Limiting distributions for eigenvalues of sample correlation matrices from heavy-tailed populations

Abstract

Consider a p-dimensional population x ∈Rp with iid coordinates in the domain of attraction of a stable distribution with index α∈ (0,2). Since the variance of x is infinite, the sample covariance matrix Sn=n-1Σi=1n xi x'i based on a sample x1,…, xn from the population is not well behaved and it is of interest to use instead the sample correlation matrix Rn= \diag( Sn)\-1/2\, Sn \diag( Sn)\-1/2. This paper finds the limiting distributions of the eigenvalues of Rn when both the dimension p and the sample size n grow to infinity such that p/n γ ∈ (0,∞). The family of limiting distributions \Hα,γ\ is new and depends on the two parameters α and γ. The moments of Hα,γ are fully identified as sum of two contributions: the first from the classical Marcenko-Pastur law and a second due to heavy tails. Moreover, the family \Hα,γ\ has continuous extensions at the boundaries α=2 and α=0 leading to the Marcenko-Pastur law and a modified Poisson distribution, respectively. Our proofs use the method of moments, the path-shortening algorithm developed in [18] and some novel graph counting combinatorics. As a consequence, the moments of Hα,γ are expressed in terms of combinatorial objects such as Stirling numbers of the second kind. A simulation study on these limiting distributions Hα,γ is also provided for comparison with the Marcenko-Pastur law.