The modeling and control of Buck-Boost converter based on energy-shaping theory

Authors

null Yong Wang, null Haisheng Yu, null Jinpeng Yu

Abstract

The model and PWM controller of Buck-Boost converter are presented based on a novel energy-shaping theory. Firstly, a port-controlled Hamiltonian (PCH) model of Buck-Boost converter and its suitable state space averaging (SSA) model are established. Secondly, using the energy-shaping theory of interconnection and damping assignment passivity-based control (IDA-PBC) techniques, the feedback control theory of Buck-Boost converter is given. Then the desired equilibrium point of the system is obtained, and the stability of equilibrium point is analyzed. Finally the feedback controller is developed using energy-shaping theory for the SSA model of the PCH system. Furthermore, an integrator is added around the passive output preserving stability to avoid steady state errors induced by the presence of noise and modeling errors. Simulation results for the full system confirm the correctness and efficiency of the obtained controller.

Citation

Journal: 2008 IEEE International Conference on Industrial Technology
Year: 2008
Volume:
Issue:
Pages: 1–6
Publisher: IEEE
DOI: 10.1109/icit.2008.4608311

BibTeX

@inproceedings{Yong_Wang_2008,
  title={{The modeling and control of Buck-Boost converter based on energy-shaping theory}},
  DOI={10.1109/icit.2008.4608311},
  booktitle={{2008 IEEE International Conference on Industrial Technology}},
  publisher={IEEE},
  author={Yong Wang and Haisheng Yu and Jinpeng Yu},
  year={2008},
  pages={1--6}
}

Download the bib file

References

Yu, H., Hou, J. & Wang, Y. Maximum Output Power Control of Permanent Magnet Synchronous Motor Based on Energy-shaping Principle. 2007 IEEE International Conference on Automation and Logistics 2008–2012 (2007) doi:10.1109/ical.2007.4338904 – 10.1109/ical.2007.4338904
tian, simulation and control of cuk converter based on energy-shaping. Journal of Qingdao University (2006)
tian, nonlinear control of dc/dc converter based on energy-shaping. DCDIS Series B (2007)
Fukuda, S. LQ control of sinusoidal current PWM rectifiers. IEE Proc., Electr. Power Appl. 144, 95 (1997) – 10.1049/ip-epa:19970939
yue, one-cycle control of switching converters. IEEE Trans on Power Electronics (1995)
xu, Modeling and Control of Power Electronic Equipments System (2005)
yu, mtpa control of pmsm based on port-controlled hamiltonian theory. Proceedings of the CESS (2006)
Ortega, R., Loría, A., Nicklasson, P. J. & Sira-Ramírez, H. Passivity-Based Control of Euler-Lagrange Systems. Communications and Control Engineering (Springer London, 1998). doi:10.1007/978-1-4471-3603-3 – 10.1007/978-1-4471-3603-3
Ortega, R., van der Schaft, A., Maschke, B. & Escobar, G. Interconnection and damping assignment passivity-based control of port-controlled Hamiltonian systems. Automatica 38, 585–596 (2002) – 10.1016/s0005-1098(01)00278-3
Putting energy back in control. IEEE Control Syst. 21, 18–33 (2001) – 10.1109/37.915398
Habetler, T. G. & Harley, R. G. Power electronic converter and system control. Proc. IEEE 89, 913–925 (2001) – 10.1109/5.931488
(0)
Ortega, R. & García-Canseco, E. Interconnection and Damping Assignment Passivity-Based Control: A Survey. European Journal of Control 10, 432–450 (2004) – 10.3166/ejc.10.432-450