Structured matrix factorization length

Abstract

Every (resp. a generic) complex n × n matrix can be expressed as a product of 2n+5 (resp. n/2 +1) Toeplitz matrices. Motivated by this result, it is natural to ask the following question: what is the minimum number of Toeplitz matrices required to factor a given matrix? We generalize this question from Toeplitz structure to more general structures. In this paper, we introduce the notion of structured matrix factorization length when the set of matrices with a given structure is an affine variety X ⊂eq Cn × n. Then we introduce the r-th X-factorization variety, defined as the Zariski closure of the set of products of r matrices in X, and use it to define the border structured matrix factorization length. In particular, we study the cases in which X is the affine variety of Toeplitz, Hankel, bidiagonal, tridiagonal, skew-symmetric or companion matrices. We calculate the dimension of the X-factorization varieties for all these cases, and discuss how numerical algebraic geometry can be used to obtain computational evidence for the degrees of X-factorization varieties with an example. In addition, we propose methods for deriving lower and upper bounds for (border) structured matrix factorization length. For lower bounds, we develop a method based on displacement rank, which can also be used to obtain some defining equations of the r-th X-factorization variety; for upper bounds, we suggest an approach using alternating minimization.