Optimal e(γ+o(1))n-Approximation of the Permanent of Positive Semidefinite Matrices

Abstract

We determine, up to lower-order terms in the exponent, the best possible deterministic polynomial-time approximation ratio for the permanent of a Hermitian positive semidefinite matrix. If A 0 has no zero diagonal entry, d=rank(A), A=VV with V∈Cn× d full column rank, and v1,…,vn are the rows of V, define \[ Φ(V)=X 0 \Σi=1n (vi Xvi)+ X-tr X+d\, P(A)=eΦ(V). \] We prove the exact sandwich \[ e-γn P(A) per(A) P(A). \] Here γ is the Euler--Mascheroni constant. Since the maximization is concave, this gives a deterministic polynomial-time e(γ+)n-approximation for every >0. Combined with the previous e(γ-)n-hardness of approximation for positive semidefinite permanents, this resolves the optimal exponential approximation ratio for deterministic polynomial-time algorithms as e(γ+o(1))n, assuming P. The proof is an entropy argument applied to the standard Wick integral formula for per(A); the loss is exactly γ per factor because E[ T]=-γ for TExp(1). The result was obtained through interactions with GPT 5.5 Pro Extended: the first author's interaction was one-shot, while the second author's was a separate multi-turn interaction with high-level guidance. Both authors verified the theorem and proof. Codex was used to assemble and typeset the manuscript.