Large deviations for sums of multivariate stretched-exponential random variables: the few-big-jumps principle

Abstract

Large deviations for sums of i.i.d.\ random variables with stretched-exponential tails (also called Weibull or semi-exponential tails) have been well understood since the 60's, going back to Nagaev's seminal work. Many extensions in the 1-dimensional setting have been developed since then, showing that such deviations are typically governed by a single big jump. In higher dimensions, a corresponding theory has remained largely undeveloped. This work provides such a multivariate extension and establishes large deviation results for sums of i.i.d.\ random vectors in Rk under fairly general assumptions. Roughly speaking, for some α∈(0,1), the log-probability of one random vector divided by x exceeding a threshold t in all components behaves asymptotically, for large x, as xα times a negative infimum of a function J. We prove large deviation results for sums of i.i.d.\ copies, where the rate function is given by a minimization of at most k summands of J. This establishes a few-big-jumps principle that generalizes the classical 1-dimensional phenomenon: the deviation is typically realized by at most k independent vectors. The results are applied to absolute powers of multivariate Gaussian vectors as well as to various other examples. They also allow us to study random projections of high-dimensional pN-balls, revealing interesting insights about the appearance of light- and heavy-tailed distributions in high-dimensional geometry.