Normal-gamma distribution

normal-gamma
Parameters	$\mu \,$ location (real) $\lambda >0\,$ (real) $\alpha >0\,$ (real) $\beta >0\,$ (real)
Support	$x\in (-\infty ,\infty )\,\!,\;\tau \in (0,\infty )$
PDF	$f(x,\tau \|\mu ,\lambda ,\alpha ,\beta )={\frac {\beta ^{\alpha }{\sqrt {\lambda }}}{\Gamma (\alpha ){\sqrt {2\pi }}}}\,\tau ^{{\alpha -{\frac {1}{2}}}}\,e^{{-\beta \tau }}\,e^{{-{\frac {\lambda \tau (x-\mu )^{2}}{2}}}}$
Mean	^[1] $\operatorname {E}(X)=\mu \,\!,\quad \operatorname {E}(\mathrm{T} )=\alpha \beta ^{{-1}}$
Mode	$\left(\mu ,{\frac {\alpha -{\frac 12}}{\beta }}\right)$
Variance	^[1] $\operatorname {var}(X)={\frac {\beta }{\lambda (\alpha -1)}},\quad \operatorname {var}(\mathrm{T} )=\alpha \beta ^{{-2}}$

In probability theory and statistics, the normal-gamma distribution (or Gaussian-gamma distribution) is a bivariate four-parameter family of continuous probability distributions. It is the conjugate prior of a normal distribution with unknown mean and precision.^[2]

Definition

For a pair of random variables, (X,T), suppose that the conditional distribution of X given T is given by

X|T\sim N(\mu ,1/(\lambda T))\,\!,

meaning that the conditional distribution is a normal distribution with mean $\mu$ and precision $\lambda T$ — equivalently, with variance $1/(\lambda T).$

Suppose also that the marginal distribution of T is given by

T|\alpha ,\beta \sim {\mathrm {Gamma}}(\alpha ,\beta )\!,

where this means that T has a gamma distribution. Here λ, α and β are parameters of the joint distribution.

Then (X,T) has a normal-gamma distribution, and this is denoted by

(X,T)\sim {\mathrm {NormalGamma}}(\mu ,\lambda ,\alpha ,\beta )\!.

Properties

Probability density function

The joint probability density function of (X,T) is

f(x,\tau |\mu ,\lambda ,\alpha ,\beta )={\frac {\beta ^{\alpha }{\sqrt {\lambda }}}{\Gamma (\alpha ){\sqrt {2\pi }}}}\,\tau ^{{\alpha -{\frac {1}{2}}}}\,e^{{-\beta \tau }}\,e^{{-{\frac {\lambda \tau (x-\mu )^{2}}{2}}}}

Marginal distributions

By construction, the marginal distribution over $\tau$ is a gamma distribution, and the conditional distribution over $x$ given $\tau$ is a Gaussian distribution. The marginal distribution over $x$ is a three-parameter non-standardized Student's t-distribution with parameters $(\nu ,\mu ,\sigma ^{2})=(2\alpha ,\mu ,\beta /(\lambda \alpha ))$ .

Exponential family

The normal-gamma distribution is a four-parameter exponential family with natural parameters $\alpha -1/2,-\beta -\lambda \mu ^{2}/2,\lambda \mu ,-\lambda /2$ and natural statistics $\ln \tau ,\tau ,\tau x,\tau x^{2}$ .

Moments of the natural statistics

The following moments can be easily computed using the moment generating function of the sufficient statistic:

\operatorname {E}(\ln T)=\psi \left(\alpha \right)-\ln \beta

, where

\psi \left(\alpha \right)

is the digamma function,

\operatorname {E}(T)={\frac {\alpha }{\beta }}

\operatorname {E}(TX)=\mu {\frac {\alpha }{\beta }}

\operatorname {E}(TX^{2})={\frac {1}{\lambda }}+\mu ^{2}{\frac {\alpha }{\beta }}

Scaling

If $(X,T)\sim {\mathrm {NormalGamma}}(\mu ,\lambda ,\alpha ,\beta ),$ then for any b > 0, (bX,bT) is distributed as ${{\rm {NormalGamma}}}(b\mu ,\lambda ,\alpha ,b^{2}\beta ).$

Posterior distribution of the parameters

Assume that x is distributed according to a normal distribution with unknown mean $\mu$ and precision $\tau$ .

x\sim {\mathcal {N}}(\mu ,\tau ^{{-1}})

and that the prior distribution on $\mu$ and $\tau$ , $(\mu ,\tau )$ , has a normal-gamma distribution

(\mu ,\tau )\sim {\text{NormalGamma}}(\mu _{0},\lambda _{0},\alpha _{0},\beta _{0}),

for which the density π satisfies

\pi (\mu ,\tau )\propto \tau ^{{\alpha _{0}-{\frac {1}{2}}}}\,\exp[{-\beta _{0}\tau }]\,\exp[{-{\frac {\lambda _{0}\tau (\mu -\mu _{0})^{2}}{2}}}].

