0, + fr="amplitude", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT eport + + HPORT = FACT (statut="f", + fr="hport source", + + NAME = SIMP (statut="o", + typ="TXM", + fr="name of the source", + ), + TYPE = SIMP (statut="o", + typ="TXM", + into=("VOLTAGE","CURRENT"), + fr="type of hport source", + ), + AMP = SIMP (statut="o", + typ="R", + defaut=0, + fr="amplitude", + ), + POLAR = SIMP (statut="o", + typ="R", + defaut=0, + fr="polarization", + ), + + ), # fin FACT hport + + +) # Fin PROC sources +