2017
DOI: 10.1137/15m1025426
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The RKFIT Algorithm for Nonlinear Rational Approximation

Abstract: Abstract. The RKFIT algorithm outlined in [M. Berljafa and S. Güttel, SIAM J. Matrix Anal. Appl., 36 (2015), pp. 894-916] is a Krylov-based approach for solving nonlinear rational least squares problems. This paper puts RKFIT into a general framework, allowing for its extension to nondiagonal rational approximants and a family of approximants sharing a common denominator. Furthermore, we derive a strategy for the degree reduction of the approximants, as well as methods for their conversion to partial fraction … Show more

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Cited by 83 publications
(80 citation statements)
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“…Nevertheless, in some case the Gauss-Jacobi quadrature applied to (8) converges faster than the same method applied to (7). We analyse the convergence just for z ∈ R + , because we want to apply the formulae to matrices having positive real eigenvalues and the convergence of the quadrature formulae for matrices follows from the convergence of the same formulae for their eigenvalues.…”
Section: Integral Representations Formentioning
confidence: 99%
See 1 more Smart Citation
“…Nevertheless, in some case the Gauss-Jacobi quadrature applied to (8) converges faster than the same method applied to (7). We analyse the convergence just for z ∈ R + , because we want to apply the formulae to matrices having positive real eigenvalues and the convergence of the quadrature formulae for matrices follows from the convergence of the same formulae for their eigenvalues.…”
Section: Integral Representations Formentioning
confidence: 99%
“…For the rational Krylov methods, the poles are chosen according to either the adaptive strategy by Güttel and Knizhnerman [24] or the function rkfit from the rktoolbox [5], based on an algorithm by Berljafa and Güttel [6,7]. In our implementation, when the matrices are larger than 1000 × 1000, we get the poles by running rkfit on a surrogate problem of size 1000 × 1000 whose setup requires a rough estimate of the extrema of the spectrum of A −1 B.…”
Section: Computing (A# T B)mentioning
confidence: 99%
“…Substituting (22) into (21), which is then substituted into (20), yields The upper bound follows by taking norms on both sides.…”
Section: Subsystem Model Reductionmentioning
confidence: 99%
“…This is a nonnormal matrix, and its eigenvalues are shown in Figure 2(a), together with the m = 16 poles used in this example. The poles are obtained using the RKFIT algorithm [5,6] and optimized for approximating exp(A)b, where the starting vector b has all its entries equal to 1. (A similar example is considered in [5, sect.…”
Section: Condition Number Of the Arnoldi Basis Asvmentioning
confidence: 99%
“…8.5]), these methods have seen an increasing number of other applications over the last two decades or so. Examples of rational Krylov applications can be found in model order reduction [11,16,17,22], matrix function approximation [10,13,19], matrix equations [3,9,24], nonlinear eigenvalue problems [20,21,31], and nonlinear rational least squares fitting [5,6].At the core of most rational Krylov applications is the rational Arnoldi algorithm, which is a Gram-Schmidt procedure for generating an orthonormal basis of a rational Krylov space. Given a matrix A ∈ C N,N , a vector b ∈ C N , and a polynomial q m of degree at most m and such that q m (A) is nonsingular, the rational Krylov space of order m is defined as…”
mentioning
confidence: 99%