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339 lines
13 KiB
C++
339 lines
13 KiB
C++
// inverse_chi_squared_bayes_eg.cpp
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// Copyright Thomas Mang 2011.
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// Copyright Paul A. Bristow 2011.
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// Use, modification and distribution are subject to the
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// Boost Software License, Version 1.0.
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// (See accompanying file LICENSE_1_0.txt
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// or copy at http://www.boost.org/LICENSE_1_0.txt)
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// This file is written to be included from a Quickbook .qbk document.
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// It can still be compiled by the C++ compiler, and run.
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// Any output can also be added here as comment or included or pasted in elsewhere.
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// Caution: this file contains Quickbook markup as well as code
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// and comments: don't change any of the special comment markups!
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#include <iostream>
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// using std::cout; using std::endl;
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//#define define possible error-handling macros here?
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#include "boost/math/distributions.hpp"
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// using ::boost::math::inverse_chi_squared;
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int main()
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{
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using std::cout; using std::endl;
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using ::boost::math::inverse_chi_squared;
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using ::boost::math::inverse_gamma;
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using ::boost::math::quantile;
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using ::boost::math::cdf;
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cout << "Inverse_chi_squared_distribution Bayes example: " << endl <<endl;
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cout.precision(3);
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// Examples of using the inverse_chi_squared distribution.
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//[inverse_chi_squared_bayes_eg_1
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/*`
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The scaled-inversed-chi-squared distribution is the conjugate prior distribution
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for the variance ([sigma][super 2]) parameter of a normal distribution
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with known expectation ([mu]).
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As such it has widespread application in Bayesian statistics:
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In [@http://en.wikipedia.org/wiki/Bayesian_inference Bayesian inference],
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the strength of belief into certain parameter values is
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itself described through a distribution. Parameters
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hence become themselves modelled and interpreted as random variables.
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In this worked example, we perform such a Bayesian analysis by using
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the scaled-inverse-chi-squared distribution as prior and posterior distribution
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for the variance parameter of a normal distribution.
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For more general information on Bayesian type of analyses,
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see:
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* Andrew Gelman, John B. Carlin, Hal E. Stern, Donald B. Rubin, Bayesian Data Analysis,
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2003, ISBN 978-1439840955.
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* Jim Albert, Bayesian Compution with R, Springer, 2009, ISBN 978-0387922973.
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(As the scaled-inversed-chi-squared is another parameterization of the inverse-gamma distribution,
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this example could also have used the inverse-gamma distribution).
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Consider precision machines which produce balls for a high-quality ball bearing.
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Ideally each ball should have a diameter of precisely 3000 [mu]m (3 mm).
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Assume that machines generally produce balls of that size on average (mean),
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but individual balls can vary slightly in either direction
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following (approximately) a normal distribution. Depending on various production conditions
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(e.g. raw material used for balls, workplace temperature and humidity, maintenance frequency and quality)
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some machines produce balls tighter distributed around the target of 3000 [mu]m,
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while others produce balls with a wider distribution.
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Therefore the variance parameter of the normal distribution of the ball sizes varies
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from machine to machine. An extensive survey by the precision machinery manufacturer, however,
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has shown that most machines operate with a variance between 15 and 50,
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and near 25 [mu]m[super 2] on average.
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Using this information, we want to model the variance of the machines.
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The variance is strictly positive, and therefore we look for a statistical distribution
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with support in the positive domain of the real numbers.
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Given the expectation of the normal distribution of the balls is known (3000 [mu]m),
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for reasons of conjugacy, it is customary practice in Bayesian statistics
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to model the variance to be scaled-inverse-chi-squared distributed.
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In a first step, we will try to use the survey information to model
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the general knowledge about the variance parameter of machines measured by the manufacturer.
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This will provide us with a generic prior distribution that is applicable
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if nothing more specific is known about a particular machine.
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In a second step, we will then combine the prior-distribution information in a Bayesian analysis
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with data on a specific single machine to derive a posterior distribution for that machine.
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[h5 Step one: Using the survey information.]
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Using the survey results, we try to find the parameter set
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of a scaled-inverse-chi-squared distribution
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so that the properties of this distribution match the results.
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Using the mathematical properties of the scaled-inverse-chi-squared distribution
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as guideline, we see that that both the mean and mode of the scaled-inverse-chi-squared distribution
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are approximately given by the scale parameter (s) of the distribution. As the survey machines operated at a
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variance of 25 [mu]m[super 2] on average, we hence set the scale parameter (s[sub prior]) of our prior distribution
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equal to this value. Using some trial-and-error and calls to the global quantile function, we also find that a
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value of 20 for the degrees-of-freedom ([nu][sub prior]) parameter is adequate so that
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most of the prior distribution mass is located between 15 and 50 (see figure below).
