NEPMiniMax: An Approach for NEPs Based on Matrix-valued Minimax Approximations
Abstract
We propose NEPMiniMax, a novel computational method for solving nonlinear eigenvalue problems (NEPs) T(λ)u= 0 on compact continua ⊂ C. The method combines two key components: (1) a rational minimax approximation scheme where the m-d-Lawson algorithm constructs a minimax rational approximation for the vector-valued function from T(x)'s split form, yielding a matrix-valued rational approximation R*(x) = P*(x)/q*(x) ≈ T(x), and (2) a structure-exploiting linearization technique. The minimax approximation guarantees uniform accuracy while generally keeping R*(x) pole-free in . Eigenpairs are then computed by solving a polynomial eigenvalue problem P*(λ) u= 0 via a strong linearization that exactly preserves eigenvalue multiplicities. Numerical experiments on benchmarks from the NLEVP collection demonstrate competitiveness with state-of-the-art methods (e.g., Beyn, NLEIGS, SV-AAA) in efficiency and accuracy, with theoretical error bounds directly relating eigenpair approximations to the rational approximation quality.
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