On the Complexity of Noncommutative Polynomial Factorization

Abstract

In this paper we study the complexity of factorization of polynomials in the free noncommutative ring F x1,x2,…,xn of polynomials over the field F and noncommuting variables x1,x2,…,xn. Our main results are the following. Although F x1,x2,…,xn is not a unique factorization ring, we note that variable-disjoint factorization in F x1,x2,…,xn has the uniqueness property. Furthermore, we prove that computing the variable-disjoint factorization is polynomial-time equivalent to Polynomial Identity Testing (both when the input polynomial is given by an arithmetic circuit or an algebraic branching program). We also show that variable-disjoint factorization in the black-box setting can be efficiently computed (where the factors computed will be also given by black-boxes, analogous to the work [KT91] in the commutative setting). As a consequence of the previous result we show that homogeneous noncommutative polynomials and multilinear noncommutative polynomials have unique factorizations in the usual sense, which can be efficiently computed. Finally, we discuss a polynomial decomposition problem in F x1,x2,…,xn which is a natural generalization of homogeneous polynomial factorization and prove some complexity bounds for it.