Optimum robust testing in linear models

Optimum robust testing in linear models

Christine Müller

Source: Ann. Statist. Volume 26, Number 3 (1998), 1126-1146.

Abstract

Robust tests for linear models are derived via Wald-type tests that are based on asymptotically linear estimators. For a robustness criterion, the maximum asymptotic bias of the level of the test for distributions in a shrinking contamination neighborhood is used. By also regarding the asymptotic power of the test, admissible robust tests and most-efficient robust tests are derived. For the greatest efficiency, the determinant of the covariance matrix of the underlying estimator is minimized. Also, most-robust tests are derived. It is shown that at the classical $D$-optimal designs, the most-robust tests and the most-efficient robust tests have a very simple form. Moreover, the $D$-optimal designs provide the highest robustness and the highest efficiency under robustness constraints across all designs. So, $D$-optimal designs are also the optimal designs for robust testing. Two examples are considered for which the most-robust tests and the most-efficient robust tests are given.

First Page: Show

Primary Subjects: 62F35, 62K05

Secondary Subjects: 62J05, 62J10

Keywords: Linear model; shrinking contamination; robust tests; asymptotically linear estimators; bias of the level; most robustness; efficiency; $D$-optimality; optimal design

Full-text: Open access

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Links and Identifiers

Permanent link to this document: http://projecteuclid.org/euclid.aos/1024691091
Mathematical Reviews number (MathSciNet): MR1635454
Digital Object Identifier: doi:10.1214/aos/1024691091
Zentralblatt MATH identifier: 0929.62080

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