Cram\'er-type Moderate Deviation for Quadratic Forms with a Fast Rate

Abstract

Let X1,…, Xn be independent and identically distributed random vectors in Rd. Suppose E X1=0, Cov(X1)=Id, where Id is the d× d identity matrix. Suppose further that there exist positive constants t0 and c0 such that E et0|X1|≤ c0<∞, where |·| denotes the Euclidean norm. Let W=1nΣi=1n Xi and let Z be a d-dimensional standard normal random vector. Let Q be a d× d symmetric positive definite matrix whose largest eigenvalue is 1. We prove that for 0≤ x≤ n1/6, equation* | P(|Q1/2W|>x)P(|Q1/2Z|>x)-1 |≤ C ( 1+x5(Q1/2)n+x6n) for\ d≥ 5 equation* and equation* | P(|Q1/2W|>x)P(|Q1/2Z|>x)-1 |≤ C ( 1+x3(Q1/2)ndd+1+x6n) for\ 1≤ d≤ 4, equation* where and C are positive constants depending only on d, t0, and c0. This is a first extension of Cram\'er-type moderate deviation to the multivariate setting with a faster convergence rate than 1/n. The range of x=o(n1/6) for the relative error to vanish and the dimension requirement d≥ 5 for the 1/n rate are both optimal. We prove our result using a new change of measure, a two-term Edgeworth expansion for the changed measure, and cancellation by symmetry for terms of the order 1/n.