BAYES FACTORS
成果类型:
Review
署名作者:
KASS, RE; RAFTERY, AE
署名单位:
University of Washington; University of Washington Seattle
刊物名称:
JOURNAL OF THE AMERICAN STATISTICAL ASSOCIATION
ISSN/ISSBN:
0162-1459
DOI:
10.1080/01621459.1995.10476572
发表日期:
1995
页码:
773-795
关键词:
vague prior information
monte-carlo integration
model selection
change-point
posterior distributions
regression variables
exponential family
irish education
poisson-process
GIBBS SAMPLER
摘要:
In a 1935 paper and in his book Theory of Probability, Jeffreys developed a methodology for quantifying the evidence in favor of a scientific theory. The centerpiece was a number, now called the Bayes factor, which is the posterior odds of the null hypothesis when the prior probability on the null is one-half. Although there has been much discussion of Bayesian hypothesis testing in the context of criticism of P-values, less attention has been given to the Bayes factor as a practical tool of applied statistics. In this article we review and discuss the uses of Bayes factors in the context of five scientific applications in genetics, sports, ecology, sociology, and psychology. We emphasize the following points: From Jeffreys' Bayesian viewpoint, the purpose of hypothesis testing is to evaluate the evidence in favor of a scientific theory. Bayes factors offer a way of evaluating evidence in favor of a null hypothesis. Bayes factors provide a way of incorporating external information into the evaluation of evidence about a hypothesis. Bayes factors are very general and do not require alternative models to be nested. Several techniques are available for computing Bayes factors, including asymptotic approximations that are easy to compute using the output from standard packages that maximize likelihoods. In ''nonstandard'' statistical models that do not satisfy common regularity conditions, it can be technically simpler to calculate Bayes factor; than to derive non-Bayesian significance tests. The Schwarz criterion (or BIG) gives a rough approximation to the logarithm of the Bayes factor, which is easy to use and does not require evaluation of prior distributions. When one is interested in estimation or prediction, Bayes factors may be converted to weights to be attached to various models so that a composite estimate or prediction may be obtained that takes account of structural or model uncertainty. Algorithms have been proposed that allow model uncertainty to be taken into account when the class of models initially considered is very large. Bayes factors are useful for guiding an evolutionary model-building process. It is important, and feasible, to assess the sensitivity of conclusions to the prior distributions used.
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