From: Pascale Noyret Date: Fri, 28 Nov 2008 09:26:56 +0000 (+0000) Subject: *** empty log message *** X-Git-Tag: V0_a1_SEPQT4~59 X-Git-Url: http://git.salome-platform.org/gitweb/?a=commitdiff_plain;h=c6f8ec6a2ae0fa3f7fcb0a761204719ebd497d60;p=tools%2Feficas.git *** empty log message *** --- diff --git a/Openturns_Study/OpenTURNS_Cata_Study_V2.py b/Openturns_Study/OpenTURNS_Cata_Study_V2.py new file mode 100644 index 00000000..58128f14 --- /dev/null +++ b/Openturns_Study/OpenTURNS_Cata_Study_V2.py @@ -0,0 +1,1486 @@ +# -*- coding: utf-8 -*- + +# -------------------------------------------------- +# debut entete +# -------------------------------------------------- + +import Accas +from Accas import * + +class loi ( ASSD ) : pass + + +#CONTEXT.debug = 1 +JdC = JDC_CATA ( code = 'OPENTURNS_STUDY', + execmodul = None, + regles = ( AU_MOINS_UN ( 'CRITERIA' ), AU_MOINS_UN ( 'MODEL' ), ), + ) # Fin JDC_CATA + +# -------------------------------------------------- +# fin entete +# -------------------------------------------------- + +LOG = PROC ( nom = "LOG", + op = None, + docu = "", + + DebugMessages = SIMP ( statut = "o", + typ = "TXM", + into = ( 'yes', 'no' ), + defaut = 'no', + fr = "Affichage du niveau de debug de la bibliotheque Open TURNS", + ang = "Open TURNS library debug level print", + ), + + WrapperMessages = SIMP ( statut = "o", + typ = "TXM", + into = ( 'yes', 'no' ), + defaut = 'no', + fr = "Affichage du niveau de wrapper de la bibliotheque Open TURNS", + ang = "Open TURNS library debug level print", + ), + + UserMessages = SIMP ( statut = "o", + typ = "TXM", + into = ( 'yes', 'no' ), + defaut = 'no', + fr = "Affichage du niveau de user de la bibliotheque Open TURNS", + ang = "Open TURNS library user level print", + ), + + InfoMessages = SIMP ( statut = "o", + typ = "TXM", + into = ( 'yes', 'no' ), + defaut = 'yes', + fr = "Affichage du niveau de info de la bibliotheque Open TURNS", + ang = "Open TURNS library info level print", + ), + + WarningMessages = SIMP ( statut = "o", + typ = "TXM", + into = ( 'yes', 'no' ), + defaut = 'yes', + fr = "Affichage du niveau de warning de la bibliotheque Open TURNS", + ang = "Open TURNS library warning level print", + ), + + ErrorMessages = SIMP ( statut = "o", + typ = "TXM", + into = ( 'yes', 'no' ), + defaut = 'yes', + fr = "Affichage du niveau de error de la bibliotheque Open TURNS", + ang = "Open TURNS library error level print", + ), + +) # Fin PROC LOG + + + + +#================================ +# 0. Definition du modele physique +#================================ + +MODEL = PROC ( nom = "MODEL", + op = None, + docu = "", + + Name = SIMP ( statut = "o", + typ = "TXM", + fr = "Nom du modele physique", + ang = "Physical model identifier", + ), + +) # Fin PROC MODEL + + + + + + +#================================ +# 1. Definition des LOIS +#================================ + +# Nota : les variables de type OPER doivent etre en majuscules ! +# Nota : les variables de type OPER doivent etre de premier niveau (pas imbriquees dans un autre type) +DISTRIBUTION = OPER ( nom = "DISTRIBUTION", + sd_prod = loi, + op = 68, + fr = "Definitions des lois marginales utilisees par les variables d'entree", + + +#==== +# Type de distribution +#==== + + Kind = SIMP ( statut = "o", typ = "TXM", + into = ( "Beta", + "Exponential", + "Gamma", + "Geometric", + "Gumbel", + "Histogram", + "Logistic", + "LogNormal", + "MultiNomial", + "Normal", + "TruncatedNormal", + "Poisson", + "Student", + "Triangular", + "Uniform", + "UserDefined", + "Weibull", + ), + fr = "Choix du type de la loi marginale", + ang = "1D marginal distribution", + ), + +#==== +# Definition des parametres selon le type de la loi +#==== + + BETA = BLOC ( condition = " Kind in ( 'Beta', ) ", + + Settings = SIMP ( statut = "o", + typ = "TXM", + max = 1, + into = ( "RT", "MuSigma" ), + defaut = "RT", + fr = "Parametrage de la loi beta", + ang = "Beta distribution parameter set", + ), + + RT_Parameters = BLOC ( condition = " Settings in ( 'RT', ) ", + + R = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre R de la loi", + ang = "R parameter", + ), + + # T > R + T = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre T de la loi | T > R", + ang = "T parameter | T > R", + ), + + ), # Fin BLOC RT_Parameters + + + MuSigma_Parameters = BLOC ( condition = " Settings in ( 'MuSigma', ) ", + + Mu = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu de la loi", + ang = "Mu parameter", + ), + + Sigma = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Sigma de la loi | Sigma > 0", + ang = "Sigma parameter | Sigma > 0", + ), + + ), # Fin BLOC MuSigma_Parameters + + + A = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre A de la loi", + ang = "A parameter", + ), + + # B > A + B = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre B de la loi | B > A", + ang = "B parameter | B > A", + ), + + ), # Fin BLOC BETA + + + + EXPONENTIAL = BLOC ( condition = " Kind in ( 'Exponential', ) ", + + Lambda = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Lambda | Lambda > 0", + ang = "Lambda parameter | Lambda > 0", + ), + + Gamma = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Gamma", + ang = "Gamma parameter", + ), + + ), # Fin BLOC EXPONENTIAL + + + + GAMMA = BLOC ( condition = " Kind in ( 