Non-commutative Edmonds' problem and matrix semi-invariants

Abstract

In 1967, Edmonds introduced the problem of computing the rank over the rational function field of an n× n matrix T with integral homogeneous linear polynomials. In this paper, we consider the non-commutative version of Edmonds' problem: compute the rank of T over the free skew field. It is known that this problem relates to the ring of matrix semi-invariants. In particular, if the nullcone of matrix semi-invariants is defined by elements of degree ≤ σ, then there follows a poly(n, σ)-time randomized algorithm to decide whether the non-commutative rank of T is <n. To our knowledge, previously the best bound for σ was O(n2· 4n2) over algebraically closed fields of characteristic 0 (Derksen, 2001). In this article we prove the following results: (1) We observe that by using an algorithm of Gurvits, and assuming the above bound σ for R(n, m) over Q, deciding whether T has non-commutative rank <n over Q can be done deterministically in time polynomial in the input size and σ. (2) When F is large enough, we devise a deterministic algorithm for non-commutative Edmonds' problem in time polynomial in (n+1)!, with the following consequences. (2.a) If the commutative rank and the non-commutative rank of T differ by a constant, then there exists a randomized efficient algorithm that computes the non-commutative rank of T. (2.b) We prove that σ≤ (n+1)!. This not only improves the bound obtained from Derksen's work over algebraically closed field of characteristic 0 but, more importantly, also provides for the first time an explicit bound on σ for matrix semi-invariants over fields of positive characteristics.