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230 lines
9.0 KiB
Plaintext
230 lines
9.0 KiB
Plaintext
[section:hypergeometric_dist Hypergeometric Distribution]
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``#include <boost/math/distributions/hypergeometric.hpp>``
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namespace boost{ namespace math{
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template <class RealType = double,
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class ``__Policy`` = ``__policy_class`` >
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class hypergeometric_distribution;
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template <class RealType, class Policy>
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class hypergeometric_distribution
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{
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public:
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typedef RealType value_type;
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typedef Policy policy_type;
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// Construct:
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hypergeometric_distribution(unsigned r, unsigned n, unsigned N);
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// Accessors:
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unsigned total()const;
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unsigned defective()const;
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unsigned sample_count()const;
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};
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typedef hypergeometric_distribution<> hypergeometric;
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}} // namespaces
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The hypergeometric distribution describes the number of "events" /k/
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from a sample /n/ drawn from a total population /N/ ['without replacement].
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Imagine we have a sample of /N/ objects of which /r/ are "defective"
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and N-r are "not defective"
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(the terms "success\/failure" or "red\/blue" are also used). If we sample /n/
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items /without replacement/ then what is the probability that exactly
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/k/ items in the sample are defective? The answer is given by the pdf of the
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hypergeometric distribution `f(k; r, n, N)`, whilst the probability of
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/k/ defectives or fewer is given by F(k; r, n, N), where F(k) is the
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CDF of the hypergeometric distribution.
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[note Unlike almost all of the other distributions in this library,
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the hypergeometric distribution is strictly discrete: it can not be
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extended to real valued arguments of its parameters or random variable.]
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The following graph shows how the distribution changes as the proportion
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of "defective" items changes, while keeping the population and sample sizes
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constant:
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[graph hypergeometric_pdf_1]
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Note that since the distribution is symmetrical in parameters /n/ and /r/, if we
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change the sample size and keep the population and proportion "defective" the same
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then we obtain basically the same graphs:
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[graph hypergeometric_pdf_2]
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[h4 Member Functions]
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hypergeometric_distribution(unsigned r, unsigned n, unsigned N);
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Constructs a hypergeometric distribution with a population of /N/ objects,
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of which /r/ are defective, and from which /n/ are sampled.
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unsigned total()const;
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Returns the total number of objects /N/.
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unsigned defective()const;
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Returns the number of objects /r/ in population /N/ which are defective.
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unsigned sample_count()const;
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Returns the number of objects /n/ which are sampled from the population /N/.
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[h4 Non-member Accessors]
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All the [link math_toolkit.dist_ref.nmp usual non-member accessor functions]
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that are generic to all distributions are supported: __usual_accessors.
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The domain of the random variable is the unsigned integers in the range
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\[max(0, n + r - N), min(n, r)\]. A __domain_error is raised if the
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random variable is outside this range, or is not an integral value.
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[caution
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The quantile function will by default return an integer result that has been
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/rounded outwards/. That is to say lower quantiles (where the probability is
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less than 0.5) are rounded downward, and upper quantiles (where the probability
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is greater than 0.5) are rounded upwards. This behaviour
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ensures that if an X% quantile is requested, then /at least/ the requested
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coverage will be present in the central region, and /no more than/
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the requested coverage will be present in the tails.
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This behaviour can be changed so that the quantile functions are rounded
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differently using
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[link math_toolkit.pol_overview Policies]. It is strongly
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recommended that you read the tutorial
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[link math_toolkit.pol_tutorial.understand_dis_quant
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Understanding Quantiles of Discrete Distributions] before
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using the quantile function on the Hypergeometric distribution. The
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[link math_toolkit.pol_ref.discrete_quant_ref reference docs]
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describe how to change the rounding policy
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for these distributions.
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However, note that the implementation method of the quantile function
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always returns an integral value, therefore attempting to use a __Policy
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that requires (or produces) a real valued result will result in a
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compile time error.
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] [/ caution]
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[h4 Accuracy]
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For small N such that
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`N < boost::math::max_factorial<RealType>::value` then table based
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lookup of the results gives an accuracy to a few epsilon.
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`boost::math::max_factorial<RealType>::value` is 170 at double or long double
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precision.