'Gamma', ) ", + + Settings = SIMP ( statut = "o", + typ = "TXM", + max = 1, + into = ( "KLambda", "MuSigma" ), + defaut = "KLambda", + fr = "Parametrage de la loi gamma", + ang = "Gamma distribution parameter set", + ), + + KLambda_Parameters = BLOC ( condition = " Settings in ( 'KLambda', ) ", + + K = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre K de la loi | K > 0", + ang = "K parameter | K > 0", + ), + + Lambda = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Lambda de la loi | Lambda > 0", + ang = "Lambda parameter | Lambda > 0", + ), + + ), # Fin BLOC KLambda_Parameters + + + MuSigma_Parameters = BLOC ( condition = " Settings in ( 'MuSigma', ) ", + + Mu = SIMP ( statut = "o", + typ = "R", + max = 1, + defaut = 0.0, + fr = "Parametre Mu de la loi", + ang = "Mu parameter", + ), + + Sigma = SIMP ( statut = "o", + typ = "R", + max = 1, + defaut = 1.0, + val_min = 0., + fr = "Parametre Sigma de la loi | Sigma > 0", + ang = "Sigma parameter | Sigma > 0", + ), + + ), # Fin BLOC MuSigma_Parameters + + Gamma = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Gamma", + ang = "Gamma parameter", + ), + + + ), # Fin BLOC GAMMA + + + + GEOMETRIC = BLOC ( condition = " Kind in ( 'Geometric', ) ", + + P = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + val_max = 1., + fr = "Parametre P | 0 < P < 1", + ang = "P parameter | 0 < P < 1", + ), + + ), # Fin BLOC GEOMETRIC + + + + GUMBEL = BLOC ( condition = " Kind in ( 'Gumbel', ) ", + + Settings = SIMP ( statut = "o", + typ = "TXM", + max = 1, + into = ( "AlphaBeta", "MuSigma" ), + defaut = "AlphaBeta", + fr = "Parametrage de la loi gumbel", + ang = "Gumbel distribution parameter set", + ), + + AlphaBeta_Parameters = BLOC ( condition = " Settings in ( 'AlphaBeta', ) ", + + Alpha = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Alpha de la loi | Alpha > 0", + ang = "Alpha parameter | Alpha > 0", + ), + + Beta = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Beta de la loi", + ang = "Beta parameter", + ), + + ), # Fin BLOC AlphaBeta_Parameters + + + MuSigma_Parameters = BLOC ( condition = " Settings in ( 'MuSigma', ) ", + + Mu = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu de la loi", + ang = "Mu parameter", + ), + + Sigma = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Sigma de la loi | Sigma > 0", + ang = "Sigma parameter | Sigma > 0", + ), + + ), # Fin BLOC MuSigma_Parameters + + ), # Fin BLOC GUMBEL + + + + HISTOGRAM = BLOC ( condition = " Kind in ( 'Histogram', ) ", + + Sup = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Borne superieure de la distribution", + ang = "Upper bound", + ), + + # Il faut definir une collection de couples ( x,p ) + Values = SIMP ( statut = 'o', + typ = 'R', + max = '**', + ), + + ), # Fin BLOC HISTOGRAM + + + + LOGNORMAL = BLOC ( condition = " Kind in ( 'LogNormal', ) ", + + Settings = SIMP ( statut = "o", + typ = "TXM", + max = 1, + into = ( "MuSigmaLog", "MuSigma", "MuSigmaOverMu" ), + defaut = "MuSigmaLog", + fr = "Parametrage de la loi lognormale", + ang = "Lognormal distribution parameter set", + ), + + MuSigma_Parameters = BLOC ( condition = " Settings in ( 'MuSigma', ) ", + + Mu = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu de la loi | Mu > Gamma", + ang = "Mu parameter | Mu > Gamma", + ), + + Sigma = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Sigma de la loi | Sigma > 0", + ang = "Sigma parameter | Sigma > 0", + ), + + ), # Fin BLOC MuSigma_Parameters + + MuSigmaOverMu_Parameters = BLOC ( condition = " Settings in ( 'MuSigmaOverMu', ) ", + + Mu = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu de la loi | Mu > Gamma", + ang = "Mu parameter | Mu > Gamma", + ), + + SigmaOverMu = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre SigmaOverMu de la loi | SigmaOverMu > 0", + ang = "SigmaOverMu parameter | SigmaOverMu > 0", + ), + + ), # Fin BLOC MuSigmaOverMu_Parameters + + MuSigmaLog_Parameters = BLOC ( condition = " Settings in ( 'MuSigmaLog', ) ", + + MuLog = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu log de la loi", + ang = "Mu log parameter", + ), + + SigmaLog = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Sigma log de la loi | SigmaLog > 0", + ang = "Sigma log parameter | SigmaLog > 0", + ), + + ), # Fin BLOC MuSigmaLog_Parameters + + Gamma = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Gamma", + ang = "Gamma parameter", + ), + + ), # Fin BLOC LOGNORMAL + + + + LOGISTIC = BLOC ( condition = " Kind in ( 'Logistic', ) ", + + Alpha = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Alpha de la loi", + ang = "Alpha parameter", + ), + + Beta = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Beta de la loi | Beta > = 0", + ang = "Beta parameter | Beta > = 0", + ), + + ), # Fin BLOC LOGISTIC + + + + MULTINOMIAL = BLOC ( condition = " Kind in ( 'MultiNomial', ) ", + + N = SIMP ( statut = "o", + typ = "I", + max = 1, + fr = "Dimension de la loi", + ang = "Distribution dimension", + ), + + # Il faut un vecteur P de taille N + Values = SIMP ( statut = 'o', + typ = 'R', + max = '**', + ), + + ), # Fin BLOC MULTINOMIAL + + + + NORMAL = BLOC ( condition = " Kind in ( 'Normal', ) ", + + Mu = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu de la loi", + ang = "Mu parameter", + ), + + Sigma = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Sigma de la loi | Sigma > 0", + ang = "Sigma parameter | Sigma > 0", + ), + + ), # Fin BLOC NORMAL + + + + POISSON = BLOC ( condition = " Kind in ( 'Poisson', ) ", + + Lambda = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Lambda de la loi | Lambda > 0", + ang = "Lambda parameter | Lambda > 0", + ), + + ), # Fin BLOC POISSON + + + + STUDENT = BLOC ( condition = " Kind in ( 'Student', ) ", + + Mu = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu de la loi", + ang = "Mu parameter", + ), + + Nu = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 2., + fr = "Parametre Nu de la loi | V > = 2", + ang = "Nu parameter | V > = 2", + ), + + ), # Fin BLOC STUDENT + + + + TRIANGULAR = BLOC ( condition = " Kind in ( 'Triangular', ) ", + + A = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Borne inferieure de la loi | A < = M < = B", + ang = "Lower bound | A < = M < = B", + ), + + M = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Mode de la loi | A < = M < = B", + ang = "Mode | A < = M < = B", + ), + + B = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Borne superieure de la loi | A < = M < = B", + ang = "Upper bound | A < = M < = B", + ), + + ), # Fin BLOC TRIANGULAR + + + + TRUNCATEDNORMAL = BLOC ( condition = " Kind in ( 'TruncatedNormal', ) ", + + MuN = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu de la loi", + ang = "Mu parameter", + ), + + SigmaN = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre SigmaN de la loi | SigmaN > 0", + ang = "SigmaN parameter | SigmaN> 0", + ), + + A = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Borne inferieure de la loi | A < = B", + ang = "Lower bound | A < = B", + ), + + B = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Borne superieure de la loi | A < = B", + ang = "Upper bound | A < = B", + ), + + ), # Fin BLOC TRUNCATEDNORMAL + + + + UNIFORM = BLOC ( condition = " Kind in ( 'Uniform', ) ", + + A = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Borne inferieure de la loi | A < = B", + ang = "Lower bound | A < = B", + ), + + B = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Borne superieure de la loi | A < = B", + ang = "Upper bound | A < = B", + ), + + ), # Fin BLOC UNIFORM + + + + USERDEFINED = BLOC ( condition = " Kind in ( 'UserDefined', ) ", + + # Il faut definir une collection de couples ( x,p ) + Values = SIMP ( statut = 'o', + typ = 'R', + max = '**', + ), + + ), # Fin BLOC USERDEFINED + + + + WEIBULL = BLOC ( condition = " Kind in ( 'Weibull', ) ", + + Settings = SIMP ( statut = "o", + typ = "TXM", + max = 1, + into = ( "AlphaBeta", "MuSigma" ), + defaut = "AlphaBeta", + fr = "Parametrage de la loi weibull", + ang = "Weibull distribution parameter set", + ), + + AlphaBeta_Parameters = BLOC ( condition = " Settings in ( 'AlphaBeta', ) ", + + Alpha = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Alpha de la loi | Alpha > 0", + ang = "Alpha parameter | Alpha > 0", + ), + + Beta = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Beta de la loi | Beta > 0", + ang = "Beta parameter | Beta > 0", + ), + + ), # Fin BLOC AlphaBeta_Parameters + + + MuSigma_Parameters = BLOC ( condition = " Settings in ( 'MuSigma', ) ", + + Mu = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Mu de la loi", + ang = "Mu parameter", + ), + + Sigma = SIMP ( statut = "o", + typ = "R", + max = 1, + val_min = 0., + fr = "Parametre Sigma de la loi | Sigma > 0", + ang = "Sigma parameter | Sigma > 0", + ), + + ), # Fin BLOC MuSigma_Parameters + + Gamma = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Parametre Gamma", + ang = "Gamma parameter", + ), + + ), # Fin BLOC WEIBULL + +) # Fin OPER DISTRIBUTION + + + + + + +#================================ +# 3. Definition de l'etude +#================================ + +# Nota : les variables de type PROC doivent etre en majuscules ! +CRITERIA = PROC ( nom = "CRITERIA", + op = None, + docu = "", + fr = "Mise en donnee pour le fichier de configuration de OPENTURNS.", + ang = "Writes the configuration file for OPENTURNS.", + + + + Type = SIMP ( statut = "o", + typ = "TXM", + into = ( "Min/Max", "Central Uncertainty", "Threshold Exceedence" ), + fr = "Type d'Analyse", + ang = "Analysis", + ), + + + + + + + + MinMax = BLOC ( condition = " Type in ( 'Min/Max', ) ", + + Method = SIMP ( statut = "o", + typ = "TXM", + into = ( "Experiment Plane", "Random Sampling" ), + fr = "Methode", + ang = "Method", + ), + # UC 3.1.1 + ExperimentPlaneSettings = BLOC ( condition = " Method in ( 'Experiment Plane', ) ", + + ExperimentPlane = SIMP ( statut = "o", + typ = "TXM", + into = ( "Axial", "Factorial", "Composite", ), + fr = "Methode", + ang = "Method", + ), + + Levels = SIMP ( statut = "o", + typ = "R", + val_min = 0.0, + max = '**', + fr = "Nombre de niveaux dans chaque direction", + ang = "Levels in each direction", + ), + + # Scaled Vector + UnitsPerDimension = SIMP ( statut = "o", + typ = "R", + max = '**', + fr = "Unite par dimension (autant que de variables declarees)", + ang = "Units per dimension (as much as declared variables)", + ), + + # Translation Vector + Center = SIMP ( statut = "o", + typ = "R", + max = '**', + fr = "Unite par dimension", + ang = "Units per dimension", + ), + + ), # Fin BLOC ExperimentPlaneSettings + + + + RandomSamplingSettings = BLOC ( condition = " Method in ( 'Random Sampling', ) ", + + PointsNumber = SIMP ( statut = "o", + typ = "I", + val_min = 1, + fr = "Nombre de points", + ang = "Points number", + ), + + ), # Fin BLOC RandomSamplingSettings + + Result = SIMP ( statut = "o", + typ = "TXM", + into = ( "Min/Max", ), + defaut = "Min/Max", + fr = "Le minimum et le maximum", + ang = "The min and max values", + ), + + + ), # Fin BLOC MinMax + + + + + CentralUncertainty = BLOC ( condition = " Type in ( 'Central Uncertainty', ) ", + + Method = SIMP ( statut = "o", + typ = "TXM", + into = ( "Taylor Variance Decomposition", "Random Sampling" ), + fr = "Methode", + ang = "Method", + ), + + # UC 3.2. + TaylorVarianceDecompositionSettings = BLOC ( condition = " Method in ( 'Taylor Variance Decomposition', ) ", + + Result = FACT ( statut = "o", + min = 1, + max = "**", + + MeanFirstOrder = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Moyenne au premier ordre", + ang = "MeanFirstOrder", + ), + + StandardDeviationFirstOrder = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Ecart-type au premier ordre", + ang = "StandardDeviationFirstOrder", + ), + + MeanSecondOrder = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Moyenne au second ordre", + ang = "MeanSecondOrder", + ), + + ImportanceFactor = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Facteur d'importance pour variable de sortie scalaire", + ang = "ImportanceFactor", + ), + + ImportanceFactorSettings = BLOC ( condition = " ImportanceFactor in ( 'yes', ) ", + + NumericalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Resultats numeriques", + ang = "NumericalResults", + ), + + GraphicalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Resultats graphiques", + ang = "GraphicalResults", + ), + + ), # Fin BLOC ImportanceFactorSettings + + ), # Fin FACT Result + + ), # Fin BLOC TaylorVarianceDecompositionSettings + + + + RandomSamplingSettings = BLOC ( condition = " Method in ( 'Random Sampling', ) ", + + PointsNumber = SIMP ( statut = "o", + typ = "I", + val_min = 1, + fr = "Nombre de points", + ang = "Points number", + ), + + Result = FACT ( statut = "o", + min = 1, + max = "**", + + EmpiricalMean = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Moyenne empirique", + ang = "Empirical mean", + ), + + EmpiricalStandardDeviation = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Ecart-type empirique", + ang = "Empirical standard deviation", + ), + + EmpiricalQuantile = SIMP ( statut = "o", + typ = 'R', + defaut = 0.0, + max = 1, + val_min = 0.0, + val_max = 1.0, + fr = "Quantile empirique", + ang = "Empirical quantile", + ), + + AnalysedCorrelations = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Correlations analysees", + ang = "Analysed correlations", + ), + + KernelSmoothing = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Kernel smoothing de l'echantillon", + ang = "Kernel smoothing of the sample", + ), + + ), # Fin FACT Result + + ), # Fin BLOC RandomSamplingSettings + + ), # Fin BLOC CentralUncertainty + + + + + ThresholdExceedence = BLOC ( condition = " Type in ( 'Threshold Exceedence', ) ", + + Event = FACT ( statut = "o", + min = 1, + max = 1, + + Threshold = SIMP ( statut = "o", + typ = "R", + max = 1, + fr = "Le seuil de defaillance", + ang = "Failure threshold", + ), + + ComparisonOperator = SIMP ( statut = "o", + typ = "TXM", + max = 1, + into = ( "Less", "LessOrEqual", "Equal", "GreaterOrEqual", "Greater" ), + fr = "Que faut-il ne pas depasser : un maximum ou un minimum", + ang = "What is the failure threshold : maximum or minimum", + ), + ), # Fin FACT Event + + + Method = SIMP ( statut = "o", + typ = "TXM", + into = ( "Simulation", "Analytical" ), + fr = "Methode", + ang = "Method", + ), + + SimulationSettings = BLOC ( condition = " Method in ( 'Simulation', ) ", + + Algorithm = SIMP ( statut = "o", + typ = "TXM", + into = ( "MonteCarlo", "LHS", "ImportanceSampling" ), + fr = "Algorithme de simulation", + ang = "Simulation algorithm", + ), + + + RandomGenerator = FACT ( statut = "o", + min = 1, + max = 1, + + SeedToBeSet = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "La racine du generateur aleatoire doit-elle etre positionnee ?", + ang = "Does the random generator seed need to be set ?", + ), + + SeedSettings = BLOC ( condition = " SeedToBeSet in ( 'yes', ) ", + + RandomGeneratorSeed = SIMP ( statut = "o", + typ = "I", + max = 1, + fr = "Racine du generateur aleatoire", + ang = "Random generator seed", + ), + + ), # Fin BLOC SeedSettings + + ), # Fin FACT RandomGenerator + + + BlockSize = SIMP ( statut = "f", + typ = "I", + max = 1, + val_min = 1, + defaut = 1, + fr = "Nombre de calculs realises en bloc", + ang = "Number of computations as a block", + ), + + MaximumOuterSampling = SIMP ( statut = "o", + typ = "I", + max = 1, + val_min = 1, + fr = "Maximum d'iterations externes", + ang = "Maximum outer Sampling value", + ), + + MaximumCoefficientOfVariation = SIMP ( statut = "f", + typ = "R", + max = 1, + defaut = 0.1, + val_min = 0.0, + fr = " maximum ...", + ang = "Absolute maximum ...." + ), + + ImportanceSamplingSettings = BLOC ( condition = " Algorithm in ( 'ImportanceSampling', ) ", + + MeanVector = SIMP ( statut = "o", + typ = "R", + max = "**", + fr = "Moyenne", + ang = "Mean