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In
probability theory Probability theory is the branch of mathematics concerned with probability. Although there are several different probability interpretations, probability theory treats the concept in a rigorous mathematical manner by expressing it through a set o ...
and
statistics Statistics (from German language, German: ''wikt:Statistik#German, Statistik'', "description of a State (polity), state, a country") is the discipline that concerns the collection, organization, analysis, interpretation, and presentation of ...
, the hypergeometric distribution is a
discrete probability distribution In probability theory and statistics, a probability distribution is the mathematical function that gives the probabilities of occurrence of different possible outcomes for an experiment. It is a mathematical description of a random phenomenon ...
that describes the probability of k successes (random draws for which the object drawn has a specified feature) in n draws, ''without'' replacement, from a finite
population Population typically refers to the number of people in a single area, whether it be a city or town, region, country, continent, or the world. Governments typically quantify the size of the resident population within their jurisdiction using a ...
of size N that contains exactly K objects with that feature, wherein each draw is either a success or a failure. In contrast, the
binomial distribution In probability theory and statistics, the binomial distribution with parameters ''n'' and ''p'' is the discrete probability distribution of the number of successes in a sequence of ''n'' independent experiments, each asking a yes–no quest ...
describes the probability of k successes in n draws ''with'' replacement.


Definitions


Probability mass function

The following conditions characterize the hypergeometric distribution: * The result of each draw (the elements of the population being sampled) can be classified into one of two mutually exclusive categories (e.g. Pass/Fail or Employed/Unemployed). * The probability of a success changes on each draw, as each draw decreases the population (''
sampling without replacement In statistics, a simple random sample (or SRS) is a subset of individuals (a sample) chosen from a larger set (a population) in which a subset of individuals are chosen randomly, all with the same probability. It is a process of selecting a sample ...
'' from a finite population). A
random variable A random variable (also called random quantity, aleatory variable, or stochastic variable) is a mathematical formalization of a quantity or object which depends on random events. It is a mapping or a function from possible outcomes (e.g., the po ...
X follows the hypergeometric distribution if its
probability mass function In probability and statistics, a probability mass function is a function that gives the probability that a discrete random variable is exactly equal to some value. Sometimes it is also known as the discrete density function. The probability mass ...
(pmf) is given by : p_X(k) = \Pr(X = k) = \frac, where *N is the population size, *K is the number of success states in the population, *n is the number of draws (i.e. quantity drawn in each trial), *k is the number of observed successes, *\textstyle is a
binomial coefficient In mathematics, the binomial coefficients are the positive integers that occur as coefficients in the binomial theorem. Commonly, a binomial coefficient is indexed by a pair of integers and is written \tbinom. It is the coefficient of the t ...
. The is positive when \max(0, n+K-N) \leq k \leq \min(K,n). A random variable distributed hypergeometrically with parameters N, K and n is written X \sim \operatorname(N,K,n) and has
probability mass function In probability and statistics, a probability mass function is a function that gives the probability that a discrete random variable is exactly equal to some value. Sometimes it is also known as the discrete density function. The probability mass ...
p_X(k) above.


Combinatorial identities

As required, we have : \sum_ = 1, which essentially follows from
Vandermonde's identity In combinatorics, Vandermonde's identity (or Vandermonde's convolution) is the following identity for binomial coefficients: :=\sum_^r for any nonnegative integers ''r'', ''m'', ''n''. The identity is named after Alexandre-Théophile Vandermo ...
from
combinatorics Combinatorics is an area of mathematics primarily concerned with counting, both as a means and an end in obtaining results, and certain properties of finite structures. It is closely related to many other areas of mathematics and has many appl ...
. Also note that : = ; This identity can be shown by expressing the binomial coefficients in terms of factorials and rearranging the latter, but it also follows from the symmetry of the problem. Indeed, consider two rounds of drawing without replacement. In the first round, K out of N neutral marbles are drawn from an urn without replacement and coloured green. Then the colored marbles are put back. In the second round, n marbles are drawn without replacement and colored red. Then, the number of marbles with both colors on them (that is, the number of marbles that have been drawn twice) has the hypergeometric distribution. The symmetry in K and n stems from the fact that the two rounds are independent, and one could have started by drawing n balls and colouring them red first.


