示例#1
0
import openturns as ot
from matplotlib import pyplot as plt
from openturns.viewer import View
if ot.Burr().__class__.__name__ == 'ComposedDistribution':
    correlation = ot.CorrelationMatrix(2)
    correlation[1, 0] = 0.25
    aCopula = ot.NormalCopula(correlation)
    marginals = [ot.Normal(1.0, 2.0), ot.Normal(2.0, 3.0)]
    distribution = ot.ComposedDistribution(marginals, aCopula)
elif ot.Burr().__class__.__name__ == 'CumulativeDistributionNetwork':
    distribution = ot.CumulativeDistributionNetwork([ot.Normal(2),ot.Dirichlet([0.5, 1.0, 1.5])], ot.BipartiteGraph([[0,1], [0,1]]))
elif ot.Burr().__class__.__name__ == 'Histogram':
    distribution = ot.Histogram([-1.0, 0.5, 1.0, 2.0], [0.45, 0.4, 0.15])
else:
    distribution = ot.Burr()
dimension = distribution.getDimension()
if dimension == 1:
    distribution.setDescription(['$x$'])
    pdf_graph = distribution.drawPDF()
    cdf_graph = distribution.drawCDF()
    fig = plt.figure(figsize=(10, 4))
    plt.suptitle(str(distribution))
    pdf_axis = fig.add_subplot(121)
    cdf_axis = fig.add_subplot(122)
    View(pdf_graph, figure=fig, axes=[pdf_axis], add_legend=False)
    View(cdf_graph, figure=fig, axes=[cdf_axis], add_legend=False)
elif dimension == 2:
    distribution.setDescription(['$x_1$', '$x_2$'])
    pdf_graph = distribution.drawPDF()
    fig = plt.figure(figsize=(10, 5))
    plt.suptitle(str(distribution))
示例#2
0
文件: Burr.py 项目: vchabri/openturns 
import openturns as ot
from matplotlib import pyplot as plt
from openturns.viewer import View

pdf_graph = ot.Graph('PDF graph', 'x', 'PDF', True, 'topleft')
cdf_graph = ot.Graph('CDF graph', 'x', 'CDF', True, 'topleft')
palette = ot.Drawable.BuildDefaultPalette(10)
for i, p in enumerate([(1, 1), (1, 2), (1, 3), (2, 1), (3, 1), (0.5, 2)]):
    c, k = p
    distribution = ot.Burr(c, k)
    pdf_curve = distribution.drawPDF().getDrawable(0)
    cdf_curve = distribution.drawCDF().getDrawable(0)
    pdf_curve.setColor(palette[i])
    cdf_curve.setColor(palette[i])
    pdf_curve.setLegend('c,k={},{}'.format(c, k))
    cdf_curve.setLegend('c,k={},{}'.format(c, k))
    pdf_graph.add(pdf_curve)
    cdf_graph.add(cdf_curve)
fig = plt.figure(figsize=(10, 4))
pdf_axis = fig.add_subplot(121)
cdf_axis = fig.add_subplot(122)
View(pdf_graph, figure=fig, axes=[pdf_axis], add_legend=True)
View(cdf_graph, figure=fig, axes=[cdf_axis], add_legend=True)
fig.suptitle('Burr(c, k)')
示例#3
0
#! /usr/bin/env python

from __future__ import print_function
import openturns as ot

ot.TESTPREAMBLE()

try:
    distribution = ot.Burr(2.5, 1.5)
    size = 10000
    sample = distribution.getSample(size)
    factory = ot.BurrFactory()
    estimatedDistribution = factory.build(sample)
    print("distribution=", repr(distribution))
    print("Estimated distribution=", repr(estimatedDistribution))
    estimatedDistribution = factory.build()
    print("Default distribution=", estimatedDistribution)
    estimatedDistribution = factory.build(distribution.getParameter())
    print("Distribution from parameters=", estimatedDistribution)
    estimatedBurr = factory.buildAsBurr(sample)
    print("Burr          =", distribution)
    print("Estimated burr=", estimatedBurr)
    estimatedBurr = factory.buildAsBurr()
    print("Default burr=", estimatedBurr)
    estimatedBurr = factory.buildAsBurr(distribution.getParameter())
    print("Burr from parameters=", estimatedBurr)

    try:
        estimatedBurr = factory.build(ot.Normal(1e-3, 1e-5).getSample(100))
        print('Estimated burr=', estimatedBurr)
    except:
示例#4
0
import openturns as ot
from matplotlib import pyplot as plt
from openturns.viewer import View
if (ot.Burr().__class__.__name__ == 'ComposedDistribution'):
    correlation = ot.CorrelationMatrix(2)
    correlation[1, 0] = 0.25
    aCopula = ot.NormalCopula(correlation)
    marginals = [ot.Normal(1.0, 2.0), ot.Normal(2.0, 3.0)]
    distribution = ot.ComposedDistribution(marginals, aCopula)
elif (ot.Burr().__class__.__name__ == 'CumulativeDistributionNetwork'):
    distribution = ot.CumulativeDistributionNetwork(
        [ot.Normal(2), ot.Dirichlet([0.5, 1.0, 1.5])],
        ot.BipartiteGraph([[0, 1], [0, 1]]))
else:
    distribution = ot.Burr()
dimension = distribution.getDimension()
if dimension <= 2:
    if distribution.getDimension() == 1:
        distribution.setDescription(['$x$'])
        pdf_graph = distribution.drawPDF()
        cdf_graph = distribution.drawCDF()
        fig = plt.figure(figsize=(10, 4))
        plt.suptitle(str(distribution))
        pdf_axis = fig.add_subplot(121)
        cdf_axis = fig.add_subplot(122)
        View(pdf_graph, figure=fig, axes=[pdf_axis], add_legend=False)
        View(cdf_graph, figure=fig, axes=[cdf_axis], add_legend=False)
    else:
        distribution.setDescription(['$x_1$', '$x_2$'])
        pdf_graph = distribution.drawPDF()
        fig = plt.figure(figsize=(10, 5))