vector", + ), + + Correlation = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'Independent', 'Linear' ), + defaut = 'Linear', + max = 1, + fr = "Le type de correlation entre les variables", + ang = "Correlation between variables", + ), + + ), # Fin BLOC ImportanceSamplingSettings + + Result = FACT ( statut = "o", + min = 1, + max = "**", + + Probability = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', ), + defaut = 'yes', + max = 1, + fr = "Probabiblite", + ang = "Probability", + ), + + ConfidenceInterval = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Ecart-type empirique", + ang = "Empirical standard deviation", + ), + + ConfidenceIntervalSettings = BLOC ( condition = " ConfidenceInterval in ( 'yes', ) ", + + Level = SIMP ( statut = "o", + typ = 'R', + defaut = 0.0, + max = 1, + val_min = 0.0, + val_max = 1.0, + fr = "Niveau de confiance", + ang = "Confidence level", + ), + + ), # Fin BLOC ConfidenceIntervalSettings + + VariationCoefficient = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Coefficient de variation", + ang = "VariationCoefficient", + ), + + IterationNumber = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Nombre d'iterations", + ang = "Iteration number", + ), + + ConvergenceGraph = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Graphe de convergence", + ang = "Convergence graph", + ), + + ), # Fin FACT Result + + + + ), # Fin BLOC SimulationSettings + + + + AnalyticalSettings = BLOC ( condition = " Method in ( 'Analytical', ) ", + + Approximation = SIMP ( statut = "o", + typ = "TXM", + into = ( "FORM", "SORM" ), + fr = "Approximation", + ang = "Approximation", + ), + + OptimizationAlgorithm = SIMP ( statut = "o", + typ = "TXM", + into = ( "Cobyla", "AbdoRackwitz" ), + fr = "Methode d'optimisation", + ang = "Optimisation method", + ), + + + PhysicalStartingPoint = SIMP ( statut = "f", + typ = "R", + max = "**", + fr = "Point de demarrage de l'algorithme iteratif", + ang = "Initial point for iterative process", + ), + + MaximumIterationsNumber = SIMP ( statut = "f", + typ = "I", + max = 1, + val_min = 1, + fr = "Nombre maximum d iterations", + ang = "Maximum number of iterations", + ), + + regles = ( EXCLUS ( "MaximumAbsoluteError", "RelativeAbsoluteError" ), ), + + MaximumAbsoluteError = SIMP ( statut = "f", + typ = "R", + max = 1, + defaut = 1E-6, + val_min = 0.0, + fr = "Distance maximum absolue entre 2 iterations successifs", + ang = "Absolute maximum distance between 2 successive iterates", + ), + + RelativeAbsoluteError = SIMP ( statut = "f", + typ = "R", + max = 1, + defaut = 1E-6, + val_min = 0.0, + fr = "Distance maximum relative entre 2 iterations successives", + ang = "Relative maximum distance between 2 successive iterates", + ), + + MaximumConstraintError = SIMP ( statut = "f", + typ = "R", + max = 1, + val_min = 0.0, + fr = "Valeur maximum absolue de la fonction moins la valeur du niveau", + ang = "Maximum absolute value of the constraint function minus the level value", + ), + + ImportanceSampling = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Tirage d'importance au point de conception", + ang = "Importance sampling at design point", + ), + + FORM = BLOC ( condition = " Approximation in ( 'FORM', ) ", + + Probability = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', ), + defaut = 'yes', + max = 1, + fr = "Probabiblite", + ang = "Probability", + ), + + DesignPoint = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Point de conception", + ang = "Design point", + ), + + HasReliabilityIndex = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Indice de fiabilite", + ang = "Reliability index", + ), + + ImportanceFactor = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Facteur d'importance pour variable de sortie scalaire", + ang = "ImportanceFactor", + ), + + ImportanceFactorSettings = BLOC ( condition = " ImportanceFactor in ( 'yes', ) ", + + NumericalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Resultats numeriques", + ang = "NumericalResults", + ), + + GraphicalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Resultats graphiques", + ang = "GraphicalResults", + ), + + ), # Fin BLOC ImportanceFactorSettings + + + SensitivityAnalysis = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Analyse de sensibilite", + ang = "Sensitivity analysis", + ), + + SensitivityAnalysisSettings = BLOC ( condition = " SensitivityAnalysis in ( 'yes', ) ", + + HasoferReliabilityIndex = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Indice de fiabilite de Hasofer", + ang = "Hasofer reliability index", + ), + + HasoferReliabilityIndexSettings = BLOC ( condition = " HasoferReliabilityIndex in ( 'yes', ) ", + + NumericalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Resultats numeriques", + ang = "NumericalResults", + ), + + GraphicalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Resultats graphiques", + ang = "GraphicalResults", + ), + + ), # Fin BLOC HasoferReliabilityIndexSettings + + ), # Fin BLOC SensitivityAnalysisSettings + + FunctionCallsNumber = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Nombre d'appels a la fonction", + ang = "Function calls number", + ), + + + ), # Fin BLOC FORM + + + SORM = BLOC ( condition = " Approximation in ( 'SORM', ) ", + + + TvedtApproximation = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Approximation de Tvedt", + ang = "Tvedt approximation", + ), + + HohenBichlerApproximation = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Approximation de HohenBichler", + ang = "HohenBichler approximation", + ), + + BreitungApproximation = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Approximation de Breitung", + ang = "Breitung approximation", + ), + + DesignPoint = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Point de conception", + ang = "Design point", + ), + + ImportanceFactor = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Facteur d'importance pour variable de sortie scalaire", + ang = "ImportanceFactor", + ), + + ImportanceFactorSettings = BLOC ( condition = " ImportanceFactor in ( 'yes', ) ", + + NumericalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Resultats numeriques", + ang = "NumericalResults", + ), + + GraphicalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Resultats graphiques", + ang = "GraphicalResults", + ), + + ), # Fin BLOC ImportanceFactorSettings + + + SensitivityAnalysis = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Analyse de sensibilite", + ang = "Sensitivity analysis", + ), + + SensitivityAnalysisSettings = BLOC ( condition = " SensitivityAnalysis in ( 'yes', ) ", + + HasoferReliabilityIndex = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Indice de fiabilite de Hasofer", + ang = "Hasofer reliability index", + ), + + HasoferReliabilityIndexSettings = BLOC ( condition = " HasoferReliabilityIndex in ( 'yes', ) ", + + NumericalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'yes', + max = 1, + fr = "Resultats numeriques", + ang = "NumericalResults", + ), + + GraphicalResults = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Resultats graphiques", + ang = "GraphicalResults", + ), + + ), # Fin BLOC HasoferReliabilityIndexSettings + + ), # Fin BLOC SensitivityAnalysisSettings + + FunctionCallsNumber = SIMP ( statut = "o", + typ = 'TXM', + into = ( 'yes', 'no' ), + defaut = 'no', + max = 1, + fr = "Nombre d'appels a la fonction", + ang = "Function calls number", + ), + + + ), # Fin BLOC SORM + + + + ), # Fin BLOC AnalyticalSettings + + + + ), # Fin BLOC ThresholdExceedence + + + +) # Fin PROC CRITERIA + + + + + + + diff --git a/Openturns_Study/catalogues_openturns.ini b/Openturns_Study/catalogues_openturns.ini index 8a16ff62..511e50a2 100644 --- a/Openturns_Study/catalogues_openturns.ini +++ b/Openturns_Study/catalogues_openturns.ini @@ -6,7 +6,7 @@ rep_cata=os.getcwd() catalogues = ( # (code,version,catalogue,formatIn,formatOut) #('OPENTURNS_WRAPPER','V1',os.path.join(rep_cata,'OpenTURNS_Cata_Wrapper_V1.py'),'openturns_wrapper','wrapper'), - ('OPENTURNS_STUDY','V1',os.path.join(rep_cata,'OpenTURNS_Cata_Study.py'),'openturns_study','wrapper'), + ('OPENTURNS_STUDY','V2',os.path.join(rep_cata,'OpenTURNS_Cata_Study_V2.py'),'openturns_study','wrapper'), #('OPENTURNS','Wrapper',os.path.join(rep_cata,'OpenTURNS_Cata_Wrapper_V1.py'),'openturns'), ) diff --git a/Openturns_Study/test/MinMax_ExpPlane.comm b/Openturns_Study/test/MinMax_ExpPlane.comm new file mode 100644 index 00000000..6f671ab3 --- /dev/null +++ b/Openturns_Study/test/MinMax_ExpPlane.comm @@ -0,0 +1,17 @@ + +LOG(DebugMessages='no', + WrapperMessages='no', + UserMessages='no', + InfoMessages='yes', + WarningMessages='yes', + ErrorMessages='yes',); + +MODEL(Name='poutre',); + +CRITERIA(Type='Min/Max', + Method='Experiment Plane', + ExperimentPlane='Axial', + Levels=(1.0,2.0,5.0,), + UnitsPerDimension=(100.0,5.0,0.5,1e-07,), + Center=(3000000000.0,300.0,2.5,4e-06,), + Result='Min/Max',); diff --git a/Openturns_Study/test/MinMax_ExpPlane.py b/Openturns_Study/test/MinMax_ExpPlane.py new file mode 100644 index 00000000..098c853e --- /dev/null +++ b/Openturns_Study/test/MinMax_ExpPlane.py @@ -0,0 +1,68 @@ +#! /usr/bin/env python + +# Chargement du module systeme +import sys +sys.path.append( '/local00/home/dutka/OpenTURNS/trunk/build/install/lib/python2.4/site-packages/openturns' ) + +# Chargement du module Open TURNS +from openturns import * + +# Definit le niveau d'affichage de la log +flags = Log.NONE +flags = flags + Log.WARN +flags = flags + Log.ERROR +flags = flags - Log.WRAPPER +flags = flags + Log.INFO +flags = flags - Log.USER +flags = flags - Log.DBG +Log.Show( flags ) + +# Etude 'Min/Max' +# Charge le modele physique +model = NumericalMathFunction( 'poutre' ) +n = model.getInputNumericalPointDimension() + +# Etude par plan d'experience +# Definit les niveaux de la structure de grille +levels = NumericalPoint( 3 ) +levels[0] = 1 +levels[1] = 2 +levels[2] = 5 + +# Cree le plan d'experience centre reduit +myCenteredReductedGrid = Axial(n, levels) +myExperimentPlane = myCenteredReductedGrid.generate() + +# Definit les facteurs d'echelle dans chaque direction +scaledVector = NumericalPoint( n ) +scaledVector[0] = 100 +scaledVector[1] = 5 +scaledVector[2] = 0.5 +scaledVector[3] = 1e-07 +myExperimentPlane.scale( scaledVector ) + +# Definit le vecteur de translation +translationVector = NumericalPoint( n ) +translationVector[0] = 3e+09 +translationVector[1] = 300 +translationVector[2] = 2.5 +translationVector[3] = 4e-06 +myExperimentPlane.translate( translationVector ) + + +inputSample = myExperimentPlane + +# Calcul +outputSample = model( inputSample ) + +# Resultats +minValue = outputSample.getMin() +maxValue = outputSample.getMax() + +print 'minValue = ', minValue +print 'maxValue = ', maxValue + + + +# Terminaison du fichier +sys.exit( 0 ) diff --git a/Openturns_Study/test/MinMax_RandomSampling.comm b/Openturns_Study/test/MinMax_RandomSampling.comm new file mode 100644 index 00000000..e9ed474b --- /dev/null +++ b/Openturns_Study/test/MinMax_RandomSampling.comm @@ -0,0 +1,30 @@ + +LOG(DebugMessages='no', + WrapperMessages='no', + UserMessages='no', + InfoMessages='yes', + WarningMessages='yes', + ErrorMessages='yes',); + +MODEL(Name='poutre',); + +L_E=DISTRIBUTION(Kind='Normal', + Mu=0.1, + Sigma=0.1,); + +L_F=DISTRIBUTION(Kind='Exponential', + Lambda=1.0, + Gamma=2.0,); + +L_L=DISTRIBUTION(Kind='MultiNomial', + N=1, + Values=1.0,); + +L_I=DISTRIBUTION(Kind='Uniform', + A=10.0, + B=20.0,); + +CRITERIA(Type='Min/Max', + Method='Random Sampling', + PointsNumber=1000, + Result='Min/Max',); diff --git a/generator/OpenturnsSTD.py b/generator/OpenturnsSTD.py index 3501a91a..dba6a227 100644 --- a/generator/OpenturnsSTD.py +++ b/generator/OpenturnsSTD.py @@ -21,7 +21,7 @@ class StudyFileGenerationError: raise StudyFileGenerationError, "The study file was not generated" """ -enteteSTD = """#! /usr/bin/env python +headerSTD = """#! /usr/bin/env python # Chargement du module systeme import sys @@ -32,7 +32,7 @@ from openturns import * """ -piedDePageSTD = """ +footerSTD = """ # Terminaison du fichier sys.exit( 0 ) @@ -84,6 +84,13 @@ class STDGenerateur : "minValue" : "minValue", "maxValue" : "maxValue", "flags" : "flags", + "inSize" : "inSize", + "distribution" : "distribution", + "marginal" : "marginal", + "collection" : "collection", + "copula" : "copula", + "inputRandomVector" : "inputRandomVector", + "outputRandomVector" : "outputRandomVector", } # Ce dictionnaire fait la correspondance entre le mot-clef du catalogue et le flag de la bibliotheque @@ -113,11 +120,11 @@ class STDGenerateur : return self.texteSTD - def Entete (self) : + def Header (self) : ''' Imprime l entete commun a tous les fichiers ''' - txt = enteteSTD % self.OpenTURNS_path + txt = headerSTD % self.OpenTURNS_path txt += "# Definit le niveau d'affichage de la log\n" txt += "%s = Log.NONE\n" % self.variable["flags"] for flag in self.logFlags.keys(): @@ -131,17 +138,17 @@ class STDGenerateur : txt += "\n" return txt - def PiedDePage (self) : + def Footer (self) : ''' Imprime le pied de page commun a tous les fichiers ''' - return piedDePageSTD + return footerSTD def MinMax (self): ''' Produit le fichier study correspondant a une analyse Min/Max ''' - txt = self.Entete() + txt = self.Header() txt += "# Etude 'Min/Max'\n" txt += self.Model() @@ -160,7 +167,7 @@ class STDGenerateur : txt += self.MinMaxComputation() txt += self.MinMaxResult() - txt += self.PiedDePage() + txt += self.Footer() return txt def Model (self): @@ -186,13 +193,67 @@ class STDGenerateur : txt += self.CenteredReductedGrid() txt += self.ScaledVector() txt += self.TranslationVector() + txt += "%s = %s\n" % (self.variable["inputSample"], self.variable["myExperimentPlane"]) + txt += "\n" return txt def RandomSampling (self): ''' Etude par echantillonage aleatoire ''' + size = 0 + if ( self.DictMCVal.has_key( 'PointsNumber' ) ): + size = self.DictMCVal[ 'PointsNumber' ] + txt = "# Etude par echantillonage aleatoire\n" + txt += self.InputDistribution() + txt += self.InputRandomVector() + txt += "%s = %d\n" % (self.variable["inSize"], size) + txt += "%s = %s.getNumericalSample( %s )\n" % (self.variable["inputSample"], self.variable["inputRandomVector"], self.variable["inSize"]) + txt += "\n" + return txt + + def InputDistribution (self): + ''' + Cree la loi jointe des variables d entree + ''' + txt = "# Definit la loi jointe des variables d'entree\n" + txt += "%s = DistributionCollection( %d )\n" % (self.variable["collection"], len( self.DictLois )) + txt += "\n" + i = 0 + for concept in self.DictLois.keys(): + loi = self.DictLois[ concept ] + if loi.has_key( 'Kind' ): + marginale = "%s_%d" % (self.variable["marginal"], i) + txt += "# Definit la loi marginale de la composante %d\n" % i + txt += "%s = %s\n" % (marginale, apply( STDGenerateur.__dict__[ loi[ 'Kind' ] ], (self, loi, i, self.variable["collection"]) )) + txt += "%s[ %d ] = Distribution( %s )\n" % (self.variable["collection"], i, marginale) + txt += "\n" + i += 1 + + txt += self.Copula() + + txt += "# Definit la loi jointe\n" + txt += "%s = ComposedDistribution( %s, Copula( %s ) )\n" % (self.variable["distribution"], self.variable["collection"], self.variable["copula"]) + txt += "\n" + return txt + + def Copula (self): + ''' + Cree la copule de la loi jointe + ''' + txt = "# Definit la copule de la loi jointe\n" + txt += "%s = IndependentCopula()\n" % self.variable["copula"] + txt += "\n" + return txt + + def InputRandomVector (self): + ''' + Cree le vector aleatoire d entree + ''' + txt = "# Definit le vecteur aleatoire d'entree\n" + txt += "%s = RandomVector( %s )\n" % (self.variable["inputRandomVector"], self.variable["distribution"]) + txt += "\n" return txt def ScaledVector (self): @@ -264,7 +325,6 @@ class STDGenerateur : Realise le calcul deterministe ''' txt = "# Calcul\n" - txt += "%s = %s\n" % (self.variable["inputSample"], self.variable["myExperimentPlane"]) txt += "%s = %s( %s )\n" % (self.variable["outputSample"], self.variable["model"], self.variable["inputSample"]) txt += "\n" return txt @@ -286,18 +346,219 @@ class STDGenerateur : ''' Produit le fichier study correspondant a une analyse d incertitude en valeur centrale ''' - txt = self.Entete() + txt = self.Header() txt += "# Etude 'Central Uncertainty'\n\n" - txt += self.PiedDePage() + txt += self.Footer() return txt def ThresholdExceedence (self): ''' Produit le fichier study correspondant a une analyse de depassement de seuil ''' - txt = self.Entete() + txt = self.Header() txt += "# Etude 'Threshold Exceedence'\n\n" - txt += self.PiedDePage() + txt += self.Footer() return txt + def Beta (self, loi, i, collection): + ''' + Definition de la loi Beta + ''' + settings = { + "RT" : "Beta.RT", + "MuSigma" : "Beta.MUSIGMA", + } + if loi[ 'Settings' ] == 'RT' : + arg1 = loi[ 'R' ] + arg2 = loi[ 'T' ] + else : + arg1 = loi[ 'Mu' ] + arg2 = loi[ 'Sigma' ] + + arg3 = loi[ 'A' ] + arg4 = loi[ 'B' ] + txt = "Beta( %g, %g, %g, %g, %s )" % (arg1, arg2, arg3, arg4, settings[ loi[ 'Settings' ] ]) + return txt + + def Exponential (self, loi, i, collection): + ''' + Definition de la loi Exponential + ''' + arg1 = loi[ 'Lambda' ] + arg2 = loi[ 'Gamma' ] + txt = "Exponential( %g, %g )" % (arg1, arg2) + return txt + def Gamma (self, loi, i, collection): + ''' + Definition de la loi Gamma + ''' + settings = { + "KLambda" : "Gamma.KLAMBDA", + "MuSigma" : "Gamma.MUSIGMA", + } + if loi[ 'Settings' ] == 'KLambda' : + arg1 = loi[ 'K' ] + arg2 = loi[ 'Lambda' ] + else : + arg1 = loi[ 'Mu' ] + arg2 = loi[ 'Sigma' ] + + arg3 = loi[ 'Gamma' ] + txt = "Gamma( %g, %g, %g, %s )" % (arg1, arg2, arg3, settings[ loi[ 'Settings' ] ]) + return txt + + def Geometric (self, loi, i, collection): + ''' + Definition de la loi Geometric + ''' + txt = "Geometric( %g )" % loi[ 'P' ] + return txt + + def Gumbel (self, loi, i, collection): + ''' + Definition de la loi Gumbel + ''' + settings = { + "AlphaBeta" : "Gamma.ALPHABETA", + "MuSigma" : "Gamma.MUSIGMA", + } + if loi[ 'Settings' ] == 'AlphaBeta' : + arg1 = loi[ 'Alpha' ] + arg2 = loi[ 'Beta' ] + else : + arg1 = loi[ 'Mu' ] + arg2 = loi[ 'Sigma' ] + + txt = "Gamma( %g, %g, %s )" % (arg1, arg2, settings[ loi[ 'Settings' ] ]) + return txt + + def Histogram (self, loi, i, collection): + ''' + Definition de la loi Histogram + ''' + txt = "** Histogram not defined yet **" + return txt + + def Logistic (self, loi, i, collection): + ''' + Definition de la loi Logistic + ''' + arg1 = loi[ 'Alpha' ] + arg2 = loi[ 'Beta' ] + txt = "Logistic( %g, %g )" % (arg1, arg2) + return txt + + def LogNormal (self, loi, i, collection): + ''' + Definition de la loi LogNormal + ''' + settings = { + "MuSigmaLog" : "LogNormal.MUSIGMA_LOG", + "MuSigma" : "LogNormal.MUSIGMA", + "MuSigmaOverMu" : "LogNormal.MU_SIGMAOVERMU", + } + if loi[ 'Settings' ] == 'MuSigmaLog' : + arg1 = loi[ 'MuLog' ] + arg2 = loi[ 'SigmaLog' ] + elif loi[ 'Settings' ] == 'MuSigmaOverMu' : + arg1 = loi[ 'Mu' ] + arg2 = loi[ 'SigmaOverMu' ] + else : + arg1 = loi[ 'Mu' ] + arg2 = loi[ 'Sigma' ] + + arg3 = loi[ 'Gamma' ] + txt = "LogNormal( %g, %g, %g, %s )" % (arg1, arg2, arg3, settings[ loi[ 'Settings' ] ]) + return txt + + def MultiNomial (self, loi, i, collection): + ''' + Definition de la loi MultiNomial + ''' + arg1 = loi[ 'Values' ] + arg2 = loi[ 'N' ] + txt = "MultiNomial( NumericalPoint( %s ) , %d)" % (arg1, arg2) + return txt + + def Normal (self, loi, i, collection): + ''' + Definition de la loi Normal + ''' + arg1 = loi[ 'Mu' ] + arg2 = loi[ 'Sigma' ] + txt = "Normal( %g, %g )" % (arg1, arg2) + return txt + + def TruncatedNormal (self, loi, i, collection): + ''' + Definition de la loi TruncatedNormal + ''' + arg1 = loi[ 'MuN' ] + arg2 = loi[ 'SigmaN' ] + arg3 = loi[ 'A' ] + arg4 = loi[ 'B' ] + txt = "TruncatedNormal( %g, %g, %g, %g )" % (arg1, arg2, arg3, arg4) + return txt + + def Poisson (self, loi, i, collection): + ''' + Definition de la loi + ''' + txt = "Poisson( %g )" % loi[ 'Lambda' ] + return txt + + def Student (self, loi, i, collection): + ''' + Definition de la loi Student + ''' + arg1 = loi[ 'Mu' ] + arg2 = loi[ 'Nu' ] + txt = "Student( %g, %g )" % (arg1, arg2) + return txt + + def Triangular (self, loi, i, collection): + ''' + Definition de la loi Triangular + ''' + arg1 = loi[ 'A' ] + arg2 = loi[ 'M' ] + arg3 = loi[ 'B' ] + txt = "Triangular( %g, %g, %g )" % (arg1, arg2, arg3) + return txt + + def Uniform (self, loi, i, collection): + ''' + Definition de la loi Uniform + ''' + arg1 = loi[ 'A' ] + arg2 = loi[ 'B' ] + txt = "Uniform( %g, %g )" % (arg1, arg2) + return txt + + def UserDefined (self, loi, i, collection): + ''' + Definition de la loi UserDefined + ''' + txt = "** UserDefined not defined yet **" + return txt + + def Weibull (self, loi, i, collection): + ''' + Definition de la loi Weibull + ''' + settings = { + "AlphaBeta" : "Weibull.ALPHABETA", + "MuSigma" : "Weibull.MUSIGMA", + } + if loi[ 'Settings' ] == 'AlphaBeta' : + arg1 = loi[ 'Alpha' ] + arg2 = loi[ 'Beta' ] + else : + arg1 = loi[ 'Mu' ] + arg2 = loi[ 'Sigma' ] + + arg3 = loi[ 'Gamma' ] + txt = "Weibull( %g, %g, %s )" % (arg1, arg2, arg3, settings[ loi[ 'Settings' ] ]) + return txt +