Noncentral t-distribution

Noncentral Student's t
Probability density function
Parameters	ν > 0 degrees of freedom $\mu \in \Re \,\!$ noncentrality parameter
Support	$x\in (-\infty ;+\infty )\,\!$
PDF	see text
CDF	see text
Mean	see text
Mode	see text
Variance	see text
Skewness	see text
Ex. kurtosis	see text

As with other noncentrality parameters, the noncentral t-distribution generalizes a probability distribution – Student's t-distribution – using a noncentrality parameter. Whereas the central distribution describes how a test statistic t is distributed when the difference tested is null, the noncentral distribution describes how t is distributed when the null is false. This leads to its use in statistics, especially calculating statistical power. The noncentral t-distribution is also known as the singly noncentral t-distribution, and in addition to its primary use in statistical inference, is also used in robust modeling for data.

Characterization

If Z is a normally distributed random variable with unit variance and zero mean, and V is a Chi-squared distributed random variable with ν degrees of freedom that is statistically independent of Z, then

T={\frac {Z+\mu }{{\sqrt {V/\nu }}}}

is a noncentral t-distributed random variable with ν degrees of freedom and noncentrality parameter μ. Note that the noncentrality parameter may be negative.

Cumulative distribution function

The cumulative distribution function of noncentral t-distribution with ν degrees of freedom and noncentrality parameter μ can be expressed as^[1]

F_{{\nu ,\mu }}(x)={\begin{cases}{\tilde {F}}_{{\nu ,\mu }}(x),&{\mbox{if }}x\geq 0;\\1-{\tilde {F}}_{{\nu ,-\mu }}(x),&{\mbox{if }}x<0,\end{cases}}

where

{\tilde {F}}_{{\nu ,\mu }}(x)=\Phi (-\mu )+{\frac {1}{2}}\sum _{{j=0}}^{\infty }\left[p_{j}I_{y}\left(j+{\frac {1}{2}},{\frac {\nu }{2}}\right)+q_{j}I_{y}\left(j+1,{\frac {\nu }{2}}\right)\right],

I_{y}\,\!(a,b)

is the regularized incomplete beta function,

y={\frac {x^{2}}{x^{2}+\nu }},

p_{j}={\frac {1}{j!}}\exp \left\{-{\frac {\mu ^{2}}{2}}\right\}\left({\frac {\mu ^{2}}{2}}\right)^{j},

q_{j}={\frac {\mu }{{\sqrt {2}}\Gamma (j+3/2)}}\exp \left\{-{\frac {\mu ^{2}}{2}}\right\}\left({\frac {\mu ^{2}}{2}}\right)^{j},

and Φ is the cumulative distribution function of the standard normal distribution.

Alternatively, the noncentral t-distribution CDF can be expressed as:

F_{v,\mu }(x)={\begin{cases}{\frac {1}{2}}\sum _{j=0}^{\infty }{\frac {1}{j!}}(-\mu {\sqrt {2}})^{j}e^{\frac {-\mu ^{2}}{2}}{\frac {\Gamma ({\frac {j+1}{2}})}{\sqrt {\pi }}}I\left({\frac {v}{v+x^{2}}};{\frac {v}{2}},{\frac {j+1}{2}}\right),&x\geq 0\\1-{\frac {1}{2}}\sum _{j=0}^{\infty }{\frac {1}{j!}}(-\mu {\sqrt {2}})^{j}e^{\frac {-\mu ^{2}}{2}}{\frac {\Gamma ({\frac {j+1}{2}})}{\sqrt {\pi }}}I\left({\frac {v}{v+x^{2}}};{\frac {v}{2}},{\frac {j+1}{2}}\right),&x<0\end{cases}}

where Γ is the gamma function and I is the regularized incomplete beta function.

Although there are other forms of the cumulative distribution function, the first form presented above is very easy to evaluate through recursive computing.^[1] In statistical software R, the cumulative distribution function is implemented as pt.

Probability density function

The probability density function (pdf) for the noncentral t-distribution with ν > 0 degrees of freedom and noncentrality parameter μ can be expressed in several forms.

