Infinite GMRES for parameterized linear systems

Abstract

We consider linear parameter-dependent systems A(μ) x(μ) = b for many different μ, where A is large and sparse, and depends nonlinearly on μ. Solving such systems individually for each μ would require great computational effort. In this work we propose to compute a partial parameterization x ≈ x(μ) where x(μ) is cheap to compute for many different μ. Our methods are based on the observation that a companion linearization can be formed where the dependence on μ is only linear. In particular, we develop methods which combine the well-established Krylov subspace method for linear systems, GMRES, with algorithms for nonlinear eigenvalue problems (NEPs) to generate a basis for the Krylov subspace. Within this new approach, the basis matrix is constructed in three different ways, using a tensor structure and exploiting that certain problems have low-rank properties. We show convergence factor bounds obtained similarly to those for the method GMRES for linear systems. More specifically, a bound is obtained based on the magnitude of the parameter μ and the spectrum of the linear companion matrix, which corresponds to the reciprocal solutions to the corresponding NEP. Numerical experiments illustrate the competitiveness of our methods for large-scale problems. The simulations are reproducible and publicly available online.