Solving generic parametric linear matrix inequalities

Abstract

We consider linear matrix inequalities (LMIs) A = A0 + x1 A1 + ... + xn An 0 with the Ai's being m × m symmetric matrices, with entries in a ring R. When R = R, the feasibility problem consists in deciding whether the xi's can be instantiated to obtain a positive semidefinite matrix. When R = Q[y1, ... , yt], the problem asks for a formula on the parameters y1, ..., yt, which describes the values of the parameters for which the specialized LMI is feasible. This problem can be solved using general quantifier elimination algorithms, with a complexity that is exponential in n. In this work, we leverage the LMI structure of the problem to design an algorithm that computes a formula describing a dense subset of the feasible region of parameters, under genericity assumptions. The complexity of this algorithm is exponential in n, m and t but becomes polynomial in n when m and t are fixed. We apply the algorithm to a parametric sum-of-squares problem and to the convergence analyses of certain first-order optimization methods, which are both known to be equivalent to the feasibility of certain parametric LMIs, hence demonstrating its practical interest.

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