Reciprocity of Nonlinear Systems

Arjan van der Schaft

doi:10.1137/24M1629250

Reciprocity of Nonlinear Systems

Arjan van der Schaft^*

^*Corresponding author for this work

Bernoulli Institute

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Reciprocity of linear input-output systems is defined as symmetry of its impulse response or transfer matrix. In the famous 1972 paper by Willems [Dissipative dynamical systems, part II: Linear systems with quadratic supply rates, Arch. Ration. Mech. Anal., 45, pp. 352-393] it was shown how reciprocity can be reflected in the state space realization. Furthermore, it was shown how to combine reciprocity with passivity in order to obtain state space realizations with physically motivated properties, including relaxation systems. The current paper is concerned with the extension of this theory to the nonlinear case. Emphasis is on nonlinear reciprocal systems with a Hessian pseudo-Riemannian metric. The combination of reciprocity with passivity is elucidated from a port-Hamiltonian perspective.

Original language	English
Pages (from-to)	3019-3041
Number of pages	23
Journal	SIAM Journal on Control and Optimization
Volume	62
Issue number	6
DOIs	https://doi.org/10.1137/24M1629250
Publication status	Published - 2024

Keywords

gradient system
Hessian Riemannian metric
Lagrangian submanifold
Legendre transformation
monotonicity
passivity
symmetry

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title = "Reciprocity of Nonlinear Systems",

abstract = "Reciprocity of linear input-output systems is defined as symmetry of its impulse response or transfer matrix. In the famous 1972 paper by Willems [Dissipative dynamical systems, part II: Linear systems with quadratic supply rates, Arch. Ration. Mech. Anal., 45, pp. 352-393] it was shown how reciprocity can be reflected in the state space realization. Furthermore, it was shown how to combine reciprocity with passivity in order to obtain state space realizations with physically motivated properties, including relaxation systems. The current paper is concerned with the extension of this theory to the nonlinear case. Emphasis is on nonlinear reciprocal systems with a Hessian pseudo-Riemannian metric. The combination of reciprocity with passivity is elucidated from a port-Hamiltonian perspective.",

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AB - Reciprocity of linear input-output systems is defined as symmetry of its impulse response or transfer matrix. In the famous 1972 paper by Willems [Dissipative dynamical systems, part II: Linear systems with quadratic supply rates, Arch. Ration. Mech. Anal., 45, pp. 352-393] it was shown how reciprocity can be reflected in the state space realization. Furthermore, it was shown how to combine reciprocity with passivity in order to obtain state space realizations with physically motivated properties, including relaxation systems. The current paper is concerned with the extension of this theory to the nonlinear case. Emphasis is on nonlinear reciprocal systems with a Hessian pseudo-Riemannian metric. The combination of reciprocity with passivity is elucidated from a port-Hamiltonian perspective.

KW - gradient system

KW - Hessian Riemannian metric

KW - Lagrangian submanifold

KW - Legendre transformation

KW - monotonicity

KW - passivity

KW - symmetry

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VL - 62

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EP - 3041

JO - SIAM Journal on Control and Optimization

JF - SIAM Journal on Control and Optimization

IS - 6

ER -

Reciprocity of Nonlinear Systems

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Keywords

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