Add to ORKGIn this paper we propose a new algorithm for solving large-scale algebraic Riccati equations with low-rank structure. The algorithm is based on the found Toeplitz-structured closed form of the stabilizing solution and the fast Fourier transform. It works without unnecessary assumptions, shift selection trategies, or matrix calculations of the cubic order with respect to the problem scale. Numerical examples are given to illustrate its features. Besides, we show that it is theoretically equivalent to several algorithms existing in the literature in the sense that they all produce the same sequence under the same parameter setting.Comment: 28 pages, 1 figur
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In this paper, we discuss numerical methods for solving large-scale continuous-time algebraic Riccat...
We describe a procedure based on the Krawczyk method to compute a verified enclosure for the stabili...
In this paper we discuss the convergence of a stabilization algorithm based on a singular version of...
Algebraic Riccati equations with indefinite quadratic terms play an important role in applications r...
AbstractWe consider the solution of large-scale algebraic Riccati equations with numerically low-ran...
In the numerical solution of the algebraic Riccati equation A∗X + XA - XBB∗X + C∗C = 0, where A is l...
The Matlab code provided here generates Figure 1 and Table 1 given in Section 6 of the paper "On a f...
AbstractIn the present work, we present a numerical method for the computation of approximate soluti...
AbstractIn this paper we discuss the convergence of a stabilization algorithm based on a singular ve...
We consider the numerical solution of large-scale symmetric differential matrix Riccati equations. U...
In the numerical solution of the algebraic Riccati equation $A^* X + XA â XBB^â X + C^â C = 0$...
AbstractWe present some recurrences that are the basis for an algorithm to invert an n×n Toeplitz sy...
The numerical solution of Stein (aka discrete Lyapunov) equations is the primary step in Newton's me...
AbstractWe present new algorithms for the numerical approximation of eigenvalues and invariant subsp...
We consider the numerical solution of the continuous algebraic Riccati equation A*X + XA − XFX + G =...
In this paper, we discuss numerical methods for solving large-scale continuous-time algebraic Riccat...
We describe a procedure based on the Krawczyk method to compute a verified enclosure for the stabili...
In this paper we discuss the convergence of a stabilization algorithm based on a singular version of...