The confluent hypergeometric function form of the density function is

f(x)={\frac {\nu ^{{{\frac {\nu }{2}}}}\Gamma (\nu +1)\exp \left(-{\frac {\mu ^{2}}{2}}\right)}{2^{\nu }(\nu +x^{2})^{{{\frac {\nu }{2}}}}\Gamma ({\frac {\nu }{2}})}}\left\{{\sqrt {2}}\mu x{\frac {{}_{1}F_{1}\left({\frac {\nu }{2}}+1;\,{\frac {3}{2}};\,{\frac {\mu ^{2}x^{2}}{2(\nu +x^{2})}}\right)}{(\nu +x^{2})\Gamma ({\frac {\nu +1}{2}})}}+{\frac {{}_{1}F_{1}\left({\frac {\nu +1}{2}};\,{\frac {1}{2}};\,{\frac {\mu ^{2}x^{2}}{2(\nu +x^{2})}}\right)}{{\sqrt {\nu +x^{2}}}\Gamma ({\frac {\nu }{2}}+1)}}\right\}

where ₁F₁ is a confluent hypergeometric function.

An alternative integral form is^[2]

f(x)={\frac {\nu ^{{{\frac {\nu }{2}}}}\exp \left(-{\frac {\nu \mu ^{2}}{2(x^{2}+\nu )}}\right)}{{\sqrt {\pi }}\Gamma ({\frac {\nu }{2}})2^{{{\frac {\nu -1}{2}}}}(x^{2}+\nu )^{{{\frac {\nu +1}{2}}}}}}\int _{0}^{\infty }y^{\nu }\exp \left(-{\frac {1}{2}}\left(y-{\frac {\mu x}{{\sqrt {x^{2}+\nu }}}}\right)^{2}\right)dy.

A third form of the density is obtained using its cumulative distribution functions, as follows.

f(x)={\begin{cases}{\frac {\nu }{x}}\left\{F_{{\nu +2,\mu }}\left(x{\sqrt {1+{\frac {2}{\nu }}}}\right)-F_{{\nu ,\mu }}(x)\right\},&{\mbox{if }}x\neq 0;\\{\frac {\Gamma ({\frac {\nu +1}{2}})}{{\sqrt {\pi \nu }}\Gamma ({\frac {\nu }{2}})}}\exp \left(-{\frac {\mu ^{2}}{2}}\right),&{\mbox{if }}x=0.\end{cases}}

This is the approach implemented by the dt function in R.

Differential equation

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

\left\{\begin{array}{l} \left(\nu+x^2\right)^2 f''(x)+x f'(x) \left(\nu \left(-\mu^2+2\nu+5\right)+(2\nu+5) x^2\right)+(\nu+1) f(x) \left(-\mu^2 \nu+\nu+(\nu+3) x^2\right)=0, \\[12pt] f(0)=\frac{\exp\left(-\frac{\mu^2}{2}\right) \Gamma\left(\frac{\nu +1}{2}\right)} {\sqrt{\pi} \sqrt{\nu} \Gamma\left(\frac{\nu}{2}\right)}, \\[12pt] f'(0)=-\frac{\exp\left(-\frac{\mu ^2}{2}\right) \mu}{\sqrt{2 \pi}} \end{array}\right\}

Properties

Moments of the Noncentral t-distribution

In general, the kth raw moment of the noncentral t-distribution is^[3]

{\mbox{E}}\left[T^{k}\right]={\begin{cases}\left({\frac {\nu }{2}}\right)^{{{\frac {k}{2}}}}{\frac {\Gamma \left({\frac {\nu -k}{2}}\right)}{\Gamma \left({\frac {\nu }{2}}\right)}}{\mbox{exp}}\left(-{\frac {\mu ^{2}}{2}}\right){\frac {d^{k}}{d\mu ^{k}}}{\mbox{exp}}\left({\frac {\mu ^{2}}{2}}\right),&{\mbox{if }}\nu >k;\\{\mbox{Does not exist}},&{\mbox{if }}\nu \leq k.\\\end{cases}}

In particular, the mean and variance of the noncentral t-distribution are

{\begin{aligned}{\mbox{E}}\left[T\right]&={\begin{cases}\mu {\sqrt {{\frac {\nu }{2}}}}{\frac {\Gamma ((\nu -1)/2)}{\Gamma (\nu /2)}},&{\mbox{if }}\nu >1;\\{\mbox{Does not exist}},&{\mbox{if }}\nu \leq 1,\\\end{cases}}\\{\mbox{Var}}\left[T\right]&={\begin{cases}{\frac {\nu (1+\mu ^{2})}{\nu -2}}-{\frac {\mu ^{2}\nu }{2}}\left({\frac {\Gamma ((\nu -1)/2)}{\Gamma (\nu /2)}}\right)^{2},&{\mbox{if }}\nu >2;\\{\mbox{Does not exist}},&{\mbox{if }}\nu \leq 2.\\\end{cases}}\end{aligned}}

An excellent approximation to ${\sqrt {{\frac {\nu }{2}}}}{\frac {\Gamma ((\nu -1)/2)}{\Gamma (\nu /2)}}$ is $\left(1-{\frac {3}{4\nu -1}}\right)^{{-1}}$ , which can be used in both formulas.

