Tsai-Fu Wu

Origin of Power Converters


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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.

      A general question was brought up in last chapter on how to develop or derive PWM converters systematically. There are several approaches to developing converters based on switching cells, canonical converter cells, and switched capacitor/inductor cells, but they left a lot of questions behind without answers. In this book, our attempt is adopting from Charles Darwin's believe of evolution on which he published the book entitled On the Origin of Species. Similarly, we are intended to identify the origin of power converters, from which all of PWM power converters are evolved. The evolution mechanism and principle will be explored in later chapters. In this chapter, three approaches to creating the original converter, the buck converter, are discussed. Based on the original converter, we present three fundamental PWM converters that are used frequently in decoding and synthesizing converters. Their operational modes are discussed correspondingly to verify the evolved converters.

      Charles Darwin's dilemma is that if species are evolved from their ancestor species and if we keep tracking back to the origin, who is the original one and how to create or generate it? The same questions bother us: if PWM converters are evolved, which one is the origin and what is the mechanism to create it? In literature, there are many converters with various transfer codes, such as D/(1 − 2D), (1 − D)/(1 − 2D), D/(2 − D), D/2(1 − D), D2/(1 − D), etc., in which all of the combinational codes include the duty ratio D and it is just the transfer code of the buck converter in continuous conduction mode (CCM). Thus, we can intuitively reveal that buck converter is the original converter. In this book, we propose three approaches to creating the original converter.

      2.1.1 Source–Load Approach

      2.1.2 Proton–Neutron–Meson Analogy

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