论文信息 - Thermodynamic Stabilization via Energy Dissipating Hybrid Controllers

Thermodynamic Stabilization via Energy Dissipating Hybrid Controllers

A novel class of fixed-order, energy-based hybrid controllers is proposed as a means for achieving enhanced energy dissipation in Euler-Lagrange, port-controlled Hamiltonian, and lossless dynamical systems. These dynamic controllers combine a logical switching architecture with continuous dynamics to guarantee that the system plant energy is strictly decreasing across switchings. The general framework leads to closed-loop systems described by impulsive differential equations. In addition, we construct hybrid dynamic controllers that guarantee that the closed-loop system is consistent with basic thermodynamic principles. In particular, the existence of an entropy function for the closed-loop system is established that satisfies a hybrid Clausius-type inequality. Special cases of energy-based hybrid controllers involving state-dependent switching are described.

[1] Dennis S. Bernstein,et al. Resetting Virtual Absorbers for Vibration Control , 2000 .

[2] Wassim M. Haddad,et al. Non-linear impulsive dynamical systems. Part I: Stability and dissipativity , 2001 .

[3] Wassim M. Haddad,et al. Thermodynamic modeling, energy equipartition, and nonconservation of entropy for discrete-time dynamical systems , 2005 .

[4] Dennis S. Bernstein,et al. Resetting Virtual Absorbers for Vibration Control , 1997, Proceedings of the 1997 American Control Conference (Cat. No.97CH36041).

[5] V. Lakshmikantham,et al. Theory of Impulsive Differential Equations , 1989, Series in Modern Applied Mathematics.

[6] J. Willems. Dissipative dynamical systems part I: General theory , 1972 .

[7] Romeo Ortega,et al. Passivity-based Control of Euler-Lagrange Systems , 1998 .

[8] S. Bhat,et al. An invariance principle for nonlinear hybrid and impulsive dynamical systems , 2003 .