An LMI Approach for Stability Analysis and Output-Feedback Stabilization of Discrete-Time Lur’e Systems Using Zames-Falb Multipliers

Abstract: This paper investigates the problem of stability analysis and output-feedback stabilization of discrete-time Lur'e systems where the nonlinearity is odd and slope bounded. Using the linear matrix inequality (LMI) conditions from the literature to handle the 1 norm and positive realness constraints, an iterative algorithm based on LMIs is constructed to assess stability through the existence of a Zames-Falb multiplier of any given order based on independent positive definite matrices for the 1 norm and positive… Show more

“…Example Consider the six systems investigated in Experiment 1 of Reference 30. The objective is to obtain the maximum value of $$$ \Omega $$$ considering sector bounded nonlinearities and the maximum value of $$$ \Omega =\Lambda $$$ for slope bounded nonlinearities.…”

“…The objective is to obtain the maximum value of $$$ \Omega $$$ considering sector bounded nonlinearities and the maximum value of $$$ \Omega =\Lambda $$$ for slope bounded nonlinearities. In the former case, Algorithm 1 is compared with BPOV20, and in the latter with BOVP22 30 . Both state‐ and output‐feedback control laws are investigated.…”

“…In the former case, Algorithm 1 is compared with BPOV20, and in the latter with BOVP22. 30 Both stateand output-feedback control laws are investigated. All methods were tested with it max = 50 and the results are shown in Table 4.…”

“…Values of Ω Σ and Λ Σ of the output-feedback stabilization problem of Example 2 considering the design conditions from KB17, 18 BPOV20,19 and Algorithm 1 (sector bounded) and Algorithm 1 (sector and slope bounded) Maximum values of Ω (sector bounded) and Ω = Λ (slope bounded) obtained by Algorithm 1, BOVP22,30 and BPOV2019 for state-and output-feedback stabilization in Example 3 (it max = 50 in all cases)…”

Control design of uncertain discrete‐time Lur'e systems with sector and slope bounded nonlinearities

“…Example Consider the six systems investigated in Experiment 1 of Reference 30. The objective is to obtain the maximum value of $$$ \Omega $$$ considering sector bounded nonlinearities and the maximum value of $$$ \Omega =\Lambda $$$ for slope bounded nonlinearities.…”

“…The objective is to obtain the maximum value of $$$ \Omega $$$ considering sector bounded nonlinearities and the maximum value of $$$ \Omega =\Lambda $$$ for slope bounded nonlinearities. In the former case, Algorithm 1 is compared with BPOV20, and in the latter with BOVP22 30 . Both state‐ and output‐feedback control laws are investigated.…”

“…In the former case, Algorithm 1 is compared with BPOV20, and in the latter with BOVP22. 30 Both stateand output-feedback control laws are investigated. All methods were tested with it max = 50 and the results are shown in Table 4.…”

“…Values of Ω Σ and Λ Σ of the output-feedback stabilization problem of Example 2 considering the design conditions from KB17, 18 BPOV20,19 and Algorithm 1 (sector bounded) and Algorithm 1 (sector and slope bounded) Maximum values of Ω (sector bounded) and Ω = Λ (slope bounded) obtained by Algorithm 1, BOVP22,30 and BPOV2019 for state-and output-feedback stabilization in Example 3 (it max = 50 in all cases)…”

Control design of uncertain discrete‐time Lur'e systems with sector and slope bounded nonlinearities

“…The stability of Lur'e models is a classical problem, expressed by the Aizerman conjecture for sectorbounded nonlinearities [17], [18], [19]. Although the Aizerman conjecture is false, the stability of Lur'e models has been widely studied in both continuous time [20], [21], [22], [23], [24], [25], [26], [27], [28], [29], [30], [31] and discrete time [32], [33], [34], [35], [36], [37], [38], [39], [40], [41], [42], [43], [44], [45].…”

Identification of Self-Excited Systems Using Discrete-Time, Time-Delayed Lur'e Models

Robustness analysis of gain‐scheduled Model Predictive Control for Linear Parameter Varying systems: An Integral Quadratic Constraints approach