Properties


Working example

The classical application of the hypergeometric distribution is sampling without replacement. Think of an
urn An urn is a vase, often with a cover, with a typically narrowed neck above a rounded body and a footed pedestal. Describing a vessel as an "urn", as opposed to a vase or other terms, generally reflects its use rather than any particular shape or ...
with two colors of
marbles A marble is a small spherical object often made from glass, clay, steel, plastic, or agate. They vary in size, and most commonly are about in diameter. These toys can be used for a variety of games called ''marbles'', as well being placed in mar ...
, red and green. Define drawing a green marble as a success and drawing a red marble as a failure (analogous to the binomial distribution). If the variable ''N'' describes the number of all marbles in the urn (see contingency table below) and ''K'' describes the number of green marbles, then ''N'' − ''K'' corresponds to the number of red marbles. In this example, ''X'' is the
random variable A random variable (also called random quantity, aleatory variable, or stochastic variable) is a mathematical formalization of a quantity or object which depends on random events. It is a mapping or a function from possible outcomes (e.g., the po ...
whose outcome is ''k'', the number of green marbles actually drawn in the experiment. This situation is illustrated by the following contingency table: Now, assume (for example) that there are 5 green and 45 red marbles in the urn. Standing next to the urn, you close your eyes and draw 10 marbles without replacement. What is the probability that exactly 4 of the 10 are green? ''Note that although we are looking at success/failure, the data are not accurately modeled by the
binomial distribution In probability theory and statistics, the binomial distribution with parameters ''n'' and ''p'' is the discrete probability distribution of the number of successes in a sequence of ''n'' independent experiments, each asking a yes–no quest ...
, because the probability of success on each trial is not the same, as the size of the remaining population changes as we remove each marble.'' This problem is summarized by the following contingency table: The probability of drawing exactly ''k'' green marbles can be calculated by the formula : P(X=k) = f(k;N,K,n) = . Hence, in this example calculate : P(X=4) = f(4;50,5,10) = = = 0.003964583\dots. Intuitively we would expect it to be even more unlikely that all 5 green marbles will be among the 10 drawn. : P(X=5) = f(5;50,5,10) = = = 0.0001189375\dots, As expected, the probability of drawing 5 green marbles is roughly 35 times less likely than that of drawing 4.


Symmetries

Swapping the roles of green and red marbles: : f(k;N,K,n) = f(n-k;N,N-K,n) Swapping the roles of drawn and not drawn marbles: : f(k;N,K,n) = f(K-k;N,K,N-n) Swapping the roles of green and drawn marbles: : f(k;N,K,n) = f(k;N,n,K) These symmetries generate the
dihedral group In mathematics, a dihedral group is the group of symmetries of a regular polygon, which includes rotations and reflections. Dihedral groups are among the simplest examples of finite groups, and they play an important role in group theory, ge ...
D_4.


Order of draws

The probability of drawing any set of green and red marbles (the hypergeometric distribution) depends only on the numbers of green and red marbles, not on the order in which they appear; i.e., it is an exchangeable distribution. As a result, the probability of drawing a green marble in the i^ draw is : P(G_i) = \frac. This is an ex ante probability—that is, it is based on not knowing the results of the previous draws.


Tail bounds

Let X \sim \operatorname(N,K,n) and p=K/N. Then for 0 < t < nK/N we can derive the following bounds: : \begin \Pr \le (p - t)n&\le e^ \le e^\\ \Pr \ge (p+t)n&\le e^ \le e^\\ \end\! where : D(a\parallel b)=a\log\frac+(1-a)\log\frac is the Kullback-Leibler divergence and it is used that D(a\parallel b) \ge 2(a-b)^2. If ''n'' is larger than ''N''/2, it can be useful to apply symmetry to "invert" the bounds, which give you the following: : \begin \Pr \le (p - t)n&\le e^ \le e^\\ \\ \Pr \ge (p+t)n&\le e^ \le e^\\ \end\!


Statistical Inference


Hypergeometric test

The hypergeometric test uses the hypergeometric distribution to measure the statistical significance of having drawn a sample consisting of a specific number of k successes (out of n total draws) from a population of size N containing K successes. In a test for over-representation of successes in the sample, the hypergeometric p-value is calculated as the probability of randomly drawing k or more successes from the population in n total draws. In a test for under-representation, the p-value is the probability of randomly drawing k or fewer successes. The test based on the hypergeometric distribution (hypergeometric test) is identical to the corresponding one-tailed version of
Fisher's exact test Fisher's exact test is a statistical significance test used in the analysis of contingency tables. Although in practice it is employed when sample sizes are small, it is valid for all sample sizes. It is named after its inventor, Ronald Fisher, a ...
. Reciprocally, the p-value of a two-sided Fisher's exact test can be calculated as the sum of two appropriate hypergeometric tests (for more information see). The test is often used to identify which sub-populations are over- or under-represented in a sample. This test has a wide range of applications. For example, a marketing group could use the test to understand their customer base by testing a set of known customers for over-representation of various demographic subgroups (e.g., women, people under 30).


