Matrix F-distribution

Matrix $F$
Matrix
Notation
Parameters	, scale matrix (pos. def.); degrees of freedom (real); degrees of freedom (real)
Support	is p × p positive definite matrix
PDF	is the multivariate gamma function; is the p × p identity matrix;
Mean	, for
Variance	see below

In statistics, the matrix F distribution (or matrix variate F distribution) is a matrix variate generalization of the F distribution which is defined on real-valued positive-definite matrices. In Bayesian statistics it can be used as the semi conjugate prior for the covariance matrix or precision matrix of multivariate normal distributions, and related distributions ^[1]^[2]^[3]^[4].

Density

The probability density function of the matrix $F$ distribution is:

$f_{\mathbf {X} }({\mathbf {X} };{\mathbf {\Psi } },\nu ,\delta )={\frac {\Gamma _{p}\left({\frac {\nu +\delta +p-1}{2}}\right)}{\Gamma _{p}\left({\frac {\nu }{2}}\right)\Gamma _{k}\left({\frac {\delta +p-1}{2}}\right)|\mathbf {\Psi } |^{\frac {\nu }{2}}}}~|{\mathbf {X} }|^{\frac {\nu -p-1}{2}}|{\textbf {I}}_{p}+{\mathbf {X} }\mathbf {\Psi } ^{-1}|^{-{\frac {\nu +\delta +p-1}{2}}}$

where $\mathbf {X}$ and ${\mathbf {\Psi } }$ are $p\times p$ positive definite matrices, $|\cdot |$ is the determinant, Γ_p(·) is the multivariate gamma function, and ${\textbf {I}}_{p}$ is the p × p identity matrix.

Properties

Construction of the distribution

The standard matrix F distribution, with an identity scale matrix $\mathbf {I} _{p}$ , was originally derived by ^[1]. When considering independent distributions, ${\mathbf {\Phi } _{1}}\sim {\mathcal {W}}({\mathbf {I} _{p}},\nu )$ and ${\mathbf {\Phi } _{2}}\sim {\mathcal {W}}({\mathbf {I} _{p}},\delta +k-1)$ , and define $\mathbf {X} ={\mathbf {\Phi } _{2}}^{-1/2}{\mathbf {\Phi } _{1}}{\mathbf {\Phi } _{2}}^{-1/2}$ , then $\mathbf {X} \sim {\mathcal {F}}({\mathbf {I} _{p}},\nu ,\delta )$ .

If ${\mathbf {X} }|\mathbf {\Phi } \sim {\mathcal {W}}^{-1}({\mathbf {\Phi } },\delta +p-1)$ and ${\mathbf {\Phi } }\sim {\mathcal {W}}({\mathbf {\Psi } },\nu )$ , then, after integrating out $\mathbf {\Phi }$ , $\mathbf {X}$ has a matrix F-distribution, i.e.,
$f_{\mathbf {X} |\mathbf {\Phi } ,\nu ,\delta }(\mathbf {X} )=\int f_{\mathbf {X} |\mathbf {\Phi } ,\delta +p-1}(\mathbf {X} )f_{\mathbf {\Phi } |\mathbf {\Psi } ,\nu }(\mathbf {\Phi } )d\mathbf {\Phi } .$
This construction is useful to construct a semi-conjugate prior for a covariance matrix^[3].

If ${\mathbf {X} }|\mathbf {\Phi } \sim {\mathcal {W}}({\mathbf {\Phi } },\nu )$ and ${\mathbf {\Phi } }\sim {\mathcal {W}}^{-1}({\mathbf {\Psi } },\delta +p-1)$ , then, after integrating out $\mathbf {\Phi }$ , $\mathbf {X}$ has a matrix F-distribution, i.e.,
$f_{\mathbf {X} |\mathbf {\Psi } ,\nu ,\delta }(\mathbf {X} )=\int f_{\mathbf {X} |\mathbf {\Phi } ,\nu }(\mathbf {X} )f_{\mathbf {\Phi } |\mathbf {\Psi } ,\delta +p-1}(\mathbf {\Phi } )d\mathbf {\Phi } .$
This construction is useful to construct a semi-conjugate prior for a precision matrix^[4].

Marginal distributions from a matrix F distributed matrix

Suppose ${\mathbf {A} }\sim F({\mathbf {\Psi } },\nu ,\delta )$ has a matrix F distribution. Partition the matrices ${\mathbf {A} }$ and ${\mathbf {\Psi } }$ conformably with each other

{\mathbf {A} }={\begin{bmatrix}\mathbf {A} _{11}&\mathbf {A} _{12}\\\mathbf {A} _{21}&\mathbf {A} _{22}\end{bmatrix}},\;{\mathbf {\Psi } }={\begin{bmatrix}\mathbf {\Psi } _{11}&\mathbf {\Psi } _{12}\\\mathbf {\Psi } _{21}&\mathbf {\Psi } _{22}\end{bmatrix}}

where ${\mathbf {A} _{ij}}$ and ${\mathbf {\Psi } _{ij}}$ are $p_{i}\times p_{j}$ matrices, then we have ${\mathbf {A} _{11}}\sim F({\mathbf {\Psi } _{11}},\nu ,\delta )$ .

