Power Electronics and Energy Conversion Systems, Switched-capacitor and Switched-inductor Converters - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Power Electronics and Energy Conversion Systems, Switched-capacitor and Switched-inductor Converters write by Adrian Ioinovici. This book was released on 2020-09-21. Power Electronics and Energy Conversion Systems, Switched-capacitor and Switched-inductor Converters available in PDF, EPUB and Kindle. The second book of a five-volume reference guide to electronic circuits outlining and comparing classic and up-to-date energy conversion solutions, this book presents the latest switched-capacitor converters and their various applications This unique and comprehensive five volume set (totalling 2144pp) focuses on the study of both classical and state-of-the-art power conversion electronic circuits, and their wide variety of applications in electronic equipment. It includes many recent research advancements that have been previously unpublished and that are currently impacting the industry. Each volume is organised in basic-to-sophisticated crescendo, appealing to senior undergraduate and graduate electrical engineering minor students and major students, researchers and designers. Each volume builds on the previous volume, with a structure that facilitates access to most complex solutions for all readers. Volume II is split into two parts. The first part covers state-of-the-art switched-capacitor (SC) converters, commonly used in hand-held devices and personal communications equipment. The authors discuss their original work, shedding light on power converters that are used in all current modems, servers and mobile applications. The second part of this book looks at converters with high DC voltage ratio. The unique material gives a clear explaination of converters in the telecommunication industry, and those that are associated with alternative sources of energy. Covers all the latest updates to switched-capacitor converter technology, including work originally pioneered by the Authors Explains power converters that are used in all current mobile applications, servers and modems Contains unique, 100% previously unpublished material on switched-capacitor converters A valuable resource for Practising engineers, researchers and designers, from all industries using power electronics circuits- aerospace, integrated circuits, consumer electronics, and renewable energy, also power supply (converter) designers, procurement managers and engineering managers.
Power Electronics and Energy Conversion Systems, Fundamentals and Hard-switching Converters
Power Electronics and Energy Conversion Systems, Fundamentals and Hard-switching Converters - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Power Electronics and Energy Conversion Systems, Fundamentals and Hard-switching Converters write by Adrian Ioinovici. This book was released on 2013-04-02. Power Electronics and Energy Conversion Systems, Fundamentals and Hard-switching Converters available in PDF, EPUB and Kindle. Power Electronics and Energy Conversion Systems is a definitive five-volume reference spanning classical theory through practical applications and consolidating the latest advancements in energy conversion technology. Comprehensive yet highly accessible, each volume is organised in a basic-to-sophisticated crescendo, providing a single-source reference for undergraduate and graduate students, researchers and designers. Volume 1 Fundamentals and Hard-switching Converters introduces the key challenges in power electronics from basic components to operation principles and presents classical hard- and soft-switching DC to DC converters, rectifiers and inverters. At a more advanced level, it provides comprehensive analysis of DC and AC models comparing the available approaches for their derivation and results. A full treatment of DC to DC hard-switching converters is given, from fundamentals to modern industrial solutions and practical engineering insight. The author elucidates various contradictions and misunderstandings in the literature, for example, in the treatment of the discontinuous conduction operation or in deriving AC small-signal models of converters. Other key features: • Consolidates the latest advancements in hard-switching converters including discontinuous capacitor voltage mode, and their use in power-factor-correction applications • Includes fully worked design examples, exercises, and case studies, with discussion of the practical consequences of each choice made during the design • Explains all topics in detail with step-by-step derivation of formulas appropriate for energy conversion courses • End-of-section review of the learned material • Includes topics treated in recent journal, conference and industry application coverage on solutions, theory and practical concerns With emphasis on clear explanation, the text offers both a thorough understanding of DC to DC converters for undergraduate and graduate students in power electronics, and more detailed material suitable for researchers, designers and practising engineers working on the development and design of power electronics. This is an accessible reference for engineering and procurement managers from industries such as consumer electronics, integrated circuits, aerospace and renewable energy.
