Log determinant of large correlation matrices under infinite fourth moment

Abstract

In this paper, we show the central limit theorem for the logarithmic determinant of the sample correlation matrix R constructed from the (p× n)-dimensional data matrix X containing independent and identically distributed random entries with mean zero, variance one and infinite fourth moments. Precisely, we show that for p/n γ∈ (0,1) as n,p ∞ the logarithmic law equation* R -(p-n+12)(1-p/n)+p-p/n-2(1-p/n)- 2 p/n d→ N(0,1)\, equation* is still valid if the entries of the data matrix X follow a symmetric distribution with a regularly varying tail of index α∈ (3,4). The latter assumptions seem to be crucial, which is justified by the simulations: if the entries of X have the infinite absolute third moment and/or their distribution is not symmetric, the logarithmic law is not valid anymore. The derived results highlight that the logarithmic determinant of the sample correlation matrix is a very stable and flexible statistic for heavy-tailed big data and open a novel way of analysis of high-dimensional random matrices with self-normalized entries.

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