Fisher information

In mathematical statistics, the Fisher information is a way of measuring the amount of information that an observable random variable X carries about an unknown parameter θ of a distribution that models X. Formally, it is the variance of the score, or the expected value of the observed information.

The role of the Fisher information in the asymptotic theory of maximum-likelihood estimation was emphasized and explored by the statistician Sir Ronald Fisher (following some initial results by Francis Ysidro Edgeworth). The Fisher information matrix is used to calculate the covariance matrices associated with maximum-likelihood estimates. It can also be used in the formulation of test statistics, such as the Wald test.

In Bayesian statistics, the Fisher information plays a role in the derivation of non-informative prior distributions according to Jeffreys' rule.[1] It also appears as the large-sample covariance of the posterior distribution, provided that the prior is sufficiently smooth (a result known as Bernstein–von Mises theorem, which was anticipated by Laplace for exponential families).[2] The same result is used when approximating the posterior with Laplace's approximation, where the Fisher information appears as the covariance of the fitted Gaussian.[3]

Statistical systems of a scientific nature (physical, biological, etc.) whose likelihood functions obey shift invariance have been shown to obey maximum Fisher information.[4] The level of the maximum depends upon the nature of the system constraints.

  1. ^ Robert, Christian (2007). "Noninformative prior distributions". The Bayesian Choice (2nd ed.). Springer. pp. 127–141. ISBN 978-0-387-71598-8.
  2. ^ Le Cam, Lucien (1986). Asymptotic Methods in Statistical Decision Theory. New York: Springer. pp. 618–621. ISBN 0-387-96307-3.
  3. ^ Kass, Robert E.; Tierney, Luke; Kadane, Joseph B. (1990). "The Validity of Posterior Expansions Based on Laplace's Method". In Geisser, S.; Hodges, J. S.; Press, S. J.; Zellner, A. (eds.). Bayesian and Likelihood Methods in Statistics and Econometrics. Elsevier. pp. 473–488. ISBN 0-444-88376-2.
  4. ^ Frieden & Gatenby (2013).