Asymmetry

The noncentral t-distribution is asymmetric unless μ is zero, i.e., a central t-distribution. The right tail will be heavier than the left when μ > 0, and vice versa. However, the usual skewness is not generally a good measure of asymmetry for this distribution, because if the degrees of freedom is not larger than 3, the third moment does not exist at all. Even if the degrees of freedom is greater than 3, the sample estimate of the skewness is still very unstable unless the sample size is very large.

Mode

The noncentral t-distribution is always unimodal and bell shaped, but the mode is not analytically available, although for μ ≠ 0 we have^[4]

{\sqrt {\frac {\nu }{\nu +(5/2)}}}<{\frac {\mathrm {mode} }{\mu }}<{\sqrt {\frac {\nu }{\nu +1}}}

In particular, the mode always has the same sign as the noncentrality parameter μ. Moreover, the negative of the mode is exactly the mode for a noncentral t-distribution with the same number of degrees of freedom ν but noncentrality parameter −μ.

The mode is strictly increasing with μ when μ > 0 and strictly decreasing with μ when μ < 0. In the limit, when μ → 0, the mode is approximated by

{\sqrt {{\frac {\nu }{2}}}}{\frac {\Gamma \left({\frac {\nu +2}{2}}\right)}{\Gamma \left({\frac {\nu +3}{2}}\right)}}\mu ;\,

and when μ → ∞, the mode is approximated by

{\sqrt {{\frac {\nu }{\nu +1}}}}\mu .

Occurrences

Use in power analysis

Suppose we have an independent and identically distributed sample X₁, ..., X_n each of which is normally distributed with mean θ and variance σ², and we are interested in testing the null hypothesis θ = 0 vs. the alternative hypothesis θ ≠ 0. We can perform a one sample t-test using the test statistic

T={\frac {\bar {X}}{{\hat {\sigma }}/{\sqrt {n}}}}={\frac {{\frac {{\bar {X}}-\theta }{(\sigma /{\sqrt {n}})}}+{\frac {\theta }{(\sigma /{\sqrt {n}})}}}{\sqrt {\left.\left({\frac {{\hat {\sigma }}^{2}}{\sigma ^{2}/(n-1)}}\right)\right/(n-1)}}}

where ${\bar {X}}$ is the sample mean and ${\hat {\sigma }}^{2}\,\!$ is the unbiased sample variance. Since the right hand side of the second equality exactly matches the characterization of a noncentral t-distribution as described above, T has a noncentral t-distribution with n−1 degrees of freedom and noncentrality parameter ${\sqrt {n}}\theta /\sigma \,\!$ .

If the test procedure rejects the null hypothesis whenever $|T|>t_{{1-\alpha /2}}\,\!$ , where $t_{{1-\alpha /2}}\,\!$ is the upper α/2 quantile of the (central) Student's t-distribution for a pre-specified α ∈ (0, 1), then the power of this test is given by

1-F_{{n-1,{\sqrt {n}}\theta /\sigma }}(t_{{1-\alpha /2}})+F_{{n-1,{\sqrt {n}}\theta /\sigma }}(-t_{{1-\alpha /2}}).

Similar applications of the noncentral t-distribution can be found in the power analysis of the general normal-theory linear models, which includes the above one sample t-test as a special case.

Use in tolerance intervals

One-sided normal tolerance intervals have an exact solution in terms of the sample mean and sample variance based on the noncentral t-distribution.^[5] This enables the calculation of a statistical interval within which, with some confidence level, a specified proportion of a sampled population falls.

Related distributions

Central t-distribution: the central t-distribution can be converted into a location/scale family. This family of distributions is used in data modeling to capture various tail behaviors. The location/scale generalization of the central t-distribution is a different distribution from the noncentral t-distribution discussed in this article. In particular, this approximation does not respect the asymmetry of the noncentral t-distribution. However, the central t-distribution can be used as an approximation to the noncentral t-distribution.^[6]
If T is noncentral t-distributed with ν degrees of freedom and noncentrality parameter μ and F = T², then F has a noncentral F-distribution with 1 numerator degree of freedom, ν denominator degrees of freedom, and noncentrality parameter μ².
If T is noncentral t-distributed with ν degrees of freedom and noncentrality parameter μ and $Z=\lim _{{\nu \rightarrow \infty }}T$ , then Z has a normal distribution with mean μ and unit variance.
When the denominator noncentrality parameter of a doubly noncentral t-distribution is zero, then it becomes a noncentral t-distribution.

