English

Real root finding for determinants of linear matrices

Symbolic Computation 2014-12-19 v1 Algebraic Geometry

Abstract

Let \A0,\A1,,\An\A_0, \A_1, \ldots, \A_n be given square matrices of size mm with rational coefficients. The paper focuses on the exact computation of one point in each connected component of the real determinantal variety {\X\RRn:det(\A0+x1\A1++xn\An)=0}\{\X \in\RR^n \: :\: \det(\A_0+x_1\A_1+\cdots+x_n\A_n)=0\}. Such a problem finds applications in many areas such as control theory, computational geometry, optimization, etc. Using standard complexity results this problem can be solved using mO(n)m^{O(n)} arithmetic operations. Under some genericity assumptions on the coefficients of the matrices, we provide an algorithm solving this problem whose runtime is essentially quadratic in (n+mn)3{{n+m}\choose{n}}^{3}. We also report on experiments with a computer implementation of this algorithm. Its practical performance illustrates the complexity estimates. In particular, we emphasize that for subfamilies of this problem where mm is fixed, the complexity is polynomial in nn.

Keywords

Cite

@article{arxiv.1412.5873,
  title  = {Real root finding for determinants of linear matrices},
  author = {Didier Henrion and Simone Naldi and Mohab Safey El Din},
  journal= {arXiv preprint arXiv:1412.5873},
  year   = {2014}
}
R2 v1 2026-06-22T07:36:54.864Z