FREQUENCY DOMAIN CLOSED-LOOP ANALYSIS AND SLIDING MODE CONTROL OF A NONMINIMUM PHASE BUCK–BOOST CONVERTER

Zengshi Chen, Wenzhong Gao, and Xiao Ye

References

1. [1] N. Mohan, T.M. Undeland, & W.P. Robbins, Power electronics converters, applications, and design (New York: Wiley, 2003).
2. [2] D. Xu, C. Zhao, & H. Fan, A PWM plus phase shift control bidirectional DC-DC converter, IEEE Transactions on Power Electronics, 19(3), 2004, 667–675.
3. [3] H. Sira-Ramirez & R. Silva-Origoza, Control design techniques in power electronics devices (New Mexico: Springer, 2006).
4. [4] R.W. Erickson & D. Maksimovic, Fundamentals of power electronics (New York: Kluwer Academic Publishers, 2004).
5. [5] K.M. Smedley & S. Cuk, One-cycle control of switching converters, IEEE Transactions on Power Electronics, 10(6), 1995, 625–633.
6. [6] H.E. Fadil & F. Giri, Robust control of interleaved synchronous PWM buck converters, Control and Intelligent Systems, 36(4), 2008, 340–346.
7. [7] E. Santi, et al., Synergetic control for DC-DC boost converter: implementation options, IEEE Transactions on Industry Applications, 39(6), 2003, 1803–1813.
8. [8] T.Y. Jiang & R. Dougal, Synergetic control of power converters for pulse current charging of advanced batteries from a fuel cell power source, IEEE Transactions on Power Electronics, 19(4), 2004, 1140–1150.
9. [9] V.I. Utkin, J. Guldner, & J.X. Shi, Sliding mode control in electromechanical systems (New York: CRC Press, 2008).
10. [10] K.D. Young, V.I. Utkin, & U. Ozguner, A control engineer’s guide to sliding mode control, IEEE Transactions on Control Systems Technology, 7(3), 328–341.
11. [11] B.J. Cardoso, et al., Analysis of switching frequency reduction methods applied to sliding mode controlled DC-DC converters, Proc. Applied Power Electronics Conf. Exposition, Boston, MA, USA, 1992.
12. [12] H. Guldemir, Sliding mode control of DC-DC boost converter, Journal of Applied Sciences, 5(3), 2005, 588–592.
13. [13] Y. He & F.L. Luo, Study of sliding mode control for DCDC converters, Proc. Power System Technology Conf., 2004, Singapore.
14. [14] K. Al-Hosani, A. Malinin, & V.I. Utkin, Sliding mode PID control of buck converters, Proc. European Control Conf., 2009, Budapest, Hungary.
15. [15] R. Anasraj & S. Thomas, Initial conditions based sliding mode controller design for improved performance of buck converter, Control and Intelligent Systems, 37(4), 2009, 235–242.
16. [16] S.G. Kadwane, et al., Practical implementation of sliding mode like control for DC-DC converter, Control and Intelligent Systems, 36(3), 2008, 260–266.
17. [17] A.V. Mayakkannan & S. Rajapandian, Modeling and analysis of sliding mode controller for buck-boost converter, International Journal of Electrical and Power Engineering, 2(3), 2008, 147–153.
18. [18] Z.S. Chen, Modeling, analysis and simulation of a buck converter under cascade control, http://www.paper.edu.cn/index. php/default/en_releasepaper/content/4380293.
19. [19] Z. Jiang & R. Dougal, Design and testing of a fuel-cell-powered battery-charging station, Journal of Power Sources, 115(2), 2003, 148–153.
20. [20] V.I. Utkin, Sliding mode control design principle and applications to electric drives, IEEE Transactions on Industrial Electronics, 3(40), 23–36.
21. [21] G.F. Franklin, J.D. Powell, & E.N. Abbas, Feedback control of dynamic systems (New York: Addison Wesley, 1991).
22. [22] W.G. Yan, et al., Sliding mode pulsewidth modulation, IEEE Transactions on Power Electronics, 23(2), 2008, 619–626.

Important Links:

• Abstract
• DOI: 10.2316/Journal.201.2010.4.201-2231
• From Journal (201) Mechatronic Systems and Control (formerly Control and Intelligent Systems) - 2010

Go Back