Optimality

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76 C. Cheng [23] Newton, M. A., Noueiry, A., Sarkar, D. and Ahlquist, P. (2004). Detecting differential gene expression with a semiparametric hierarchical mixture method, Biostatistics 5, 155–176. [24] Pounds, S. and Morris, S. (2003). Estimating the occurrence of false positives and false negatives in microarray studies by approximating and partitioning the empirical distribution of p-values. Bioinformatics 19, 1236–1242. [25] Pounds, S. and Cheng, C. (2004). Improving false discovery rate estimation. Bioinformatics 20, 1737–1745. [26] Reiner, A., Yekutieli, D. and Benjamini, Y. (2003). Identifying differentially expressed genes using false discovery rate controlling procedures. Bioinformatics 19, 368–375. [27] Schweder, T. and Spjøtvoll, E. (1982). Plots of P-values to evaluate many tests simultaneously. Biometrika 69 493-502. [28] Smyth, G. K. (2004). Linear models and empirical Bayes methods for assessing differential expression in microarray experiments. Statistical Applications in Genetics and Molecular Biology 3, Article 3. URL: //www.bepress.com/sagmb/vol3/iss1/art3. [29] Storey, J. D. (2002). A direct approach to false discovery rates. J. R. Stat. Soc. Ser. B Stat. Methodol. 64, 479–498. [30] Storey, J. D. (2003). The positive false discovery rate: a Baysian interpretation and the q-value. Ann. Statis. 31, 2103–2035. [31] Storey, J. D., Taylor, J. and Siegmund, D. (2003). Strong control, conservative point estimation and simultaneous conservative consistency of false discovery rates: a unified approach. J. R. Stat. Soc. Ser. B Stat. Methodol. 66, 187–205. [32] Storey, J. D. and Tibshirani, R. (2003). SAM thresholding and false discovery rates for detecting differential gene expression in DNA microarrays. In The Analysis of Gene Expression Data (Parmigiani, G. et al., eds.). Springer, New York. [33] Storey, J. D. and Tibshirani, R. (2003). Statistical significance for genome-wide studies. Proc. Natl. Acad. Sci. USA 100, 9440–9445. [34] Tsai, C-A., Hsueh, H-M. and Chen, J. J. (2003). Estimation of false discovery rates in multiple testing: Application to gene microarray data. Biometrics 59, 1071–1081. [35] Tusher, V. G., Tibshirani, R. and Chu, G. (2001). Significance analysis of microarrays applied to ionizing radiation response. Proc. Natl. Acad. Sci. USA 98, 5116–5121. [36] van der Laan, M., Dudoit, S. and Pollard, K. S. (2004a). Multiple Testing. Part II. Step-down procedures for control of the family-wise error rate. Statistical Applications in Genetics and Molecular Biology 3, Article 14. URL: //www.bepress.com/sagmb/vol3/iss1/art14. [37] van der Laan, M., Dudoit, S. and Pollard, K. S. (2004b). Augmentation procedures for control of the generalized family-wise error rate and tail probabilities for the proportion of false positives. Statistical Applications in Genetics and Molecular Biology 3, Article 15. URL: //www.bepress.com/sagmb/vol3/iss1/art15.
IMS Lecture Notes–Monograph Series 2nd Lehmann Symposium – <strong>Optimality</strong> Vol. 49 (2006) 77–97 c○ Institute of Mathematical Statistics, 2006 DOI: 10.1214/074921706000000400 Frequentist statistics as a theory of inductive inference Deborah G. Mayo 1 and D. R. Cox 2 Viriginia Tech and Nuffield College, Oxford Abstract: After some general remarks about the interrelation between philosophical and statistical thinking, the discussion centres largely on significance tests. These are defined as the calculation of p-values rather than as formal procedures for “acceptance” and “rejection.” A number of types of null hypothesis are described and a principle for evidential interpretation set out governing the implications of p-values in the specific circumstances of each application, as contrasted with a long-run interpretation. A variety of more complicated situations are discussed in which modification of the simple p-value may be essential. 1. Statistics and inductive philosophy 1.1. What is the Philosophy of Statistics? The philosophical foundations of statistics may be regarded as the study of the epistemological, conceptual and logical problems revolving around the use and interpretation of statistical methods, broadly conceived. As with other domains of philosophy of science, work in statistical science progresses largely without worrying about “philosophical foundations”. Nevertheless, even in statistical practice, debates about the different approaches to statistical analysis may influence and be influenced by general issues of the nature of inductive-statistical inference, and thus are concerned with foundational or philosophical matters. Even those who are largely concerned with applications are often interested in identifying general principles that underlie and justify the procedures they have come to value on relatively pragmatic grounds. At one level of analysis at least, statisticians and philosophers of science ask many of the same questions. • What should be observed and what may justifiably be inferred from the resulting data? • How well do data confirm or fit a model? • What is a good test? • Does failure to reject a hypothesis H constitute evidence “confirming” H? • How can it be determined whether an apparent anomaly is genuine? How can blame for an anomaly be assigned correctly? • Is it relevant to the relation between data and a hypothesis if looking at the data influences the hypothesis to be examined? • How can spurious relationships be distinguished from genuine regularities? 1Department of Philosophy and Economics, Virginia Tech, Blacksburg, VA 24061-0126, e-mail: mayod@vt.edu 2Nuffield College, Oxford OX1 1NF, UK, e-mail: david.cox@nuffield.ox.ac.uk AMS 2000 subject classifications: 62B15, 62F03. Keywords and phrases: statistical inference, significance test, confidence interval, test of hypothesis, Neyman–Pearson theory, selection effect, multiple testing. 77
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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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Modeling inequality, spread in mult
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Modeling inequality, spread in mult
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Semiparametric transformation model
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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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Regression trees 227 effects and in
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2.1. Maximin efficiency robust test
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Robust tests for genetic associatio
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1 . . . 1 i . . . . . . R j . . . O
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Optimal sampling strategies 269 as
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Optimal sampling strategies 271 γ1
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Optimal sampling strategies 273 Def
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Optimal sampling strategies 275 Usi
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Optimal sampling strategies 277 Def
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optimal 1 2 3 4 leaf sets 5 6 (leaf
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6. Related work Optimal sampling st
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Optimal sampling strategies 285 Sin
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Optimal sampling strategies 287 µ
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Optimal sampling strategies 289 on
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Linear prediction after model selec
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Moment-density estimation 323 may n
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Moment-density estimation 327 Corol
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Moment-density estimation 329 Suppo
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Moment-density estimation 333 [7] M
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for positive α, and for α = 0 as
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Asymptotics of the MDPDE 337 Lemma
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