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We say follows an inverse Wishart distribution, denoted as , if its inverse has a Wishart distribution. Important identities have been derived for the inverse-Wishart distribution.[2]
Suppose we wish to make inference about a covariance matrix whose prior has a distribution. If the observations are independent p-variate Gaussian variables drawn from a distribution, then the conditional distribution has a distribution, where .
Because the prior and posterior distributions are the same family, we say the inverse Wishart distribution is conjugate to the multivariate Gaussian.
Due to its conjugacy to the multivariate Gaussian, it is possible to marginalize out (integrate out) the Gaussian's parameter .
(this is useful because the variance matrix is not known in practice, but because is known a priori, and can be obtained from the data, the right hand side can be evaluated directly). The inverse-Wishart distribution as a prior can be constructed via existing transferred prior knowledge.[5]
Moments
The following is based on Press, S. J. (1982) "Applied Multivariate Analysis", 2nd ed. (Dover Publications, New York), after reparameterizing the degree of freedom to be consistent with the p.d.f. definition above.
The variance of the diagonal uses the same formula as above with , which simplifies to:
The covariance of elements of are given by:
The "white" inverse complex Wishart was shown by Shaman[6] to have tridiagonal statistical structure in which the leading diagonal and first sub- and supra-diagonals are correlated, while all other element are uncorrelated. It was also shown by Brennan and Reed[7] using a matrix partitioning procedure, albeit in the complex variable domain, that the marginal pdf of the [1,1] diagonal element of this matrix has an Inverse-chi-squared distribution. This extends easily to all diagonal elements since is statistically invariant under orthogonal transformations, which includes interchanges of elements. For the inverse Chi squared distribution, with arbitrary degrees of freedom, the pdf is
the mean and variance of which are respectively. These two parameters are matched to the corresponding inverse Wishart diagonal moments when and hence the diagonal element marginal pdf of becomes:
which, below, is generalized to all diagonal elements.
i.e., the inverse-gamma distribution, where is the ordinary Gamma function.
The Inverse Wishart distribution is a special case of the inverse matrix gamma distribution when the shape parameter and the scale parameter .
Another generalization has been termed the generalized inverse Wishart distribution, . A positive definite matrix is said to be distributed as if is distributed as . Here denotes the symmetric matrix square root of , the parameters are positive definite matrices, and the parameter is a positive scalar larger than . Note that when is equal to an identity matrix, . This generalized inverse Wishart distribution has been applied to estimating the distributions of multivariate autoregressive processes.[8]
When the scale matrix is an identity matrix, is an arbitrary orthogonal matrix, replacement of by does not change the pdf of so belongs to the family of spherically invariant random processes (SIRPs) in some sense.
Thus, an arbitrary p-vector with can be rotated into the vector without changing the pdf of , moreover can be a permutation matrix which exchanges diagonal elements. It follows that the diagonal elements of are identically inverse chi squared distributed, with pdf in the previous section though they are not mutually independent. The result is known in optimal portfolio statistics, as in Theorem 2 Corollary 1 of Bodnar et al[9], where it is expressed in the inverse form .
^A. O'Hagan, and J. J. Forster (2004). Kendall's Advanced Theory of Statistics: Bayesian Inference. Vol. 2B (2 ed.). Arnold. ISBN978-0-340-80752-1.
^Haff, LR (1979). "An identity for the Wishart distribution with applications". Journal of Multivariate Analysis. 9 (4): 531–544. doi:10.1016/0047-259x(79)90056-3.
^Gelman, Andrew; Carlin, John B.; Stern, Hal S.; Dunson, David B.; Vehtari, Aki; Rubin, Donald B. (2013-11-01). Bayesian Data Analysis, Third Edition (3rd ed.). Boca Raton: Chapman and Hall/CRC. ISBN9781439840955.
^Shahrokh Esfahani, Mohammad; Dougherty, Edward (2014). "Incorporation of Biological Pathway Knowledge in the Construction of Priors for Optimal Bayesian Classification". IEEE Transactions on Bioinformatics and Computational Biology. 11 (1): 202–218. doi:10.1109/tcbb.2013.143. PMID26355519.
^Brennan, L E; Reed, I S (January 1982). "An Adaptive Array Signal Processing Algorithm for Communications". IEEE Trans on Aerospace and Electronic Systems. AES-18, No. 1: 120–130.