Special cases

When μ = 0, the noncentral t-distribution becomes the central (Student's) t-distribution with the same degrees of freedom.

References

1 2 Lenth, Russell V (1989). "Algorithm AS 243: Cumulative Distribution Function of the Non-central t Distribution". Journal of the Royal Statistical Society, Series C. 38: 185–189. JSTOR 2347693.
↑ L. Scharf, Statistical Signal Processing, (Massachusetts: Addison-Wesley, 1991), p.177.
↑ Hogben, D; Wilk, MB (1961). "The moments of the non-central t-distribution". Biometrika. 48: 465–468. doi:10.1093/biomet/48.3-4.465. JSTOR 2332772.
↑ van Aubel, A; Gawronski, W (2003). "Analytic properties of noncentral distributions". Applied Mathematics and Computation. 141: 3–12. doi:10.1016/S0096-3003(02)00316-8.
↑ 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.23
↑ Helena Chmura Kraemer; Minja Paik (1979). "A Central t Approximation to the Noncentral t Distribution". Technometrics. 21 (3): 357–360. doi:10.1080/00401706.1979.10489781. JSTOR 1267759.

External links

Eric W. Weisstein. "Noncentral Student's t-Distribution." From MathWorld—A Wolfram Web Resource
High accuracy calculation for life or science.: Noncentral t-distribution From Casio company.

Probability distributions

List

Discrete univariate with finite support	Benford Bernoulli beta-binomial binomial categorical hypergeometric Poisson binomial Rademacher discrete uniform Zipf Zipf–Mandelbrot

Discrete univariate with infinite support	beta negative binomial Borel Conway–Maxwell–Poisson discrete phase-type Delaporte extended negative binomial Gauss–Kuzmin geometric logarithmic negative binomial parabolic fractal Poisson Skellam Yule–Simon zeta

Continuous univariate supported on a bounded interval	arcsine ARGUS Balding–Nichols Bates beta beta rectangular Irwin–Hall Kumaraswamy logit-normal noncentral beta raised cosine reciprocal triangular U-quadratic uniform Wigner semicircle

Continuous univariate supported on a semi-infinite interval	Benini Benktander 1st kind Benktander 2nd kind beta prime Burr chi-squared chi Dagum Davis exponential-logarithmic Erlang exponential F folded normal Flory–Schulz Fréchet gamma gamma/Gompertz generalized inverse Gaussian Gompertz half-logistic half-normal Hotelling's T-squared hyper-Erlang hyperexponential hypoexponential inverse chi-squared scaled inverse chi-squared inverse Gaussian inverse gamma Kolmogorov Lévy log-Cauchy log-Laplace log-logistic log-normal Lomax matrix-exponential Maxwell–Boltzmann Maxwell–Jüttner Mittag-Leffler Nakagami noncentral chi-squared Pareto phase-type poly-Weibull Rayleigh relativistic Breit–Wigner Rice shifted Gompertz truncated normal type-2 Gumbel Weibull Discrete Weibull Wilks's lambda

Continuous univariate supported on the whole real line	Cauchy exponential power Fisher's z Gaussian q generalized normal generalized hyperbolic geometric stable Gumbel Holtsmark hyperbolic secant Johnson's S_U Landau Laplace asymmetric Laplace logistic noncentral t normal (Gaussian) normal-inverse Gaussian skew normal slash stable Student's t type-1 Gumbel Tracy–Widom variance-gamma Voigt

Continuous univariate with support whose type varies	generalized extreme value generalized Pareto Tukey lambda q-Gaussian q-exponential q-Weibull shifted log-logistic

Mixed continuous-discrete univariate	rectified Gaussian

Multivariate (joint)	Discrete Ewens multinomial Dirichlet-multinomial negative multinomial Continuous Dirichlet generalized Dirichlet multivariate normal multivariate stable multivariate t normal-inverse-gamma normal-gamma Matrix-valued inverse matrix gamma inverse-Wishart matrix normal matrix t matrix gamma normal-inverse-Wishart normal-Wishart Wishart

