Symplectic Integration Schemes for Systems with Nonlinear Dissipation

Symplectic Integration Schemes for Systems with Nonlinear Dissipation

In previous work a variational integration scheme for mechanical systems containing linear dissipation was developed [1]. The key idea is to use a transmission line as the solution to a power-balancing control problem-in the physics literature controllers of this type are known as 'heat baths&#...

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Bibliographic Details
Published in:IEEE transactions on automatic control Vol. 68; no. 4; pp. 1 - 14
Main Authors: Limebeer, David J. N., Farshi, Farhang Haddad, Ober-Blobaum, Sina
Format: Journal Article
Language:English
Published: New York IEEE 01-04-2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Algorithms
Balancing
Closed loops
Damping
Dissipation
Feedback control
Force
Hamilton's principle
Mechanical systems
Nonlinear systems
Optimal control
Power transmission lines
Propagation losses
Shock absorbers
Transmission lines
Variational principles
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Summary:In previous work a variational integration scheme for mechanical systems containing linear dissipation was developed [1]. The key idea is to use a transmission line as the solution to a power-balancing control problem-in the physics literature controllers of this type are known as 'heat baths'. The power-balanced closed-loop system is thereby made amenable to analysis with Hamilton's principle. As a consequence, variational principles can be used to find symplectic integration schemes for dissipative systems. The outcome of this work is a coherent physical explanation as to why variational/symplectic integration algorithms for open dissipative system can perform as well as their conservative counterparts. An important application of these integration algorithms is the solution of long-time-horizon optimal control problems. In this paper these ideas are extended to systems with smooth memoryless nonlinear dissipation. This extension employs a nonlinear lossless transmission line, which is again the solution to a power-balancing control problem. As in the case of linear dissipation, the resulting variational integration schemes are demonstrated to have excellent numerical properties, which are significantly less demanding computationally than their implicit non-variational counterparts.
ISSN:0018-9286
1558-2523
DOI:10.1109/TAC.2023.3235908