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For larger N such that `N < boost::math::prime(boost::math::max_prime)`
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then only basic arithmetic is required for the calculation
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and the accuracy is typically < 20 epsilon. This takes care of N
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up to 104729.
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For `N > boost::math::prime(boost::math::max_prime)` then accuracy quickly
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degrades, with 5 or 6 decimal digits being lost for N = 110000.
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In general for very large N, the user should expect to lose log[sub 10]N
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decimal digits of precision during the calculation, with the results
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becoming meaningless for N >= 10[super 15].
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[h4 Testing]
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There are three sets of tests: our implementation is tested against a table of values
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produced by Mathematica's implementation of this distribution. We also sanity check
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our implementation against some spot values computed using the online calculator
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here [@http://stattrek.com/Tables/Hypergeometric.aspx http://stattrek.com/Tables/Hypergeometric.aspx].
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Finally we test accuracy against some high precision test data using
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this implementation and NTL::RR.
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[h4 Implementation]
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The PDF can be calculated directly using the formula:
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[equation hypergeometric1]
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However, this can only be used directly when the largest of the factorials
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is guaranteed not to overflow the floating point representation used.
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This formula is used directly when `N < max_factorial<RealType>::value`
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in which case table lookup of the factorials gives a rapid and accurate
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implementation method.
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For larger /N/ the method described in
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"An Accurate Computation of the Hypergeometric Distribution Function",
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Trong Wu, ACM Transactions on Mathematical Software, Vol. 19, No. 1,
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March 1993, Pages 33-43 is used. The method relies on the fact that
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there is an easy method for factorising a factorial into the product
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of prime numbers:
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[equation hypergeometric2]
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Where p[sub i] is the i'th prime number, and e[sub i] is a small
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positive integer or zero, which can be calculated via:
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[equation hypergeometric3]
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Further we can combine the factorials in the expression for the PDF
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to yield the PDF directly as the product of prime numbers:
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[equation hypergeometric4]
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With this time the exponents e[sub i] being either positive, negative
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or zero. Indeed such a degree of cancellation occurs in the calculation
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of the e[sub i] that many are zero, and typically most have a magnitude
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or no more than 1 or 2.
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Calculation of the product of the primes requires some care to prevent
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numerical overflow, we use a novel recursive method which splits the
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calculation into a series of sub-products, with a new sub-product
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started each time the next multiplication would cause either overflow
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or underflow. The sub-products are stored in a linked list on the
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program stack, and combined in an order that will guarantee no overflow
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or unnecessary-underflow once the last sub-product has been calculated.
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This method can be used as long as N is smaller than the largest prime
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number we have stored in our table of primes (currently 104729). The method
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is relatively slow (calculating the exponents requires the most time), but
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requires only a small number of arithmetic operations to
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calculate the result (indeed there is no shorter method involving only basic
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arithmetic once the exponents have been found), the method is therefore
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much more accurate than the alternatives.
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For much larger N, we can calculate the PDF from the factorials using
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either lgamma, or by directly combining lanczos approximations to avoid
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calculating via logarithms. We use the latter method, as it is usually
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1 or 2 decimal digits more accurate than computing via logarithms with
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lgamma. However, in this area where N > 104729, the user should expect
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to lose around log[sub 10]N decimal digits during the calculation in
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the worst case.
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The CDF and its complement is calculated by directly summing the PDF's.
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We start by deciding whether the CDF, or its complement, is likely to be
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the smaller of the two and then calculate the PDF at /k/ (or /k+1/ if we're
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calculating the complement) and calculate successive PDF values via the
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recurrence relations:
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[equation hypergeometric5]
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Until we either reach the end of the distributions domain, or the next
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PDF value to be summed would be too small to affect the result.
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The quantile is calculated in a similar manner to the CDF: we first guess
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which end of the distribution we're nearer to, and then sum PDFs starting
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from the end of the distribution this time, until we have some value /k/ that
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gives the required CDF.
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The median is simply the quantile at 0.5, and the remaining properties are
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calculated via:
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[equation hypergeometric6]
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[endsect]
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[/ hypergeometric.qbk
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Copyright 2008 John Maddock.
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Distributed under the Boost Software License, Version 1.0.
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(See accompanying file LICENSE_1_0.txt or copy at
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http://www.boost.org/LICENSE_1_0.txt).
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]
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