Figure 1.24 Four types of grafted switches: (a) T‐type, (b) inverse T‐type, (c) Π‐type, and (d) inverse Π‐type.
Note that for converter applications, the buck and the boost converters in cascade and with a simplified filter shown in Figure 1.25a are also feasible for their lower voltage stresses imposed on switches S1&S2 and diodes D1&D2, and Vi and Vo have a common voltage polarity, even though the cascaded converter requires two pairs of active–passive switches and more switch drivers.
Figure 1.25 Illustration of the buck‐boost converter derived with the graft switch technique.
The GST starts from dealing with two active switches, but in fact, it can be extended to any number of switches operated synchronously and with at least a common node. Moreover, with a transfer‐ratio decoding process, the GST can be applied to derive other PWM converters, including the converters shown in Figures 1.8–1.13.
Figure 1.26 Derivation of the buck‐boost converter with the converter layer technique.
Based on a transfer‐ratio decoding process, the converter layer technique (CLT) was proposed. With the CLT, the buck‐boost converter can be derived readily, as shown in Figure 1.26. Figure 1.26a shows a buck converter with its input‐to‐output voltage transfer ratio D. With a positive unity output feedback to the input, the input‐to‐output voltage transfer ratio can be determined as Vo/Vi = D/(1 − D), as shown in Figure 1.26b, which can be realized with the buck converter and a unity output feedback shown in Figure 1.26c. Redrawing the circuit in a well‐known form can be recognized as a buck‐boost converter, as shown in Figure 1.26d.
The GST can be equivalent to a converter feedforward approach, while the CLT is a feedback scheme. With these two techniques together, many new PWM converters can be derived. When further associated with the transfer‐ratio decoding process, more converters can be synthesized, and readers can understand the converter evolution mechanism or principle comprehensively.
1.5 Evolution
In “On the Origin of Species” by Charles Darwin, evolution is the primary principle of generating offsprings from the original species through natural selection. Evolution is the process of change in all forms of life over generations. Biological populations evolve through genetic changes that correspond to changes in the organisms' observable traits. Genetic changes include mutations, which are caused by damage or replication errors in organisms' DNA. As the genetic variation of a population drifts randomly over generations, natural selection gradually leads traits to become more or less common based on the relative reproductive success of organisms with those traits. The above statements are digested from “Introduction to Evolution” in Wikipedia. DNA carries codes for heredity through the mechanisms of replication, mutation, and natural selection in diverging species from the original one. Offsprings decode parental DNA for synthesizing all tissues and organs. In general, we are all a family and have the same ancestor.
Analogously, this book is entitled “Origin of Power Converters,” and we are searching for possible similar mechanisms for evolving power converters from the original converter. We will develop the decoding and synthesizing mechanisms for evolving power converters artificially. Additionally, we will make use of fundamental circuit theories to extend the converters with soft‐switching features and isolation.
1.6 About the Text
The objective of this book is to present approaches to decoding, synthesizing, and modeling PWM converters systematically and to provide readers a comprehensive understanding of converter evolution from the original converter. This book is divided into two parts.
1.6.1 Part I: Decoding and Synthesizing
Part I includes 11 chapters. They present an introduction, discovery of the original converter, some fundamentals related to power converter synthesis and evolution, illustration of converter synthesis approaches, synthesis of multistage/multilevel converters, extension of hard‐switching converters to soft‐switching ones, and determination of switch‐voltage stresses in the converters. Converters evolved from the original converter are the primary concept developed in this book.
Chapter 2 presents three approaches to creating the origin of power converters, including source–load, proton–neutron–meson, and resonant approaches. In addition, it reviews the properties and typical operation of three conventional PWM converters. Moreover, the conventional topological duality and current source are re‐examined to set up a foundation for later discussions on the development of new PWM converters.
During converter synthesis and evolution, several fundamental circuit theories and principles are used frequently, and they are briefly reviewed and presented in Chapter 3. The fundamentals include DC voltage/current offsetting, capacitor/inductor splitting, DC voltage blocking and filtering, magnetic coupling, DC transformer, switch/diode grafting, and layer scheme.
Chapter 4 first reviews several typical transfer codes, such as step‐down, step‐up, step‐up and step‐down, and ±step‐up and step‐down, from which a proper transfer code derived from the typical codes can be designed for the desired applications. Given a transfer ratio or code, we have to first decode it in terms of the codes of the original converter and its derivatives. Thus, the code configurations and decoding approaches are also presented in Chapter 4.
In Chapter 5, the conventional cell and synchronous switch approaches to developing power converters are first reviewed, from which their limitations are addressed. Then, we describe the principles of the proposed graft switch/diode techniques, and along with the code configurations, syntheses