Optimality

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IMS Lecture Notes–Monograph Series 2nd Lehmann Symposium – <strong>Optimality</strong> Vol. 49 (2006) 291–311 c○ Institute of Mathematical Statistics, 2006 DOI: 10.1214/074921706000000518 The distribution of a linear predictor after model selection: Unconditional finite-sample distributions and asymptotic approximations Hannes Leeb 1,∗ Yale University Abstract: We analyze the (unconditional) distribution of a linear predictor that is constructed after a data-driven model selection step in a linear regression model. First, we derive the exact finite-sample cumulative distribution function (cdf) of the linear predictor, and a simple approximation to this (complicated) cdf. We then analyze the large-sample limit behavior of these cdfs, in the fixed-parameter case and under local alternatives. 1. Introduction The analysis of the unconditional distribution of linear predictors after model selection given in this paper complements and completes the results of Leeb [1], where the corresponding conditional distribution is considered, conditional on the outcome of the model selection step. The present paper builds on Leeb [1] as far as finite-sample results are concerned. For a large-sample analysis, however, we can not rely on that paper; the limit behavior of the unconditional cdf differs from that of the conditional cdfs so that a separate analysis is necessary. For a review of the relevant related literature and for an outline of applications of our results, we refer the reader to Leeb [1]. We consider a linear regression model Y = Xθ + u with normal errors. (The normal linear model facilitates a detailed finite-sample analysis. Also note that asymptotic properties of the Gaussian location model can be generalized to a much larger model class including nonlinear models and models for dependent data, as long as appropriate standard regularity conditions guaranteeing asymptotic normality of the maximum likelihood estimator are satisfied.) We consider model selection by a sequence of ‘general-to-specific’ hypothesis tests; that is, starting from the overall model, a sequence of tests is used to simplify the model. The cdf of a linear function of the post-model-selection estimator (properly scaled and centered) is denoted by Gn,θ,σ(t). The notation suggests that this cdf depends on the sample size n, the regression parameter θ, and on the error variance σ 2 . An explicit formula for Gn,θ,σ(t) is given in (3.10) below. From this formula, we see that the distribution of, say, a linear predictor after model selection is significantly different from 1 Department of Statistics, Yale University, 24 Hillhouse Avenue, New Haven, CT 06511. ∗ Research supported by the Max Kade Foundation and by the Austrian Science Foundation (FWF), project no. P13868-MAT. A preliminary version of this manuscript was written in February 2002. AMS 2000 subject classifications: primary 62E15; secondary 62F10, 62F12, 62J05. Keywords and phrases: model uncertainty, model selection, inference after model selection, distribution of post-model-selection estimators, linear predictor constructed after model selection, pre-test estimator. 291
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Institute of Mathematical Statistic
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Institute of Mathematical Statistic
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iv Contents Copulas and Decoupling
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vi Finally, thanks go the Statistic
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SCIENTIFIC PROGRAM The Second Erich
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x Recent Advances in Longitudinal D
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The Second Lehmann Symposium—Opti
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xiv Richard Davis Colorado State Un
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xvi Matthias Matheas Rice Universit
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xviii Hui Zhao University of Texas
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IMS Lecture Notes-Monograph Series
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Proof. The maximum LR test rejects
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4. Location-scale families On likel
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6. Conclusions On likelihood ratio
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Student’s t-test for scale mixtur
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Optimality in multiple testing 17 w
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Optimality in multiple testing 19 I
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power 0.02 0.03 0.04 0.05 0.06 0.07
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Optimality in multiple testing 23 i
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Optimality in multiple testing 25 (
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Optimality in multiple testing 27 M
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6. Summary Optimality in multiple t
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Optimality in multiple testing 31 [
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On the false discovery proportion 3
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≤ N� � N� P m=1 On the fals
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Since j≤ s, it follows that On th
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0.025 0.02 0.015 0.01 0.005 On the
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Massive multiple hypotheses testing
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P value EDF qdf 0.0 0.2 0.4 0.6 0.8
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Proof. See Appendix. Massive multip
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X1 Massive multiple hypotheses test
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0.0 0.2 0.4 0.6 0.8 1.0 0.0 0.2 0.4
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Then π0α ∗ cal π0α ∗ cal +
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Frequentist statistics: theory of i
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2.3. Failure and confirmation Frequ
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together with the probabilistic ass
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Statistical models: problem of spec
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Modeling inequality, spread in mult
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Semiparametric transformation model
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6.3. Part (ii) Put (6.1) (6.2) ˙Γ
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Bayesian transformation hazard mode
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Cumulative Hazard 0.0 0.2 0.4 0.6 0
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Hazard function 0.0 0.5 1.0 1.5 2.0
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Copulas, information, dependence an
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Regression trees 211 right model in
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Abs(effects) 0.00 0.05 0.10 0.15 0.
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Regression trees 215 of the tree. T
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Regression trees 217 GUIDE methods
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Regression trees 219 and E appear a
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Regression trees 221 Table 3 Result
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Solder =thick 2.5 Regression trees
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Observed values 0 10 20 30 40 50 60
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Regression trees 227 effects and in
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On Competing risk and degradation p
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