PrinciplesOfPowerElectronicsKassakianpdf
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Principles of Power Electronics by John G. Kassakian
This is a book review of Principles of Power Electronics by John G. Kassakian, Martin F. Schlecht and George C. Verghese, published by Addison-Wesley in 1991. The book is a comprehensive and rigorous introduction to the field of power electronics, covering topics such as converters, inverters, rectifiers, filters, control methods, modulation techniques and applications.
The book is divided into three parts: Part I covers the basic principles and components of power electronics, such as switches, diodes, thyristors, transistors and transformers. Part II focuses on the analysis and design of power electronic circuits, such as dc-dc converters, ac-dc rectifiers, dc-ac inverters and ac-ac cycloconverters. Part III discusses the applications of power electronics in various domains, such as motor drives, power supplies, renewable energy systems and power quality improvement.
The book is well-written and organized, with clear explanations, examples, exercises and references. The book assumes a background in electrical engineering and circuit theory, but also provides some review material on relevant topics. The book is suitable for undergraduate and graduate students who want to learn the fundamentals and advanced concepts of power electronics, as well as for practicing engineers who want to update their knowledge and skills in this field.Power electronics has a wide range of applications in various domains, such as renewable energy generation, electric vehicles, biomedical devices, lighting, industrial drives, power supplies and power quality improvement. Some examples of power electronics applications are:
Renewable energy generation: Power electronics is used to convert the variable and intermittent output of renewable energy sources such as solar panels, wind turbines and fuel cells into stable and usable electric power. Power electronics can also perform maximum power point tracking (MPPT), grid synchronization, voltage regulation and power factor correction for renewable energy systems. [^1^] [^2^]
Electric vehicles: Power electronics is used to control the speed and torque of electric motors in electric vehicles, such as cars, buses, trains and bikes. Power electronics can also perform bidirectional power conversion between the battery and the motor, as well as between the battery and the grid. Power electronics can also improve the efficiency, performance and reliability of electric vehicles. [^1^] [^3^]
Biomedical devices: Power electronics is used to provide safe and precise power delivery to biomedical devices, such as pacemakers, defibrillators, artificial organs and implants. Power electronics can also perform wireless power transfer, battery management and bio-signal processing for biomedical devices. [^1^] [^4^]
Lighting: Power electronics is used to control the brightness and color of lighting devices, such as LEDs, CFLs and OLEDs. Power electronics can also perform dimming, flicker-free operation, color mixing and color temperature adjustment for lighting devices. Power electronics can also improve the efficiency, lifespan and quality of lighting devices. [^1^] [^5^]
Industrial drives: Power electronics is used to control the speed and torque of electric motors in industrial applications, such as pumps, fans, compressors, conveyors and robots. Power electronics can also perform soft-starting, braking, speed regulation and torque control for industrial drives. Power electronics can also improve the efficiency, performance and reliability of industrial drives. [^1^]
Power supplies: Power electronics is used to convert the input AC or DC voltage into a desired output DC or AC voltage for various electronic devices and systems. Power electronics can also perform voltage regulation, current limiting, short-circuit protection and isolation for power supplies. Power electronics can also improve the efficiency, performance and reliability of power supplies. [^1^]
Power quality improvement: Power electronics is used to improve the quality of electric power delivered to loads or grids by compensating for disturbances such as harmonics, voltage sags, voltage swells, flicker and transients. Power electronics can also perform active filtering, reactive power compensation, voltage stabilization and power factor correction for power quality improvement. Power electronics can also improve the efficiency, performance and reliability of electric power systems. [^1^] ec8f644aee