Hybrid Switched-capacitor Power Converter Techniques
Hybrid Switched-capacitor Power Converter Techniques - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Hybrid Switched-capacitor Power Converter Techniques write by Nathan Miles Ellis. This book was released on 2020. Hybrid Switched-capacitor Power Converter Techniques available in PDF, EPUB and Kindle. Power conversion is a necessity in almost all modern electric systems and machines: energy must be regulated and delivered in the intended manner if a system is to perform well, or at all. Power converters, the electronic circuits used to control this energy flow, have been a subject of intense study and rapid development in recent years and are widely acknowledged to be a fundamental enabler for modern day human societal capabilities. Many market sectors have strongly advocated for further development of energy conversion systems with improved efficiency and power density as these traits often directly dictate practical viability. While advancements in semiconductor device physics have yielded improved parts for use inconverter solutions, it is becoming apparent that there is additional massive potential and merit in revisiting fundamental converter topologies and circuit techniques. To date, power converters that use capacitors as their primary energy transfer elements (termed "switchedcapacitor" power converters) are far less ubiquitous than their switched-inductor counterparts, and seemingly for good reason: characteristics such as poor output regulation and intrinsic transient inrush currents that lead to inefficiency have largely prevented switched-capacitor topologies from gaining practical consideration in general power converter markets. Solutions to these negative attributes are strongly desired as capacitors can offer energy densities up to three orders of magnitude greater than inductors, with these energy transfer elements typically consuming the majority of a power converter's weight/volume. Recent work has demonstrated significant potential for hybrid switched-capacitor-inductor converter techniques: here, small inductive element(s) are used to eliminate the conventional drawbacks of a converter which is predominantly capacitor based. The hybridized approach helps unlock the full potential of capacitor-based converters and has been demonstrated to offer compelling results at the cost of added complexity. This work offers an exploration into a collection of state-of-the-art power converter techniques and topological methods, primarily within the field of hybridized switched-capacitor-inductor converters. The first two chapters give a background on fundamental considerations such as conventional loss mechanisms and the slow-switching-limit (SSL), as well as several established loss mitigation techniques. An integrated converter system and its associated functional blocks is then discussed in Chapters 3 and 4, exemplifying a hybridized two-stage converter and illustrating the implementation of several loss mitigation methods and practical circuit techniques. Next, several hybridized variations of the Dickson topology are discussed: this family of DC-DC converters is well suited for non-isolated large voltage conversion ratios. A number of these variants are proposed here for the first time, illustrating significant potential for further converter development. The steady-state bias points, resonant switching frequency, duty cycle and voltage ripple as a function of load are calculated for several example converters, including the non-trivial case of a converter undergoing split-phase operation and whose operating points exhibit a strong load dependence. To facilitate comparative analysis between topologies, a mathematical method is presented that characterizes the total energy density utilization of fly capacitors throughout a converter, accounting for large voltage ripple and iii highly nonlinear reverse-bias transitions. This analysis assists with optimal topology selection as energy density utilization directly dictates the required capacitor volume at a specified power level and switching frequency. An expanded family of fly capacitor networks is then introduced in Chapter 6; here it is shown that there are a large number of unexplored yet practical fly capacitor configurations that are eligible for use in hybridized converters. It is calculated that a 6-7 % reduction in capacitor volume can be achieved relative to conventional Dickson fly capacitor networks, while preserving the desirable characteristic of equal voltage ripple on its branches. N-phase and split-phase switching methods and their respective trade-offs are then discussed in detail, offering control techniques that allow a departure from conventional two-phase operation while retaining high-efficiency zero-voltage and zero-current switching (ZVS/ZCS) conditions. A Cockcroft-Walton prototype demonstrates both methods implemented on the same piece of hardware, significantly improving the efficiency range with respect to load and resulting in a state-of-the-art power