Time-uniform Chernoff bounds via nonnegative supermartingales

被引:57
作者
Howard, Steven R. [1 ]
Ramdas, Aaditya [2 ,3 ]
McAuliffe, Jon [1 ]
Sekhon, Jasjeet [1 ,4 ]
机构
[1] Univ Calif Berkeley, Dept Stat, Berkeley, CA 94720 USA
[2] Carnegie Mellon Univ, Dept Stat, Pittsburgh, PA 15213 USA
[3] Carnegie Mellon Univ, Dept Machine Learning, Pittsburgh, PA 15213 USA
[4] Univ Calif Berkeley, Dept Polit Sci, Berkeley, CA 94720 USA
关键词
Exponential concentration inequalities; nonnegative supermartingale; line crossing probability; EXPONENTIAL INEQUALITIES; PROBABILITY-INEQUALITIES; MOMENT BOUNDS; MARTINGALES; SUMS; GRAPHS;
D O I
10.1214/18-PS321
中图分类号
O21 [概率论与数理统计]; C8 [统计学];
学科分类号
020208 ; 070103 ; 0714 ;
摘要
We develop a class of exponential bounds for the probability that a martingale sequence crosses a time-dependent linear threshold. Our key insight is that it is both natural and fruitful to formulate exponential concentration inequalities in this way. We illustrate this point by presenting a single assumption and theorem that together unify and strengthen many tail bounds for martingales, including classical inequalities (1960-80) by Bernstein, Bennett, Hoeffding, and Freedman; contemporary inequalities (1980-2000) by Shorack and Wellner, Pinelis, Blackwell, van de Geer, and de la Pena; and several modern inequalities (post-2000) by Khan, Tropp, Bercu and Touati, Delyon, and others. In each of these cases, we give the strongest and most general statements to date, quantifying the time-uniform concentration of scalar, matrix, and Banach-space-valued martingales, under a variety of nonparametric assumptions in discrete and continuous time. In doing so, we bridge the gap between existing line-crossing inequalities, the sequential probability ratio test, the Cramer-Chernoff method, self-normalized processes, and other parts of the literature.
引用
收藏
页码:257 / 317
页数:61
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