Lecture Notes of Power Electronics Course PDF Download
Are you looking for read ebook online? Search for your book and save it on your Kindle device, PC, phones or tablets. Download Lecture Notes of Power Electronics Course PDF full book. Access full book title Lecture Notes of Power Electronics Course by Dr. Hidaia Mahmood Alassouli. Download full books in PDF and EPUB format.
Author: Dr. Hidaia Mahmood Alassouli Publisher: Dr. Hidaia Mahmood Alassouli ISBN: Category : Technology & Engineering Languages : en Pages : 141
Book Description
This book includes my lecture notes for power electronics course course. The characteristics and operation of electronic power devices, firing circuits, and driving circuits for power converters are described and implemented practically in the laboratory. Uncontrolled and controlled, single phase rectifiers are used in various electrical power applications. DC to DC power conversion circuits are investigated. Circuit simulation and practical laboratories are utilized to reinforce concepts. The book is divided to different learning parts · Part1- Describe the characteristics and operation of electronic power devices. · Part2- Describe firing and driving circuits for power electronic converters. · Part3- Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications. · Part4- Investigate the DC-to-DC power conversion circuits used in power applications. Part1: Describe the characteristics and operation of electronic power devices. 1. Describe diode characteristics, types (power diode, general-purpose, and fast recovery), and connections (series, parallel and freewheeling). 2. Describe thyristor characteristics, two-transistor model, and purpose of di/dt and dv/dt protection. 3. Describe the power MOSFET and IGBT characteristics. 4. Compare electronic power devices in terms of various power converter applications, frequency of operation (switching speed), rating, and switching power losses. Part 2: Describe firing and driving circuits for power electronic converters. 1. Describe ideal and non-ideal properties of operational amplifiers. Determine the operation of various related circuits (inverting and non-inverting amplifiers, buffer amplifier, summing amplifier) 2. Describe the use of an operational amplifier for PWM generation, for triangular and sine wave generation, as a comparator, and its integration into a 555 timer. 3. Explore other basic firing and driving circuits by focusing on requirements and control features such as based on specific power devices and operational amplifier. Part 3: Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications. 1. Determine the performance characteristics of uncontrolled single-phase, half-wave and full-wave rectifiers, with resistive and inductive loads. 2. Determine the performance characteristics of controlled single-phase, half-wave and full-wave rectifiers with resistive and inductive loads. 3. Determine the change in power factor when using uncontrolled and controlled rectifiers. Define input distortion and displacement factor. 4. Describe how power inversion may be achieved by varying the firing angle in controlled rectifiers. Part 4: Investigate the DC-to-DC power conversion circuits used in power applications. 1. State the principle of step-down and step-up operations. 2. Explain the DC chopper classification and describe switch-mode regulators 3. Explain the operation of buck, boost 4. Explain the operation buck-boost regulators.
Author: Dr. Hidaia Mahmood Alassouli Publisher: Dr. Hidaia Mahmood Alassouli ISBN: Category : Technology & Engineering Languages : en Pages : 141
Book Description
This book includes my lecture notes for power electronics course course. The characteristics and operation of electronic power devices, firing circuits, and driving circuits for power converters are described and implemented practically in the laboratory. Uncontrolled and controlled, single phase rectifiers are used in various electrical power applications. DC to DC power conversion circuits are investigated. Circuit simulation and practical laboratories are utilized to reinforce concepts. The book is divided to different learning parts · Part1- Describe the characteristics and operation of electronic power devices. · Part2- Describe firing and driving circuits for power electronic converters. · Part3- Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications. · Part4- Investigate the DC-to-DC power conversion circuits used in power applications. Part1: Describe the characteristics and operation of electronic power devices. 1. Describe diode characteristics, types (power diode, general-purpose, and fast recovery), and connections (series, parallel and freewheeling). 2. Describe thyristor characteristics, two-transistor model, and purpose of di/dt and dv/dt protection. 3. Describe the power MOSFET and IGBT characteristics. 4. Compare electronic power devices in terms of various power converter applications, frequency of operation (switching speed), rating, and switching power losses. Part 2: Describe firing and driving circuits for power electronic converters. 1. Describe ideal and non-ideal properties of operational amplifiers. Determine the operation of various related circuits (inverting and non-inverting amplifiers, buffer amplifier, summing amplifier) 2. Describe the use of an operational amplifier for PWM generation, for triangular and sine wave generation, as a comparator, and its integration into a 555 timer. 3. Explore other basic firing and driving circuits by focusing on requirements and control features such as based on specific power devices and operational amplifier. Part 3: Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications. 1. Determine the performance characteristics of uncontrolled single-phase, half-wave and full-wave rectifiers, with resistive and inductive loads. 2. Determine the performance characteristics of controlled single-phase, half-wave and full-wave rectifiers with resistive and inductive loads. 3. Determine the change in power factor when using uncontrolled and controlled rectifiers. Define input distortion and displacement factor. 4. Describe how power inversion may be achieved by varying the firing angle in controlled rectifiers. Part 4: Investigate the DC-to-DC power conversion circuits used in power applications. 1. State the principle of step-down and step-up operations. 2. Explain the DC chopper classification and describe switch-mode regulators 3. Explain the operation of buck, boost 4. Explain the operation buck-boost regulators.
