Finite-time stabilization of Port-Controlled Hamiltonian systems with application to nonlinear affine systems

Authors

null Yuzhen Wang, Gang Feng

Abstract

The finite-time stabilization of nonlinear Port-Controlled Hamiltonian (PCH) systems is investigated in this paper, and a number of approaches to the finite-time control design are proposed. Based on a finite-time stability criterion and the so-called “energy shaping plus damping injection” technique, the continuous finite-time stabilization problem is studied for the PCH systems, and several global stabilization results are obtained. Via Hamiltonian realization, the results obtained for the Hamiltonian systems are applied to investigate continuous finite-time stabilization of nonlinear affine systems, and several global control design results are presented. Study on several examples shows that the control design approaches developed in this paper work very well.

Citation

• Journal: 2008 American Control Conference
• Year: 2008
• Volume:
• Issue:
• Pages: 1202–1207
• Publisher: IEEE
• DOI: 10.1109/acc.2008.4586656

BibTeX

@inproceedings{Yuzhen_Wang_2008,
  title={{Finite-time stabilization of Port-Controlled Hamiltonian systems with application to nonlinear affine systems}},
  DOI={10.1109/acc.2008.4586656},
  booktitle={{2008 American Control Conference}},
  publisher={IEEE},
  author={Yuzhen Wang and Feng, Gang},
  year={2008},
  pages={1202--1207}
}

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References

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