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We first construct our prior distribution using these values, and then list out a few quantiles:
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*/
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double priorDF = 20.0;
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double priorScale = 25.0;
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inverse_chi_squared prior(priorDF, priorScale);
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// Using an inverse_gamma distribution instead, we could equivalently write
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// inverse_gamma prior(priorDF / 2.0, priorScale * priorDF / 2.0);
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cout << "Prior distribution:" << endl << endl;
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cout << " 2.5% quantile: " << quantile(prior, 0.025) << endl;
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cout << " 50% quantile: " << quantile(prior, 0.5) << endl;
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cout << " 97.5% quantile: " << quantile(prior, 0.975) << endl << endl;
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//] [/inverse_chi_squared_bayes_eg_1]
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//[inverse_chi_squared_bayes_eg_output_1
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/*`This produces this output:
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Prior distribution:
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2.5% quantile: 14.6
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50% quantile: 25.9
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97.5% quantile: 52.1
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*/
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//] [/inverse_chi_squared_bayes_eg_output_1]
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//[inverse_chi_squared_bayes_eg_2
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/*`
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Based on this distribution, we can now calculate the probability of having a machine
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working with an unusual work precision (variance) at <= 15 or > 50.
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For this task, we use calls to the `boost::math::` functions `cdf` and `complement`,
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respectively, and find a probability of about 0.031 (3.1%) for each case.
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*/
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cout << " probability variance <= 15: " << boost::math::cdf(prior, 15.0) << endl;
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cout << " probability variance <= 25: " << boost::math::cdf(prior, 25.0) << endl;
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cout << " probability variance > 50: "
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<< boost::math::cdf(boost::math::complement(prior, 50.0))
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<< endl << endl;
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//] [/inverse_chi_squared_bayes_eg_2]
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//[inverse_chi_squared_bayes_eg_output_2
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/*`This produces this output:
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probability variance <= 15: 0.031
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probability variance <= 25: 0.458
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probability variance > 50: 0.0318
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*/
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//] [/inverse_chi_squared_bayes_eg_output_2]
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//[inverse_chi_squared_bayes_eg_3
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/*`Therefore, only 3.1% of all precision machines produce balls with a variance of 15 or less
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(particularly precise machines),
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but also only 3.2% of all machines produce balls
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with a variance of as high as 50 or more (particularly imprecise machines). Moreover, slightly more than
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one-half (1 - 0.458 = 54.2%) of the machines work at a variance greater than 25.
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Notice here the distinction between a
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[@http://en.wikipedia.org/wiki/Bayesian_inference Bayesian] analysis and a
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[@http://en.wikipedia.org/wiki/Frequentist_inference frequentist] analysis:
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because we model the variance as random variable itself,
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we can calculate and straightforwardly interpret probabilities for given parameter values directly,
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while such an approach is not possible (and interpretationally a strict ['must-not]) in the frequentist
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world.
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[h5 Step 2: Investigate a single machine]
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In the second step, we investigate a single machine,
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which is suspected to suffer from a major fault
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as the produced balls show fairly high size variability.
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Based on the prior distribution of generic machinery performance (derived above)
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and data on balls produced by the suspect machine, we calculate the posterior distribution for that
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machine and use its properties for guidance regarding continued machine operation or suspension.
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It can be shown that if the prior distribution
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was chosen to be scaled-inverse-chi-square distributed,
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then the posterior distribution is also scaled-inverse-chi-squared-distributed
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(prior and posterior distributions are hence conjugate).
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For more details regarding conjugacy and formula to derive the parameters set
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for the posterior distribution see
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[@http://en.wikipedia.org/wiki/Conjugate_prior Conjugate prior].
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Given the prior distribution parameters and sample data (of size n), the posterior distribution parameters
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are given by the two expressions:
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__spaces [nu][sub posterior] = [nu][sub prior] + n
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which gives the posteriorDF below, and
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__spaces s[sub posterior] = ([nu][sub prior]s[sub prior] + [Sigma][super n][sub i=1](x[sub i] - [mu])[super 2]) / ([nu][sub prior] + n)
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which after some rearrangement gives the formula for the posteriorScale below.
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Machine-specific data consist of 100 balls which were accurately measured
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and show the expected mean of 3000 [mu]m and a sample variance of 55 (calculated for a sample mean defined to be 3000 exactly).
