A Sudakov--Fernique proof of Lehner-type edge bounds for matrix-valued GUE sums

Abstract

Let A0,A1,…,An∈ MN(C) be Hermitian matrices and let G1,…,Gn be independent M× M GUE matrices normalized so that \|M-1/2Gi\| 2 almost surely as M∞. We study the spectral edges and operator norm of HM = A0 IM + 1MΣi=1n Ai Gi. Lehner's formula identifies the right and left edges of the corresponding free semicircular operator as ρ+ = ∈fZ 0λ(A0+Z+Σi=1n AiZ-1Ai) and ρ- = Z 0λ(A0+Z+Σi=1n AiZ-1Ai). Assuming Ai 0 for i 1 and M N, we prove via concentration and minimax duality the finite-dimensional bounds Eλ(HM) ρ+ + 9nN/M\,\|Σi=1n Ai2\|op1/2 and Eλ(HM) ρ- - 9nN/M\,\|Σi=1n Ai2\|op1/2. With ρ* = \ρ+,-ρ-\, this yields E\|HM\|op ρ* + 9nN/M\,\|Σi=1n Ai2\|op1/2. For uniformly bounded positive coefficients, bounded n, and N=o(M), one obtains M∞E\|HM\|opρ whenever ρ*,Mρ. The proof is a matrix-coefficient extension of classical Sudakov--Fernique comparison, combined with a Davidson--Szarek-type singular-value estimate and dual variational formulas for Lehner's edge quantities over density matrices. We also explain why this approach does not extend sharply to signed Hermitian coefficients.