density of 483.3 kW/liter (7, 920W/inch3). Next, a method termed "resonant charge redistribution" (RCR) is proposed that greatly reduces output capacitance (C[subscript OSS]) related switching losses in all switches of a complex switched-capacitor network. Despite little effort being put towards optimization, a prototype using RCR measures a 61 % reduction in total losses at light load for a near negligible 0.74 % increase in total solution volume. Lastly, resonant gate drive techniques are discussed. Here, within a proposed resonant gate-driver topology, a capacitive decoupling technique is demonstrated that allows power to be delivered to a "flying" high-side N-channel device which commutes between two variable voltages. The implemented prototype achieves up to a 72 % reduction in gating loss when switching over 20 MHz and with rise/fall times ≤ 7 ns. Combining several of the novel techniques described herein can result in near complete mitigation of all primary switching loss mechanisms observed throughout the complex structure of a switched-capacitor converter network. This relatively new field of hybridized converter design has already yielded converters with record-breaking performance, as is demonstrated here. With contemporary techniques, including those described in this work, the field of power electronics is on the cusp of seeing widespread dramatic improvements in energy handling capability, power density, specific power and efficiency at reduced cost, with huge potential for growth and improved energy consumption in both developed and emerging markets.
Power Electronics and Energy Conversion Systems, Fundamentals and Hard-switching Converters
Power Electronics and Energy Conversion Systems, Fundamentals and Hard-switching Converters - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Power Electronics and Energy Conversion Systems, Fundamentals and Hard-switching Converters write by Adrian Ioinovici. This book was released on 2013-06-10. Power Electronics and Energy Conversion Systems, Fundamentals and Hard-switching Converters available in PDF, EPUB and Kindle. Power Electronics and Energy Conversion Systems is a definitive five-volume reference spanning classical theory through practical applications and consolidating the latest advancements in energy conversion technology. Comprehensive yet highly accessible, each volume is organised in a basic-to-sophisticated crescendo, providing a single-source reference for undergraduate and graduate students, researchers and designers. Volume 1 Fundamentals and Hard-switching Converters introduces the key challenges in power electronics from basic components to operation principles and presents classical hard- and soft-switching DC to DC converters, rectifiers and inverters. At a more advanced level, it provides comprehensive analysis of DC and AC models comparing the available approaches for their derivation and results. A full treatment of DC to DC hard-switching converters is given, from fundamentals to modern industrial solutions and practical engineering insight. The author elucidates various contradictions and misunderstandings in the literature, for example, in the treatment of the discontinuous conduction operation or in deriving AC small-signal models of converters. Other key features: • Consolidates the latest advancements in hard-switching converters including discontinuous capacitor voltage mode, and their use in power-factor-correction applications • Includes fully worked design examples, exercises, and case studies, with discussion of the practical consequences of each choice made during the design • Explains all topics in detail with step-by-step derivation of formulas appropriate for energy conversion courses • End-of-section review of the learned material • Includes topics treated in recent journal, conference and industry application coverage on solutions, theory and practical concerns With emphasis on clear explanation, the text offers both a thorough understanding of DC to DC converters for undergraduate and graduate students in power electronics, and more detailed material suitable for researchers, designers and practising engineers working on the development and design of power electronics. This is an accessible reference for engineering and procurement managers from industries such as consumer electronics, integrated circuits, aerospace and renewable energy.
Power Systems-On-Chip
Power Systems-On-Chip - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Power Systems-On-Chip write by Bruno Allard. This book was released on 2016-11-22. Power Systems-On-Chip available in PDF, EPUB and Kindle. The book gathers the major issues involved in the practical design of Power Management solutions in wireless products as Internet-of-things. Presentation is not about state-of-the-art but about appropriation of validated recent technologies by practicing engineers. The book delivers insights on major trade-offs and a presentation of examples as a cookbook. The content is segmented in chapters to make access easier for the lay-person.
