Adapting to Unknown Sparsity by controlling the False Discovery Rate
摘要
We attempt to recover an -dimensional vector observed in white noise, where is large and the vector is known to be sparse, but the degree of sparsity is unknown. We consider three different ways of defining sparsity of a vector: using the fraction of nonzero terms; imposing power-law decay bounds on the ordered entries; and controlling the norm for small. We obtain a procedure which is asymptotically minimax for loss, simultaneously throughout a range of such sparsity classes. The optimal procedure is a data-adaptive thresholding scheme, driven by control of the {\it False Discovery Rate} (FDR). FDR control is a relatively recent innovation in simultaneous testing, ensuring that at most a certain fraction of the rejected null hypotheses will correspond to false rejections. In our treatment, the FDR control parameter also plays a determining role in asymptotic minimaxity. If and also we get sharp asymptotic minimaxity, simultaneously, over a wide range of sparse parameter spaces and loss functions. On the other hand, , forces the risk to exceed the minimax risk by a factor growing with . To our knowledge, this relation between ideas in simultaneous inference and asymptotic decision theory is new. Our work provides a new perspective on a class of model selection rules which has been introduced recently by several authors. These new rules impose complexity penalization of the form . We exhibit a close connection with FDR-controlling procedures under stringent control of the false discovery rate.
引用
@article{arxiv.math/0505374,
title = {Adapting to Unknown Sparsity by controlling the False Discovery Rate},
author = {Felix Abramovich and Yoav Benjamini and David L. Donoho and Iain M. Johnstone},
journal= {arXiv preprint arXiv:math/0505374},
year = {2007}
}
备注
This is a complete version of a paper to appear in Annals of Statitistics. The paper in AoS has certain proofs abbreviated that are given here in detail