Given a dataset ${\mathbf {X}}$ , consisting of $n$ independent and identically distributed random variables (i.i.d), $\{x_{1},...,x_{n}\}$ , the posterior distribution of $\mu$ and $\tau$ given this dataset can be analytically determined by Bayes' theorem.^[3] Explicitly,

{\mathbf {P}}(\tau ,\mu |{\mathbf {X}})\propto {\mathbf {L}}({\mathbf {X}}|\tau ,\mu )\pi (\tau ,\mu )

where $\mathbf {L}$ is the likelihood of the data given the parameters.

Since the data are i.i.d, the likelihood of the entire dataset is equal to the product of the likelihoods of the individual data samples:

{\mathbf {L}}({\mathbf {X}}|\tau ,\mu )=\prod _{{i=1}}^{n}{\mathbf {L}}(x_{i}|\tau ,\mu ).

This expression can be simplified as follows:

{\begin{aligned}{\mathbf {L}}({\mathbf {X}}|\tau ,\mu )&\propto \prod _{{i=1}}^{n}\tau ^{{1/2}}\exp[{\frac {-\tau }{2}}(x_{i}-\mu )^{2}]\\&\propto \tau ^{{n/2}}\exp[{\frac {-\tau }{2}}\sum _{{i=1}}^{n}(x_{i}-\mu )^{2}]\\&\propto \tau ^{{n/2}}\exp[{\frac {-\tau }{2}}\sum _{{i=1}}^{n}(x_{i}-{\bar {x}}+{\bar {x}}-\mu )^{2}]\\&\propto \tau ^{{n/2}}\exp[{\frac {-\tau }{2}}\sum _{{i=1}}^{n}\left((x_{i}-{\bar {x}})^{2}+({\bar {x}}-\mu )^{2}\right)]\\&\propto \tau ^{{n/2}}\exp[{\frac {-\tau }{2}}\left(ns+n({\bar {x}}-\mu )^{2}\right)],\end{aligned}}

where ${\bar {x}}={\frac {1}{n}}\sum _{{i=1}}^{n}x_{i}$ , the mean of the data samples, and $s={\frac {1}{n}}\sum _{{i=1}}^{n}(x_{i}-{\bar {x}})^{2}$ , the sample variance.

The posterior distribution of the parameters is proportional to the prior times the likelihood.

{\begin{aligned}{\mathbf {P}}(\tau ,\mu |{\mathbf {X}})&\propto {\mathbf {L}}({\mathbf {X}}|\tau ,\mu )\pi (\tau ,\mu )\\&\propto \tau ^{{n/2}}\exp[{\frac {-\tau }{2}}\left(ns+n({\bar {x}}-\mu )^{2}\right)]\tau ^{{\alpha _{0}-{\frac {1}{2}}}}\,\exp[{-\beta _{0}\tau }]\,\exp[{-{\frac {\lambda _{0}\tau (\mu -\mu _{0})^{2}}{2}}}]\\&\propto \tau ^{{{\frac {n}{2}}+\alpha _{0}-{\frac {1}{2}}}}\exp[-\tau \left({\frac {1}{2}}ns+\beta _{0}\right)]\exp \left[-{\frac {\tau }{2}}\left(\lambda _{0}(\mu -\mu _{0})^{2}+n({\bar {x}}-\mu )^{2}\right)\right]\\\end{aligned}}

The final exponential term is simplified by completing the square.

{\begin{aligned}\lambda _{0}(\mu -\mu _{0})^{2}+n({\bar {x}}-\mu )^{2}&=\lambda _{0}\mu ^{2}-2\lambda _{0}\mu \mu _{0}+\lambda _{0}\mu _{0}^{2}+n\mu ^{2}-2n{\bar {x}}\mu +n{\bar {x}}^{2}\\&=(\lambda _{0}+n)\mu ^{2}-2(\lambda _{0}\mu _{0}+n{\bar {x}})\mu +\lambda _{0}\mu _{0}^{2}+n{\bar {x}}^{2}\\&=(\lambda _{0}+n)(\mu ^{2}-2{\frac {\lambda _{0}\mu _{0}+n{\bar {x}}}{\lambda _{0}+n}}\mu )+\lambda _{0}\mu _{0}^{2}+n{\bar {x}}^{2}\\&=(\lambda _{0}+n)\left(\mu -{\frac {\lambda _{0}\mu _{0}+n{\bar {x}}}{\lambda _{0}+n}}\right)^{2}+\lambda _{0}\mu _{0}^{2}+n{\bar {x}}^{2}-{\frac {\left(\lambda _{0}\mu _{0}+n{\bar {x}}\right)^{2}}{\lambda _{0}+n}}\\&=(\lambda _{0}+n)\left(\mu -{\frac {\lambda _{0}\mu _{0}+n{\bar {x}}}{\lambda _{0}+n}}\right)^{2}+{\frac {\lambda _{0}n({\bar {x}}-\mu _{0})^{2}}{\lambda _{0}+n}}\end{aligned}}