Moments

Let $X\sim F({\mathbf {\Psi } },\nu ,\delta )$ .

The mean is given by: $E(\mathbf {X} )={\frac {\nu }{\delta -2}}\mathbf {\Psi } .$

The (co)variance of elements of $\mathbf {X}$ are given by^[3]:

\operatorname {cov} (X_{ij},X_{ml})=\Psi _{ij}\Psi _{ml}{\tfrac {2\nu ^{2}+2\nu (\delta -2)}{(\delta -1)(\delta -2)^{2}(\delta -4)}}+(\Psi _{il}\Psi _{jm}+\Psi _{im}\Psi _{jl})\left({\tfrac {2\nu +\nu ^{2}(\delta -2)+\nu (\delta -2)}{(\delta -1)(\delta -2)^{2}(\delta -4)}}+{\tfrac {\nu }{(\delta -2)^{2}}}\right).

Related distributions

The matrix F-distribution has also been termed the multivariate beta II distribution^[5]. See also ^[6], for a univariate version.

A univariate version of the matrix F distribution is the F-distribution. With $p=1$ (i.e. univariate) and $\mathbf {\Psi } =1$ , and $x=\mathbf {X}$ , the probability density function of the matrix F distribution becomes the univariate (unscaled) F distribution:
$f_{x\mid \nu ,\delta }(x)=\operatorname {B} \left({\tfrac {\nu }{2}},{\tfrac {\delta }{2}}\right)^{-1}\left({\tfrac {\nu }{\delta }}\right)^{\nu /2}x^{\nu /2-1}\left(1+{\tfrac {\nu }{\delta }}\,x\right)^{-(\nu +\delta )/2},$

In the univariate case, with $p=1$ and $x=\mathbf {X}$ , and when setting $\nu =1$ , then ${\sqrt {x}}$ follows a half t distribution with scale parameter ${\sqrt {\psi }}$ and degrees of freedom $\delta$ . The half t distribution is a common prior for standard deviations^[7].

References

^ ^a ^b Olkin, I. and Rubin, H. (1964). "Multivariate Beta Distributions and Independence Properties of the Wishart Distribution.". The Annals of Mathematical Statistics, 35, pp. 261–269.
^ Dawid, A. P. (1981). "Some matrix-variate distribution theory: Notational considerations and a Bayesian application". Biometrika, 68:1, pp. 265–274.
^ ^a ^b ^c Mulder, J. and Pericchi, L. R. (2010). "The Matrix-F Prior for Estimating and Testing Covariance Matrices". Bayesian Analysis, 13:4, pp. 1193-1214.
^ ^a ^b Williams, D. R. and Mulder, J. (2020). "Bayesian hypothesis testing for Gaussian graphical models: Conditional independence and order constraints". Journal of Mathematical Psychology, 99, 102441
^ Tan, W.Y. (1969). "Note on the multivariate and the generalized multivariate beta distributions.". Journal of American Statistical Association, 64, pp. 230–241.
^ Perez, M.-E. and Pericchi, L. R. and Ramirez, I. C. (2017). "The Scaled Beta2 Distribution as a Robust Prior for Scales.". Bayesian Analysis, 12:3, pp. 615–637.
^ Gelman A. (2006). "Prior distributions for variance parameters in hierarchical models.". Bayesian Analysis, 1:3, pp. 515–534.

[olkinrubin1964-1] Olkin, I. and Rubin, H. (1964). "Multivariate Beta Distributions and Independence Properties of the Wishart Distribution.". The Annals of Mathematical Statistics, 35, pp. 261–269.

[dawid1981-2] Dawid, A. P. (1981). "Some matrix-variate distribution theory: Notational considerations and a Bayesian application". Biometrika, 68:1, pp. 265–274.

[mulderpericchi2018-3] Mulder, J. and Pericchi, L. R. (2010). "The Matrix-F Prior for Estimating and Testing Covariance Matrices". Bayesian Analysis, 13:4, pp. 1193-1214.

[williamsmulder2020-4] Williams, D. R. and Mulder, J. (2020). "Bayesian hypothesis testing for Gaussian graphical models: Conditional independence and order constraints". Journal of Mathematical Psychology, 99, 102441

[tan1969-5] Tan, W.Y. (1969). "Note on the multivariate and the generalized multivariate beta distributions.". Journal of American Statistical Association, 64, pp. 230–241.

[perez2017-6] Perez, M.-E. and Pericchi, L. R. and Ramirez, I. C. (2017). "The Scaled Beta2 Distribution as a Robust Prior for Scales.". Bayesian Analysis, 12:3, pp. 615–637.

[gelman2006-7] Gelman A. (2006). "Prior distributions for variance parameters in hierarchical models.". Bayesian Analysis, 1:3, pp. 515–534.

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