Probability density function |
|
Cumulative distribution function |
|
| Parameters | <math>k>0\,</math> (degrees of freedom) |
|---|---|
| Support | <math>x\in [0;\infty)</math> |
| Probability density function (pdf) | <math>\frac{2^{1-k/2}x^{k-1}e^{-x^2/2 |
| Cumulative distribution function (cdf) | {{{cdf}}} |
| Mean | {{{mean}}} |
| Median | {{{median}}} |
| Mode | {{{mode}}} |
| Variance | {{{variance}}} |
| Skewness | {{{skewness}}} |
| Excess kurtosis | {{{kurtosis}}} |
| Entropy | {{{entropy}}} |
| Moment-generating function (mgf) | {{{mgf}}} |
| Characteristic function | {{{char}}} |
{\Gamma(k/2)}</math>|
cdf =<math>P(k/2,x^2/2)\,</math>|
mean =<math>\mu=\sqrt{2}\,\frac{\Gamma((k+1)/2)}{\Gamma(k/2)}</math>|
median =|
mode =<math>\sqrt{k-1}\,</math> for <math>k\ge 1</math>|
variance =<math>\sigma^2=k-\mu^2\,</math>|
skewness =<math>\gamma_1=\frac{\mu}{\sigma^3}\,(1-2\sigma^2)</math>|
kurtosis =<math>\frac{2}{\sigma^2}(1-\mu\sigma\gamma_1-\sigma^2)</math>|
entropy =<math>\ln(\Gamma(k/2))+\,</math>
<math>\frac{1}{2}(k\!-\!\ln(2)\!-\!(k\!-\!1)\psi_0(k/2))</math>|
mgf =Complicated (see text)|
char =Complicated (see text)|
}} In probability theory and statistics, the chi distribution is a continuous probability distribution. The distribution usually arises when a k-dimensional vector's orthogonal components are independent and each follow a standard normal distribution. The length of the vector will then have a chi distribution. The most familiar example is the Maxwell distribution of (normalized) molecular speeds which is a chi distribution with 3 degrees of freedom. If <math>X_i</math> are k independent, normally distributed random variables with means <math>\mu_i</math> and standard deviations <math>\sigma_i</math>, then the statistic
- <math>Z = \sqrt{\sum_1^k \left(\frac{X_i-\mu_i}{\sigma_i}\right)^2}</math>
is distributed according to the chi distribution. The chi distribution has one parameter: <math>k</math> which specifies the number of degrees of freedom (i.e. the number of <math>X_i</math>).
Contents |
Characterization
Probability density function
The probability density function is
- <math>f(x;k) = \frac{2^{1-k/2}x^{k-1}e^{-x^2/2}}{\Gamma(k/2)}</math>
where <math>\Gamma(z)</math> is the Gamma function.
Cumulative distribution function
The cumulative distribution function is given by:
- <math>F(x;k)=P(k/2,x^2/2)\,</math>
where <math>P(k,x)</math> is the regularized Gamma function.
Generating functions
Moment generating function
The moment generating function is given by:
- <math>M(t)=M\left(\frac{k}{2},\frac{1}{2},\frac{t^2}{2}\right)+</math>
- <math>t\sqrt{2}\,\frac{\Gamma((k+1)/2)}{\Gamma(k/2)}
M\left(\frac{k+1}{2},\frac{3}{2},\frac{t^2}{2}\right)</math>
Characteristic function
The characteristic function is given by:
- <math>\varphi(t;k)=M\left(\frac{k}{2},\frac{1}{2},\frac{-t^2}{2}\right)+</math>
- <math>it\sqrt{2}\,\frac{\Gamma((k+1)/2)}{\Gamma(k/2)}
M\left(\frac{k+1}{2},\frac{3}{2},\frac{-t^2}{2}\right)</math> where again, <math>M(a,b,z)</math> is Kummer's confluent hypergeometric function.
Properties
Moments
The raw moments are then given by:
- <math>\mu_j=2^{j/2}\frac{\Gamma((k+j)/2)}{\Gamma(k/2)}</math>
where <math>\Gamma(z)</math> is the Gamma function. The first few raw moments are:
- <math>\mu_1=\sqrt{2}\,\,\frac{\Gamma((k\!+\!1)/2)}{\Gamma(k/2)}</math>
- <math>\mu_2=k\,</math>
- <math>\mu_3=2\sqrt{2}\,\,\frac{\Gamma((k\!+\!3)/2)}{\Gamma(k/2)}=(k+1)\mu_1</math>
- <math>\mu_4=(k)(k+2)\,</math>
- <math>\mu_5=4\sqrt{2}\,\,\frac{\Gamma((k\!+\!5)/2)}{\Gamma(k/2)}=(k+1)(k+3)\mu_1</math>
- <math>\mu_6=(k)(k+2)(k+4)\,</math>
where the rightmost expressions are derived using the recurrence relationship for the Gamma function:
- <math>\Gamma(x+1)=x\Gamma(x)\,</math>
From these expressions we may derive the following relationships: Mean: <math>\mu=\sqrt{2}\,\,\frac{\Gamma((k+1)/2)}{\Gamma(k/2)}</math> Variance: <math>\sigma^2=k-\mu^2\,</math> Skewness: <math>\gamma_1=\frac{\mu}{\sigma^3}\,(1-2\sigma^2)</math> Kurtosis excess: <math>\gamma_2=\frac{2}{\sigma^2}(1-\mu\sigma\gamma_1-\sigma^2)</math>
Entropy
The entropy is given by:
- <math>S=\ln(\Gamma(k/2))+\frac{1}{2}(k\!-\!\ln(2)\!-\!(k\!-\!1)\psi_0(k/2))</math>
where <math>\psi_0(z)</math> is the polygamma function.
Related distributions
- If <math>X</math> is chi distributed <math>X \sim \chi_k(x)</math> then <math>X^2</math> is chi-square distributed: <math>X^2 \sim \chi^2_k</math>
- The Rayleigh distribution with <math>\sigma=1</math> is a chi distribution with two degrees of freedom.
- The Maxwell distribution for normalized molecular speeds is a chi distribution with three degrees of freedom.
- The chi distribution for <math>k=1</math> is the half-normal distribution.
| Name | Statistic |
|---|---|
| chi-square distribution | <math>\sum_1^k \left(\frac{X_i-\mu_i}{\sigma_i}\right)^2</math> |
| noncentral chi-square distribution | <math>\sum_1^k \left(\frac{X_i}{\sigma_i}\right)^2</math> |
| chi distribution | <math>\sqrt{\sum_1^k \left(\frac{X_i-\mu_i}{\sigma_i}\right)^2}</math> |
| noncentral chi distribution | <math>\sqrt{\sum_1^k \left(\frac{X_i}{\sigma_i}\right)^2}</math> |
