Enforcing stability through ellipsoidal inner approximations in the indirect approach for continuous-time system identification

Gonzalez, Rodrigo A.; Welsh, James S.; Rojas, Cristian R.

Title: Enforcing stability through ellipsoidal inner approximations in the indirect approach for continuous-time system identification
Creator: Gonzalez, Rodrigo A.; Welsh, James S.; Rojas, Cristian R.
Relation: 21st IFAC World Congress on Automatic Control - Meeting Societal Challenges. Proceedings of the 21st IFAC World Congress on Automatic Control - Meeting Societal Challenges, Vol. 53 No. 2 (Berlin, Germany 12-17 July, 2020) p. 566-571
Publisher Link: http://dx.doi.org/10.1016/j.ifacol.2020.12.492
Publisher: Elsevier
Resource Type: conference paper
Date: 2020
Description: Recently, a new indirect approach method for continuous-time system identification has been proposed that provides complete freedom on the number of poles and zeros of the linear and time-invariant continuous-time model structure. However, this procedure has reliability issues, as it may deliver unstable estimates even if the initialisation model and true system are stable. In this paper, we propose a method to overcome this problem. By generating ellipsoids that contain parameter vectors whose coefficients yield stable polynomials, we introduce a convex constraint in the indirect prediction error method formulation, and show that the proposed method enjoys optimal asymptotic properties while being robust in small and noisy data set scenarios. The effectiveness of the novel method is tested through extensive simulations.
Subject: system identification; continuous-time systems; stability; sampled data
Identifier: http://hdl.handle.net/1959.13/1437585
Identifier: uon:40397
Identifier: ISSN:24058963
Language: eng
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