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Further Reading

Оглавление

1 Anderson, J. and Peng, F.Z. (2008a). Four quasi‐Z source inverters. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 2743–2749.

2 Anderson, J. and Peng, F.Z. (2008b). A class of quasi‐Z source inverters. Proceedings of the IEEE Industrial Application Meeting, pp. 1–7.

3 Axelrod, B., Borkovich, Y., and Ioinovici, A. (2008). Switched‐capacitor/switched‐inductor structures for getting transformerless hybrid dc‐dc PWM converters. IEEE Trans. Circuits Syst. I 55 (2): 687–696.

4  Berkovich, Y., Shenkman, A., Ioinovici, A., and Axelrod, B. (2006). Algebraic representation of DC‐DC converters and symbolic method of their analysis. Proceedings of the IEEE Convention. Electrical and Electronics Engineers, pp. 47–51.

5 Berkovich, Y., Axelrod, B., Tapuchi, S., and Ioinovici, A. (2007). A family of four‐quadrant, PWM DC‐DC converters. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 1878–1883.

6 Bhat, A.K.S. and Tan, F.D. (1991). A unified approach to characterization of PWM and quasi‐PWM switching converters: topological constraints, classification, and synthesis. IEEE Trans. Power Electron. 6 (4): 719–726.

7 Bryant, B. and Kazimierczuk, M.K. (2002). Derivation of the buck‐boost PWM DC‐DC converter circuit topology. Proc. IEEE Int. Symp. Circuits Syst. 5: 841–844.

8 Bryant, B. and Kazimierczuk, M.K. (2003). Derivation of the Ćuk PWM DC‐DC converter circuit topology. Proc. IEEE Int. Symp. Circuits Syst. 3: 292–295.

9 Cao, D. and Peng, F.Z. (2009). A family of Z source and quasi‐Z source DC‐DC converters. Proceedings of the IEEE Applied Power Electronics Conference, pp. 1097–1101.

10 Ćuk, S. (1979). General topological properties of switching structures. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 109–130.

11 Erickson, R.W. (1983). Synthesis of switched‐mode converters. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 9–22.

12 Freeland, S.D. (1992). Techniques for the practical applications of duality to power circuits. IEEE Trans. Power Electron. 7 (2): 374–384.

13 Hopkins, D.C. and Root, D.W. Jr. (1994). Synthesis of a new class of converters that utilize energy recirculation. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 1167–1172.

14 Khan, F.H., Tolbert, L.M., and Peng, F.Z. (2006). Deriving new topologies of DC‐DC converters featuring basic switching cells. Proceedings of the IEEE Workshops on Computers in Power Electronics, pp. 328–332.

15 Lee, F.C. (1989). High‐Frequency Resonant, Quasi‐Resonant and Multi‐Resonant Converters. Virginia Power Electronics Center.

16 Liu, K.‐H. and Lee, F.C. (1988). Topological constraints of basic PWM converters. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 164–172.

17 Makowski, M.S. (1993). On topological assumptions on PWM converters: a re‐examination. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 141–147.

18 Maksimovic, D. and Ćuk, S. (1989). General properties and synthesis of PWM DC‐to‐DC converters. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 515–525.

19 Ogata, M. and Nishi, T. (2003). Topological criteria for switched mode DC‐DC converters. Proc. IEEE Int. Symp. Circuits Syst. 3: 184–187.

20  Peng, F.Z. (2003). Z source inverter. IEEE Trans. Ind. Appl. 39 (2): 504–510.

21 Peng, F.Z., Joseph, A., Wang, J. et al. (2005a). Z source inverter for motor drives. IEEE Trans. Power Electron. 20 (4): 857–863.

22 Peng, F.Z., Tolbert, L.M., and Khan, F.H. (2005b). Power electronic circuit topology – the basic switching cells. Proceedings of the IEEE Power Electronics Education Workshop, pp. 52–57.

23 Qian, W., Peng, F.Z., and Cha, H. (2011). Trans‐Z source inverters. IEEE Trans. Power Electron. 26 (12): 3453–3463.

24 Severns, R.P. and Bloom, G.E. (1985). Modern DC‐to‐DC Switch Mode Power Converter Circuits. New York: Van Nonstrand Reinhold Co.

25 Tolbert, L. M., Peng, F.Z., Khan, F.H., and Li, S. (2009). Switching cells and their implications for power electronic circuits. Proceedings of the IEEE International Power Electronics and Motion Control Conference, pp. 773–779.

26 Tymerski, R. and Vorperian, V. (1986). Generation, classification and analysis of switched‐mode DC‐to‐DC converters by the use of converter cells. Proceedings of the International Telecommunications Energy Conference, pp. 181–195.

27 Williams, B.W. (2008). Basic DC‐to‐DC converters. IEEE Trans. Power Electron. 23 (1): 387–401.

28 Williams, B.W. (2014). Generation and analysis of canonical switching cell DC‐to‐DC converters. IEEE Trans. Ind. Electron. 61: 329–346.

29 Wu, T.‐F. and Chen, Y.‐K. (1996). A systematic and unified approach to modeling PWM DC/DC converters using the layer scheme. Proceedings of the IEEE Power Electronics Specialists Conference, pp. 575–580.

30 Wu, T.‐F. and Yu, T.‐H. (1998). Unified approach to developing single‐stage power converters. IEEE Trans. Aerosp. Electron. Syst. 34 (1): 221–223.

31 Wu, T.‐F., Liang, S.‐A., and Chen, Y.‐K. (2003). A structural approach to synthesizing soft switching PWM converters. IEEE Trans. Power Electron. 18 (1): 38–43.

Origin of Power Converters

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