Related distributions

Let X\sim\operatorname(N,K,n) and p=K/N. *If n=1 then X has a
Bernoulli distribution In probability theory and statistics, the Bernoulli distribution, named after Swiss mathematician Jacob Bernoulli,James Victor Uspensky: ''Introduction to Mathematical Probability'', McGraw-Hill, New York 1937, page 45 is the discrete probabil ...
with parameter p. *Let Y have a
binomial distribution In probability theory and statistics, the binomial distribution with parameters ''n'' and ''p'' is the discrete probability distribution of the number of successes in a sequence of ''n'' independent experiments, each asking a yes–no quest ...
with parameters n and p; this models the number of successes in the analogous sampling problem ''with'' replacement. If N and K are large compared to n, and p is not close to 0 or 1, then X and Y have similar distributions, i.e., P(X \le k) \approx P(Y \le k). *If n is large, N and K are large compared to n, and p is not close to 0 or 1, then ::P(X \le k) \approx \Phi \left( \frac \right) where \Phi is the standard normal distribution function * If the probabilities of drawing a green or red marble are not equal (e.g. because green marbles are bigger/easier to grasp than red marbles) then X has a
noncentral hypergeometric distribution In statistics, the hypergeometric distribution is the discrete probability distribution generated by picking colored balls at random from an urn without replacement. Various generalizations to this distribution exist for cases where the picking ...
* The
beta-binomial distribution In probability theory and statistics, the beta-binomial distribution is a family of discrete probability distributions on a finite support of non-negative integers arising when the probability of success in each of a fixed or known number of B ...
is a
conjugate prior In Bayesian probability theory, if the posterior distribution p(\theta \mid x) is in the same probability distribution family as the prior probability distribution p(\theta), the prior and posterior are then called conjugate distributions, and th ...
for the hypergeometric distribution. The following table describes four distributions related to the number of successes in a sequence of draws:


Multivariate hypergeometric distribution

The model of an
urn An urn is a vase, often with a cover, with a typically narrowed neck above a rounded body and a footed pedestal. Describing a vessel as an "urn", as opposed to a vase or other terms, generally reflects its use rather than any particular shape or ...
with green and red marbles can be extended to the case where there are more than two colors of marbles. If there are ''K''''i'' marbles of color ''i'' in the urn and you take ''n'' marbles at random without replacement, then the number of marbles of each color in the sample (''k''1, ''k''2,..., ''k''''c'') has the multivariate hypergeometric distribution. This has the same relationship to the
multinomial distribution In probability theory, the multinomial distribution is a generalization of the binomial distribution. For example, it models the probability of counts for each side of a ''k''-sided dice rolled ''n'' times. For ''n'' independent trials each of w ...
that the hypergeometric distribution has to the binomial distribution—the multinomial distribution is the "with-replacement" distribution and the multivariate hypergeometric is the "without-replacement" distribution. The properties of this distribution are given in the adjacent table,Duan, X. G. "Better understanding of the multivariate hypergeometric distribution with implications in design-based survey sampling." arXiv preprint arXiv:2101.00548 (2021)
(pdf)
/ref> where ''c'' is the number of different colors and N=\sum_^c K_i is the total number of marbles.


Example

Suppose there are 5 black, 10 white, and 15 red marbles in an urn. If six marbles are chosen without replacement, the probability that exactly two of each color are chosen is : P(2\text, 2\text, 2\text) = = 0.079575596816976


Occurrence and applications


Application to auditing elections

Election audits typically test a sample of machine-counted precincts to see if recounts by hand or machine match the original counts. Mismatches result in either a report or a larger recount. The sampling rates are usually defined by law, not statistical design, so for a legally defined sample size ''n'', what is the probability of missing a problem which is present in ''K'' precincts, such as a hack or bug? This is the probability that ''k'' = 0. Bugs are often obscure, and a hacker can minimize detection by affecting only a few precincts, which will still affect close elections, so a plausible scenario is for ''K'' to be on the order of 5% of ''N''. Audits typically cover 1% to 10% of precincts (often 3%), so they have a high chance of missing a problem. For example, if a problem is present in 5 of 100 precincts, a 3% sample has 86% probability that ''k'' = 0 so the problem would not be noticed, and only 14% probability of the problem appearing in the sample (positive ''k''): : \begin \Pr(X = 0) & = \frac = \frac = \frac = \frac \\ pt& = \frac = \frac = \frac = \frac = 86\% \end The sample would need 45 precincts in order to have probability under 5% that ''k'' = 0 in the sample, and thus have probability over 95% of finding the problem: : P(X = 0) = \frac = \frac = \frac = \frac = 4.6\%