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From these data, the prior parameterization, and noting that the term
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[Sigma][super n][sub i=1](x[sub i] - [mu])[super 2] equals the sample variance multiplied by n - 1,
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it follows that the posterior distribution of the variance parameter
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is scaled-inverse-chi-squared distribution with degrees-of-freedom ([nu][sub posterior]) = 120 and
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scale (s[sub posterior]) = 49.54.
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*/
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int ballsSampleSize = 100;
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cout <<"balls sample size: " << ballsSampleSize << endl;
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double ballsSampleVariance = 55.0;
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cout <<"balls sample variance: " << ballsSampleVariance << endl;
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double posteriorDF = priorDF + ballsSampleSize;
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cout << "prior degrees-of-freedom: " << priorDF << endl;
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cout << "posterior degrees-of-freedom: " << posteriorDF << endl;
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double posteriorScale =
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(priorDF * priorScale + (ballsSampleVariance * (ballsSampleSize - 1))) / posteriorDF;
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cout << "prior scale: " << priorScale << endl;
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cout << "posterior scale: " << posteriorScale << endl;
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/*`An interesting feature here is that one needs only to know a summary statistics of the sample
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to parameterize the posterior distribution: the 100 individual ball measurements are irrelevant,
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just knowledge of the sample variance and number of measurements is sufficient.
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*/
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//] [/inverse_chi_squared_bayes_eg_3]
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//[inverse_chi_squared_bayes_eg_output_3
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/*`That produces this output:
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balls sample size: 100
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balls sample variance: 55
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prior degrees-of-freedom: 20
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posterior degrees-of-freedom: 120
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prior scale: 25
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posterior scale: 49.5
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*/
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//] [/inverse_chi_squared_bayes_eg_output_3]
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//[inverse_chi_squared_bayes_eg_4
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/*`To compare the generic machinery performance with our suspect machine,
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we calculate again the same quantiles and probabilities as above,
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and find a distribution clearly shifted to greater values (see figure).
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[graph prior_posterior_plot]
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*/
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inverse_chi_squared posterior(posteriorDF, posteriorScale);
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cout << "Posterior distribution:" << endl << endl;
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cout << " 2.5% quantile: " << boost::math::quantile(posterior, 0.025) << endl;
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cout << " 50% quantile: " << boost::math::quantile(posterior, 0.5) << endl;
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cout << " 97.5% quantile: " << boost::math::quantile(posterior, 0.975) << endl << endl;
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cout << " probability variance <= 15: " << boost::math::cdf(posterior, 15.0) << endl;
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cout << " probability variance <= 25: " << boost::math::cdf(posterior, 25.0) << endl;
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cout << " probability variance > 50: "
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<< boost::math::cdf(boost::math::complement(posterior, 50.0)) << endl;
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//] [/inverse_chi_squared_bayes_eg_4]
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//[inverse_chi_squared_bayes_eg_output_4
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/*`This produces this output:
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Posterior distribution:
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2.5% quantile: 39.1
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50% quantile: 49.8
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97.5% quantile: 64.9
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probability variance <= 15: 2.97e-031
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probability variance <= 25: 8.85e-010
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probability variance > 50: 0.489
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*/
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//] [/inverse_chi_squared_bayes_eg_output_4]
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//[inverse_chi_squared_bayes_eg_5
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/*`Indeed, the probability that the machine works at a low variance (<= 15) is almost zero,
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and even the probability of working at average or better performance is negligibly small
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(less than one-millionth of a permille).
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On the other hand, with an almost near-half probability (49%), the machine operates in the
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extreme high variance range of > 50 characteristic for poorly performing machines.
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Based on this information the operation of the machine is taken out of use and serviced.
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In summary, the Bayesian analysis allowed us to make exact probabilistic statements about a
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parameter of interest, and hence provided us results with straightforward interpretation.
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*/
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//] [/inverse_chi_squared_bayes_eg_5]
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} // int main()
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//[inverse_chi_squared_bayes_eg_output
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/*`
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[pre
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Inverse_chi_squared_distribution Bayes example:
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Prior distribution:
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2.5% quantile: 14.6
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50% quantile: 25.9
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97.5% quantile: 52.1
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probability variance <= 15: 0.031
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probability variance <= 25: 0.458
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probability variance > 50: 0.0318
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balls sample size: 100
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balls sample variance: 55
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prior degrees-of-freedom: 20
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posterior degrees-of-freedom: 120
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prior scale: 25
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posterior scale: 49.5
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Posterior distribution:
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2.5% quantile: 39.1
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50% quantile: 49.8
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97.5% quantile: 64.9
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probability variance <= 15: 2.97e-031
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probability variance <= 25: 8.85e-010
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probability variance > 50: 0.489
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] [/pre]
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*/
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//] [/inverse_chi_squared_bayes_eg_output]
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