On inserting this back into the expression above,

{\begin{aligned}\mathbf {P} (\tau ,\mu |\mathbf {X} )&\propto \tau ^{{\frac {n}{2}}+\alpha _{0}-{\frac {1}{2}}}\exp \left[-\tau \left({\frac {1}{2}}ns+\beta _{0}\right)\right]\exp \left[-{\frac {\tau }{2}}\left(\left(\lambda _{0}+n\right)\left(\mu -{\frac {\lambda _{0}\mu _{0}+n{\bar {x}}}{\lambda _{0}+n}}\right)^{2}+{\frac {\lambda _{0}n({\bar {x}}-\mu _{0})^{2}}{\lambda _{0}+n}}\right)\right]\\&\propto \tau ^{{\frac {n}{2}}+\alpha _{0}-{\frac {1}{2}}}\exp \left[-\tau \left({\frac {1}{2}}ns+\beta _{0}+{\frac {\lambda _{0}n({\bar {x}}-\mu _{0})^{2}}{2(\lambda _{0}+n)}}\right)\right]\exp \left[-{\frac {\tau }{2}}\left(\lambda _{0}+n\right)\left(\mu -{\frac {\lambda _{0}\mu _{0}+n{\bar {x}}}{\lambda _{0}+n}}\right)^{2}\right]\end{aligned}}

This final expression is in exactly the same form as a Normal-Gamma distribution, i.e.,

{\mathbf {P}}(\tau ,\mu |{\mathbf {X}})={\text{NormalGamma}}\left({\frac {\lambda _{0}\mu _{0}+n{\bar {x}}}{\lambda _{0}+n}},\lambda _{0}+n,\alpha _{0}+{\frac {n}{2}},\beta _{0}+{\frac {1}{2}}\left(ns+{\frac {\lambda _{0}n({\bar {x}}-\mu _{0})^{2}}{\lambda _{0}+n}}\right)\right)

Interpretation of parameters

The interpretation of parameters in terms of pseudo-observations is as follows:

The new mean takes a weighted average of the old pseudo-mean and the observed mean, weighted by the number of associated (pseudo-)observations.
The precision was estimated from $2\alpha$ pseudo-observations (i.e. possibly a different number of pseudo-observations, to allow the variance of the mean and precision to be controlled separately) with sample mean $\mu$ and sample variance ${\frac {\beta }{\alpha }}$ (i.e. with sum of squared deviations $2\beta$ ).
The posterior updates the number of pseudo-observations ( $\lambda _{0}$ ) simply by adding up the corresponding number of new observations ( $n$ ).
The new sum of squared deviations is computed by adding the previous respective sums of squared deviations. However, a third "interaction term" is needed because the two sets of squared deviations were computed with respect to different means, and hence the sum of the two underestimates the actual total squared deviation.

As a consequence, if one has a prior mean of $\mu _{0}$ from $n_{\mu }$ samples and a prior precision of $\tau _{0}$ from $n_{\tau }$ samples, the prior distribution over $\mu$ and $\tau$ is

{\mathbf {P}}(\tau ,\mu |{\mathbf {X}})={\text{NormalGamma}}(\mu _{0},n_{\mu },{\frac {n_{\tau }}{2}},{\frac {n_{\tau }}{2\tau _{0}}})

and after observing $n$ samples with mean $\mu$ and variance $s$ , the posterior probability is

{\mathbf {P}}(\tau ,\mu |{\mathbf {X}})={\text{NormalGamma}}\left({\frac {n_{\mu }\mu _{0}+n\mu }{n_{\mu }+n}},n_{\mu }+n,{\frac {1}{2}}(n_{\tau }+n),{\frac {1}{2}}\left({\frac {n_{\tau }}{\tau _{0}}}+ns+{\frac {n_{\mu }n(\mu -\mu _{0})^{2}}{n_{\mu }+n}}\right)\right)

Note that in some programming languages, such as Matlab, the gamma distribution is implemented with the inverse definition of $\beta$ , so the fourth argument of the Normal-Gamma distribution is $2\tau _{0}/n_{\tau }$ .

Generating normal-gamma random variates

Generation of random variates is straightforward:

Sample $\tau$ from a gamma distribution with parameters $\alpha$ and $\beta$
Sample $x$ from a normal distribution with mean $\mu$ and variance $1/(\lambda \tau )$

Related distributions

The normal-inverse-gamma distribution is essentially the same distribution parameterized by variance rather than precision
The normal-exponential-gamma distribution

Notes

1 2 Bernardo & Smith (1993, p.434)
↑ Bernardo & Smith (1993, pages 136, 268, 434)
↑ http://www.trinity.edu/cbrown/bayesweb/

References

Bernardo, J.M.; Smith, A.F.M. (1993) Bayesian Theory, Wiley. ISBN 0-471-49464-X
Dearden et al. "Bayesian Q-learning", Proceedings of the Fifteenth National Conference on Artificial Intelligence (AAAI-98), July 26–30, 1998, Madison, Wisconsin, USA.

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

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