An algebraic characterization of non-singular matrix semicircles

Abstract

Let A1, …, Ar be Hermitian n × n matrices and S = Σ Ai si the associated matrix semicircle, where s1, …, sr are free semicircular variables. We prove that the following are equivalent: (i) the matrix pencil A = Σ Ai xi is LR-semisimple (decomposes, up to left--right equivalence, as a direct sum of unsplittable pencils); (ii) S is non-singular at t = 0 (the matrix-valued Cauchy transform has a continuous boundary limit near the origin); (iii) the covariance map η X Σ Ai X Ai is symmetrically DS-scalable (there exists C 0 with η(C) = C-1). When these hold, the spectral density satisfies f(0) = 1π\,tr(C), where C is the unique trace minimizer of the solution set \W 0 : η(W)\,W = I\. The proof combines algebraic and analytic ingredients. On the algebraic side, we establish the equivalence (i) (iii) using Gurvits' capacity theory for indecomposable maps and a geodesic reflection theorem in the Riemannian manifold of positive definite matrices, which upgrades DS-scalability to symmetric DS-scalability for self-adjoint completely positive maps. On the analytic side, we prove (iii) ⇒ (ii) via a Lyapunov--Schmidt reduction of Speicher's equation at a trace-minimizing solution, showing that the Jacobian of the bifurcation equations is positive definite. This removes a stability hypothesis that was required in earlier approaches.