Noncentral chi-squared distribution

Noncentral chi-squared
Probability density function

Cumulative distribution function

Parameters

degrees of freedom

non-centrality parameter
Support
PDF
CDF with Marcum Q-function
Mean
Variance
Skewness
Ex. kurtosis
MGF
CF

In probability theory and statistics, the noncentral chi-squared or noncentral distribution is a generalization of the chi-squared distribution. This distribution often arises in the power analysis of statistical tests in which the null distribution is (perhaps asymptotically) a chi-squared distribution; important examples of such tests are the likelihood ratio tests.

Background

Let (, ) be k independent, normally distributed random variables with means and unit variances. Then the random variable

is distributed according to the noncentral chi-squared distribution. It has two parameters: which specifies the number of degrees of freedom (i.e. the number of ), and which is related to the mean of the random variables by:

is sometimes called the noncentrality parameter. Note that some references define in other ways, such as half of the above sum, or its square root.

This distribution arises in multivariate statistics as a derivative of the multivariate normal distribution. While the central chi-squared distribution is the squared norm of a random vector with distribution (i.e., the squared distance from the origin of a point taken at random from that distribution), the non-central is the squared norm of a random vector with distribution. Here is a zero vector of length k, and is the identity matrix of size k.

Definition

The probability density function (pdf) is given by

where is distributed as chi-squared with degrees of freedom.

From this representation, the noncentral chi-squared distribution is seen to be a Poisson-weighted mixture of central chi-squared distributions. Suppose that a random variable J has a Poisson distribution with mean , and the conditional distribution of Z given is chi-squared with k+2i degrees of freedom. Then the unconditional distribution of Z is non-central chi-squared with k degrees of freedom, and non-centrality parameter .

Alternatively, the pdf can be written as

where is a modified Bessel function of the first kind given by

Using the relation between Bessel functions and hypergeometric functions, the pdf can also be written as:[1]

Siegel (1979) discusses the case k = 0 specifically (zero degrees of freedom), in which case the distribution has a discrete component at zero.

Properties

Moment generating function

The moment generating function is given by

Moments

The first few raw moments are:

The first few central moments are:

The nth cumulant is

Hence

Cumulative distribution function

Again using the relation between the central and noncentral chi-squared distributions, the cumulative distribution function (cdf) can be written as

where is the cumulative distribution function of the central chi-squared distribution with k degrees of freedom which is given by

and where is the lower incomplete Gamma function.

The Marcum Q-function can also be used to represent the cdf.[2]

Approximation

Sankaran [3] discusses a number of closed form approximations for the cumulative distribution function. In an earlier paper,[4] he derived and states the following approximation:

where

denotes the cumulative distribution function of the standard normal distribution;

This and other approximations are discussed in a later text book.[5]

To approximate the chi-squared distribution, the non-centrality parameter, , is set to zero, yielding

essentially approximating the normalized chi-squared distribution X / k as the cube of a Gaussian.

For a given probability, the formula is easily inverted to provide the corresponding approximation for .

Differential equation

The pdf of the noncentral chi-squared distribution is a solution of the following differential equation:

Derivation of the pdf

The derivation of the probability density function is most easily done by performing the following steps:

  1. First, assume without loss of generality that . Then the joint distribution of is spherically symmetric, up to a location shift.
  2. The spherical symmetry then implies that the distribution of depends on the means only through the squared length, . Without loss of generality, we can therefore take and .
  3. Now derive the density of (i.e. the k = 1 case). Simple transformation of random variables shows that
where is the standard normal density.
  1. Expand the cosh term in a Taylor series. This gives the Poisson-weighted mixture representation of the density, still for k = 1. The indices on the chi-squared random variables in the series above are 1 + 2i in this case.
  2. Finally, for the general case. We've assumed, without loss of generality, that are standard normal, and so has a central chi-squared distribution with (k  1) degrees of freedom, independent of . Using the poisson-weighted mixture representation for , and the fact that the sum of chi-squared random variables is also chi-squared, completes the result. The indices in the series are (1 + 2i) + (k  1) = k + 2i as required.

Transformations

Sankaran (1963) discusses the transformations of the form . He analyzes the expansions of the cumulants of up to the term and shows that the following choices of produce reasonable results:

Also, a simpler transformation can be used as a variance stabilizing transformation that produces a random variable with mean and variance .

Usability of these transformations may be hampered by the need to take the square roots of negative numbers.

Various chi and chi-squared distributions
Name Statistic
chi-squared distribution
noncentral chi-squared distribution
chi distribution
noncentral chi distribution

Occurrences

Use in tolerance intervals

Two-sided normal regression tolerance intervals can be obtained based on the noncentral chi-squared distribution.[7] This enables the calculation of a statistical interval within which, with some confidence level, a specified proportion of a sampled population falls.

Notes

  1. Muirhead (2005) Theorem 1.3.4
  2. Nuttall, Albert H. (1975): Some Integrals Involving the QM Function, IEEE Transactions on Information Theory, 21(1), 95–96, ISSN 0018-9448
  3. Sankaran , M. (1963). Approximations to the non-central chi-squared distribution Biometrika, 50(1-2), 199204
  4. Sankaran , M. (1959). "On the non-central chi-squared distribution", Biometrika 46, 235237
  5. Johnson et al. (1995) "Continuous Univariate Distributions" Section 29.8
  6. Muirhead (2005) pages 2224 and problem 1.18.
  7. Derek S. Young (August 2010). "tolerance: An R Package for Estimating Tolerance Intervals". Journal of Statistical Software. 36 (5): 1–39. ISSN 1548-7660. Retrieved 19 February 2013., p.32

References

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