Directional	Univariate (circular) directional Circular uniform univariate von Mises wrapped normal wrapped Cauchy wrapped exponential wrapped asymmetric Laplace wrapped Lévy Bivariate (spherical) Kent Bivariate (toroidal) bivariate von Mises Multivariate von Mises–Fisher Bingham

Degenerate and singular	Degenerate Dirac delta function Singular Cantor

Families	Circular compound Poisson elliptical exponential natural exponential location-scale maximum entropy mixture Pearson Tweedie wrapped

Some common univariate probability distributions

Continuous	beta Cauchy chi-squared exponential F gamma Laplace log-normal normal Pareto Student's t uniform Weibull

Discrete	Bernoulli binomial discrete uniform geometric hypergeometric negative binomial Poisson

List of probability distributions

Statistics

Descriptive statistics

Continuous data

Center	Mean arithmetic geometric harmonic Median Mode

Dispersion	Variance Standard deviation Coefficient of variation Percentile Range Interquartile range

Shape	Moments Skewness Kurtosis L-moments

Count data

Index of dispersion

Summary tables

Dependence

Graphics

Data collection

Study design	Population Statistic Effect size Statistical power Sample size determination Missing data

Survey methodology	Sampling Standard error stratified cluster Opinion poll Questionnaire

Controlled experiments	Design control optimal Controlled trial Randomized Random assignment Replication Blocking Interaction Factorial experiment

Uncontrolled studies	Observational study Natural experiment Quasi-experiment

Statistical inference

Statistical theory

Frequentist inference

Point estimation	Estimating equations Maximum likelihood Method of moments M-estimator Minimum distance Unbiased estimators Mean-unbiased minimum-variance Rao–Blackwellization Lehmann–Scheffé theorem Median unbiased Plug-in

Interval estimation	Confidence interval Pivot Likelihood interval Prediction interval Tolerance interval Resampling Bootstrap Jackknife

Testing hypotheses	1- & 2-tails Power Uniformly most powerful test Permutation test Randomization test Multiple comparisons

Parametric tests	Likelihood-ratio Wald Score

Specific tests

Z (normal) Student's t-test F

Goodness of fit	Chi-squared Kolmogorov–Smirnov Anderson–Darling Normality (Shapiro–Wilk) Likelihood-ratio test Model selection Cross validation AIC BIC

Rank statistics	Sign Sample median Signed rank (Wilcoxon) Hodges–Lehmann estimator Rank sum (Mann–Whitney) Nonparametric anova 1-way (Kruskal–Wallis) 2-way (Friedman) Ordered alternative (Jonckheere–Terpstra)

Bayesian inference

Correlation	Pearson product–moment Partial correlation Confounding variable Coefficient of determination

Regression analysis	Errors and residuals Regression model validation Mixed effects models Simultaneous equations models Multivariate adaptive regression splines (MARS)

Linear regression	Simple linear regression Ordinary least squares General linear model Bayesian regression

Non-standard predictors	Nonlinear regression Nonparametric Semiparametric Isotonic Robust Heteroscedasticity Homoscedasticity

Generalized linear model	Exponential families Logistic (Bernoulli) / Binomial / Poisson regressions

Partition of variance	Analysis of variance (ANOVA, anova) Analysis of covariance Multivariate ANOVA Degrees of freedom

Categorical / Multivariate / Time-series / Survival analysis

Categorical

Multivariate

Time-series

General	Decomposition Trend Stationarity Seasonal adjustment Exponential smoothing Cointegration Structural break Granger causality

Specific tests	Dickey–Fuller Johansen Q-statistic (Ljung–Box) Durbin–Watson Breusch–Godfrey

Time domain	Autocorrelation (ACF) partial (PACF) Cross-correlation (XCF) ARMA model ARIMA model (Box–Jenkins) Autoregressive conditional heteroskedasticity (ARCH) Vector autoregression (VAR)

Frequency domain	Spectral density estimation Fourier analysis Wavelet

Survival

Survival function	Kaplan–Meier estimator (product limit) Proportional hazards models Accelerated failure time (AFT) model First hitting time

Hazard function	Nelson–Aalen estimator

Test	Log-rank test

Applications

Biostatistics	Bioinformatics Clinical trials / studies Epidemiology Medical statistics

Engineering statistics	Chemometrics Methods engineering Probabilistic design Process / quality control Reliability System identification

Social statistics	Actuarial science Census Crime statistics Demography Econometrics National accounts Official statistics Population statistics Psychometrics

Spatial statistics	Cartography Environmental statistics Geographic information system Geostatistics Kriging

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