Application to Texas hold'em poker

In
hold'em Texas hold 'em (also known as Texas holdem, hold 'em, and holdem) is one of the most popular variants of the card game of poker. Two cards, known as hole cards, are dealt face down to each player, and then five community cards are dealt fac ...
poker players make the best hand they can combining the two cards in their hand with the 5 cards (community cards) eventually turned up on the table. The deck has 52 and there are 13 of each suit. For this example assume a player has 2 clubs in the hand and there are 3 cards showing on the table, 2 of which are also clubs. The player would like to know the probability of one of the next 2 cards to be shown being a club to complete the
flush Flush may refer to: Places * Flush, Kansas, a community in the United States Architecture, construction and manufacturing * Flush cut, a type of cut made with a French flush-cut saw or diagonal pliers * Flush deck, in naval architecture * Fl ...
.
(Note that the probability calculated in this example assumes no information is known about the cards in the other players' hands; however, experienced poker players may consider how the other players place their bets (check, call, raise, or fold) in considering the probability for each scenario. Strictly speaking, the approach to calculating success probabilities outlined here is accurate in a scenario where there is just one player at the table; in a multiplayer game this probability might be adjusted somewhat based on the betting play of the opponents.) There are 4 clubs showing so there are 9 clubs still unseen. There are 5 cards showing (2 in the hand and 3 on the table) so there are 52-5=47 still unseen. The probability that one of the next two cards turned is a club can be calculated using hypergeometric with k=1, n=2, K=9 and N=47. (about 31.64%) The probability that both of the next two cards turned are clubs can be calculated using hypergeometric with k=2, n=2, K=9 and N=47. (about 3.33%) The probability that neither of the next two cards turned are clubs can be calculated using hypergeometric with k=0, n=2, K=9 and N=47. (about 65.03%)


See also

*
Noncentral hypergeometric distributions In statistics, the hypergeometric distribution is the discrete probability distribution generated by picking colored balls at random from an urn without replacement. Various generalizations to this distribution exist for cases where the picking ...
*
Negative hypergeometric distribution In probability theory and statistics, the negative hypergeometric distribution describes probabilities for when sampling from a finite population without replacement in which each sample can be classified into two mutually exclusive categories lik ...
*
Multinomial distribution In probability theory, the multinomial distribution is a generalization of the binomial distribution. For example, it models the probability of counts for each side of a ''k''-sided dice rolled ''n'' times. For ''n'' independent trials each of w ...
*
Sampling (statistics) In statistics, quality assurance, and survey methodology, sampling is the selection of a subset (a statistical sample) of individuals from within a statistical population to estimate characteristics of the whole population. Statisticians attempt ...
*
Generalized hypergeometric function In mathematics, a generalized hypergeometric series is a power series in which the ratio of successive coefficients indexed by ''n'' is a rational function of ''n''. The series, if convergent, defines a generalized hypergeometric function, which ...
*
Coupon collector's problem In probability theory, the coupon collector's problem describes "collect all coupons and win" contests. It asks the following question: If each box of a brand of cereals contains a coupon, and there are ''n'' different types of coupons, what is th ...
*
Geometric distribution In probability theory and statistics, the geometric distribution is either one of two discrete probability distributions: * The probability distribution of the number ''X'' of Bernoulli trials needed to get one success, supported on the set \; * ...
*
Keno Keno is a lottery-like gambling game often played at modern casinos, and also offered as a game in some lotteries. Players wager by choosing numbers ranging from 1 through (usually) 80. After all players make their wagers, 20 numbers (some va ...
*
Lady tasting tea In the design of experiments in statistics, the lady tasting tea is a randomized experiment devised by Ronald Fisher and reported in his book ''The Design of Experiments'' (1935). The experiment is the original exposition of Fisher's notion of ...


References


Citations


Sources

* * unpublished note


External links


The Hypergeometric Distribution
an
Binomial Approximation to a Hypergeometric Random Variable
by Chris Boucher,
Wolfram Demonstrations Project The Wolfram Demonstrations Project is an organized, open-source collection of small (or medium-size) interactive programs called Demonstrations, which are meant to visually and interactively represent ideas from a range of fields. It is hos ...
. * {{DEFAULTSORT:Hypergeometric Distribution Discrete distributions Factorial and binomial topics