Bayesian influence analysis: A geometric approach

Hongtu Zhu; Joseph G. Ibrahim; Niansheng Tang

doi:10.1093/biomet/asr009

Bayesian influence analysis: A geometric approach

Hongtu Zhu, Joseph G. Ibrahim, Niansheng Tang

Research output: Contribution to journal › Review article › peer-review

40 Scopus citations

Abstract

In this paper we develop a general framework of Bayesian influence analysis for assessing various perturbation schemes to the data, the prior and the sampling distribution for a class of statistical models. We introduce a perturbation model to characterize these various perturbation schemes. We develop a geometric framework, called the Bayesian perturbation manifold, and use its associated geometric quantities including the metric tensor and geodesic to characterize the intrinsic structure of the perturbation model. We develop intrinsic influence measures and local influence measures based on the Bayesian perturbation manifold to quantify the effect of various perturbations to statistical models. Theoretical and numerical examples are examined to highlight the broad spectrum of applications of this local influence method in a formal Bayesian analysis.

Original language	English (US)
Pages (from-to)	307-323
Number of pages	17
Journal	Biometrika
Volume	98
Issue number	2
DOIs	https://doi.org/10.1093/biomet/asr009
State	Published - Jun 2011

Keywords

Influence measure
Perturbation manifold
Perturbation model
Prior distribution

ASJC Scopus subject areas

Statistics and Probability
General Mathematics
Agricultural and Biological Sciences (miscellaneous)
General Agricultural and Biological Sciences
Statistics, Probability and Uncertainty
Applied Mathematics

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10.1093/biomet/asr009

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title = "Bayesian influence analysis: A geometric approach",

abstract = "In this paper we develop a general framework of Bayesian influence analysis for assessing various perturbation schemes to the data, the prior and the sampling distribution for a class of statistical models. We introduce a perturbation model to characterize these various perturbation schemes. We develop a geometric framework, called the Bayesian perturbation manifold, and use its associated geometric quantities including the metric tensor and geodesic to characterize the intrinsic structure of the perturbation model. We develop intrinsic influence measures and local influence measures based on the Bayesian perturbation manifold to quantify the effect of various perturbations to statistical models. Theoretical and numerical examples are examined to highlight the broad spectrum of applications of this local influence method in a formal Bayesian analysis.",

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author = "Hongtu Zhu and Ibrahim, {Joseph G.} and Niansheng Tang",

year = "2011",

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T1 - Bayesian influence analysis

T2 - A geometric approach

AU - Zhu, Hongtu

AU - Ibrahim, Joseph G.

AU - Tang, Niansheng

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N2 - In this paper we develop a general framework of Bayesian influence analysis for assessing various perturbation schemes to the data, the prior and the sampling distribution for a class of statistical models. We introduce a perturbation model to characterize these various perturbation schemes. We develop a geometric framework, called the Bayesian perturbation manifold, and use its associated geometric quantities including the metric tensor and geodesic to characterize the intrinsic structure of the perturbation model. We develop intrinsic influence measures and local influence measures based on the Bayesian perturbation manifold to quantify the effect of various perturbations to statistical models. Theoretical and numerical examples are examined to highlight the broad spectrum of applications of this local influence method in a formal Bayesian analysis.

AB - In this paper we develop a general framework of Bayesian influence analysis for assessing various perturbation schemes to the data, the prior and the sampling distribution for a class of statistical models. We introduce a perturbation model to characterize these various perturbation schemes. We develop a geometric framework, called the Bayesian perturbation manifold, and use its associated geometric quantities including the metric tensor and geodesic to characterize the intrinsic structure of the perturbation model. We develop intrinsic influence measures and local influence measures based on the Bayesian perturbation manifold to quantify the effect of various perturbations to statistical models. Theoretical and numerical examples are examined to highlight the broad spectrum of applications of this local influence method in a formal Bayesian analysis.

KW - Influence measure

KW - Perturbation manifold

KW - Perturbation model

KW - Prior distribution

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M3 - Review article

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SP - 307

EP - 323

JO - Biometrika

JF - Biometrika

IS - 2

ER -

Bayesian influence analysis: A geometric approach

Abstract

Keywords

ASJC Scopus subject areas

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