#! /usr/bin/env python from __future__ import print_function from openturns import * TESTPREAMBLE() RandomGenerator.SetSeed(0) try: allDistributions = [InverseGamma(5.5, 2.5), InverseGamma(15.0, 2.5)] for n in range(len(allDistributions)): distribution = allDistributions[n] print("Distribution ", distribution) # Is this distribution elliptical ? print("Elliptical = ", distribution.isElliptical()) # Is this distribution continuous ? print("Continuous = ", distribution.isContinuous()) # Test for realization of distribution oneRealization = distribution.getRealization() print("oneRealization=", oneRealization) # Test for sampling size = 10000 oneSample = distribution.getSample(size) print("oneSample first=", oneSample[0], " last=", oneSample[size - 1]) print("mean=", oneSample.computeMean()) print("covariance=", oneSample.computeCovariance()) size = 100 for i in range(2): if FittingTest.Kolmogorov(distribution.getSample(size), distribution).getBinaryQualityMeasure(): msg = "accepted" else: msg = "rejected" print( "Kolmogorov test for the generator, sample size=", size, " is ", msg) size *= 10 # Define a point point = NumericalPoint( distribution.getDimension(), 2.0 / (distribution.getK() * distribution.getLambda())) print("Point= ", point) # Show PDF and CDF of point eps = 1e-5 DDF = distribution.computeDDF(point) print("ddf =", DDF) print("ddf (FD)=%.6g" % ((distribution.computePDF(point + NumericalPoint(1, eps)) - distribution.computePDF(point + NumericalPoint(1, -eps))) / (2.0 * eps))) LPDF = distribution.computeLogPDF(point) print("log pdf= %.12g" % LPDF) PDF = distribution.computePDF(point) print("pdf =%.6g" % PDF) print("pdf (FD)=%.6g" % ((distribution.computeCDF(point + NumericalPoint(1, eps)) - distribution.computeCDF(point + NumericalPoint(1, -eps))) / (2.0 * eps))) CDF = distribution.computeCDF(point) print("cdf= %.12g" % CDF) CCDF = distribution.computeComplementaryCDF(point) print("ccdf= %.12g" % CCDF) Survival = distribution.computeSurvivalFunction(point) print("survival= %.12g" % Survival) CF = distribution.computeCharacteristicFunction(point[0]) print("characteristic function=(%.6g, %.6g)" % (CF.real, CF.imag)) LCF = distribution.computeLogCharacteristicFunction(point[0]) print("log characteristic function=(%.6g, %.6g)" % (LCF.real, LCF.imag)) PDFgr = distribution.computePDFGradient(point) print("pdf gradient =", PDFgr) PDFgrFD = NumericalPoint(2) PDFgrFD[0] = (InverseGamma(distribution.getK() + eps, distribution.getLambda()).computePDF(point) - InverseGamma(distribution.getK() - eps, distribution.getLambda()).computePDF(point)) / (2.0 * eps) PDFgrFD[1] = (InverseGamma(distribution.getK(), distribution.getLambda() + eps).computePDF(point) - InverseGamma(distribution.getK(), distribution.getLambda() - eps).computePDF(point)) / (2.0 * eps) print("pdf gradient (FD)=", PDFgrFD) CDFgr = distribution.computeCDFGradient(point) print("cdf gradient =", CDFgr) CDFgrFD = NumericalPoint(2) CDFgrFD[0] = (InverseGamma(distribution.getK() + eps, distribution.getLambda()).computeCDF(point) - InverseGamma(distribution.getK() - eps, distribution.getLambda()).computeCDF(point)) / (2.0 * eps) CDFgrFD[1] = (InverseGamma(distribution.getK(), distribution.getLambda() + eps).computeCDF(point) - InverseGamma(distribution.getK(), distribution.getLambda() - eps).computeCDF(point)) / (2.0 * eps) print("cdf gradient (FD)=", CDFgrFD) quantile = distribution.computeQuantile(0.95) print("quantile=", quantile) print("cdf(quantile)= %.2f" % distribution.computeCDF(quantile)) mean = distribution.getMean() print("mean=", mean) covariance = distribution.getCovariance() print("covariance=", covariance) correlation = distribution.getCorrelation() print("correlation=", correlation) spearman = distribution.getSpearmanCorrelation() print("spearman=", spearman) kendall = distribution.getKendallTau() print("kendall=", kendall) parameters = distribution.getParametersCollection() print("parameters=", parameters) for i in range(6): print("standard moment n=", i, ", value=", distribution.getStandardMoment(i)) print("Standard representative=", distribution.getStandardRepresentative()) standardDeviation = distribution.getStandardDeviation() print("standard deviation=", standardDeviation) skewness = distribution.getSkewness() print("skewness=", skewness) kurtosis = distribution.getKurtosis() print("kurtosis=", kurtosis) except: import sys print("InverseGamma.py", sys.exc_info()[0], sys.exc_info()[1])