Author: Hidaia Alassouli Publisher: Createspace Independent Publishing Platform ISBN: 9781986494427 Category : Languages : en Pages : 142
Book Description
This book includes my lecture notes for power electronics course course. The characteristics and operation of electronic power devices, firing circuits, and driving circuits for power converters are described and implemented practically in the laboratory. Uncontrolled and controlled, single phase rectifiers are used in various electrical power applications. DC to DC power conversion circuits are investigated. Circuit simulation and practical laboratories are utilized to reinforce concepts. The book is divided to different learning parts -Part1- Describe the characteristics and operation of electronic power devices. -Part2- Describe firing and driving circuits for power electronic converters. -Part3- Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications. -Part4- Investigate the DC-to-DC power conversion circuits used in power applications. Part1: Describe the characteristics and operation of electronic power devices. 1.Describe diode characteristics, types (power diode, general-purpose, and fast recovery), and connections (series, parallel and freewheeling). 2.Describe thyristor characteristics, two-transistor model, and purpose of di/dt and dv/dt protection. 3.Describe the power MOSFET and IGBT characteristics. 4.Compare electronic power devices in terms of various power converter applications, frequency of operation (switching speed), rating, and switching power losses. Part 2: Describe firing and driving circuits for power electronic converters. 1.Describe ideal and non-ideal properties of operational amplifiers. Determine the operation of various related circuits (inverting and non-inverting amplifiers, buffer amplifier, summing amplifier) 2.Describe the use of an operational amplifier for PWM generation, for triangular and sine wave generation, as a comparator, and its integration into a 555 timer. 3.Explore other basic firing and driving circuits by focusing on requirements and control features such as based on specific power devices and operational amplifier. Part 3: Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications. 1.Determine the performance characteristics of uncontrolled single-phase, half-wave and full-wave rectifiers, with resistive and inductive loads. 2.Determine the performance characteristics of controlled single-phase, half-wave and full-wave rectifiers with resistive and inductive loads. 3.Determine the change in power factor when using uncontrolled and controlled rectifiers. Define input distortion and displacement factor. 4.Describe how power inversion may be achieved by varying the firing angle in controlled rectifiers. Part 4: Investigate the DC-to-DC power conversion circuits used in power applications. 1.State the principle of step-down and step-up operations. 2.Explain the DC chopper classification and describe switch-mode regulators 3.Explain the operation of buck, boost 4.Explain the operation buck-boost regulators.
Author: Hidaia Alassouli Publisher: ISBN: 9781986354332 Category : Languages : en Pages : 142
Book Description
This book includes my lecture notes for power electronics course course. The characteristics and operation of electronic power devices, firing circuits, and driving circuits for power converters are described and implemented practically in the laboratory. Uncontrolled and controlled, single phase rectifiers are used in various electrical power applications. DC to DC power conversion circuits are investigated. Circuit simulation and practical laboratories are utilized to reinforce concepts.The book is divided to different learning parts* Part1- Describe the characteristics and operation of electronic power devices.* Part2- Describe firing and driving circuits for power electronic converters.* Part3- Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications.* Part4- Investigate the DC-to-DC power conversion circuits used in power applications.Part1: Describe the characteristics and operation of electronic power devices.1. Describe diode characteristics, types (power diode, general-purpose, and fast recovery), and connections (series, parallel and freewheeling).2. Describe thyristor characteristics, two-transistor model, and purpose of di/dt and dv/dt protection.3. Describe the power MOSFET and IGBT characteristics.4. Compare electronic power devices in terms of various power converter applications, frequency of operation (switching speed), rating, and switching power losses.Part 2: Describe firing and driving circuits for power electronic converters.1. Describe ideal and non-ideal properties of operational amplifiers. Determine the operation of various related circuits (inverting and non-inverting amplifiers, buffer amplifier, summing amplifier)2. Describe the use of an operational amplifier for PWM generation, for triangular and sine wave generation, as a comparator, and its integration into a 555 timer.3. Explore other basic firing and driving circuits by focusing on requirements and control features such as based on specific power devices and operational amplifier.Part 3: Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications.1. Determine the performance characteristics of uncontrolled single-phase, half-wave and full-wave rectifiers, with resistive and inductive loads.2. Determine the performance characteristics of controlled single-phase, half-wave and full-wave rectifiers with resistive and inductive loads.3. Determine the change in power factor when using uncontrolled and controlled rectifiers. Define input distortion and displacement factor.4. Describe how power inversion may be achieved by varying the firing angle in controlled rectifiers.Part 4: Investigate the DC-to-DC power conversion circuits used in power applications.1. State the principle of step-down and step-up operations.2. Explain the DC chopper classification and describe switch-mode regulators3. Explain the operation of buck, boost4. Explain the operation buck-boost regulators.
Author: Dr. Hidaia Mahmood Alassouli Publisher: Dr. Hidaia Mahmood Alassouli ISBN: Category : Technology & Engineering Languages : en Pages : 141
Book Description
This book includes my lecture notes for power electronics course course. The characteristics and operation of electronic power devices, firing circuits, and driving circuits for power converters are described and implemented practically in the laboratory. Uncontrolled and controlled, single phase rectifiers are used in various electrical power applications. DC to DC power conversion circuits are investigated. Circuit simulation and practical laboratories are utilized to reinforce concepts. The book is divided to different learning parts · Part1- Describe the characteristics and operation of electronic power devices. · Part2- Describe firing and driving circuits for power electronic converters. · Part3- Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications. · Part4- Investigate the DC-to-DC power conversion circuits used in power applications. Part1: Describe the characteristics and operation of electronic power devices. 1. Describe diode characteristics, types (power diode, general-purpose, and fast recovery), and connections (series, parallel and freewheeling). 2. Describe thyristor characteristics, two-transistor model, and purpose of di/dt and dv/dt protection. 3. Describe the power MOSFET and IGBT characteristics. 4. Compare electronic power devices in terms of various power converter applications, frequency of operation (switching speed), rating, and switching power losses. Part 2: Describe firing and driving circuits for power electronic converters. 1. Describe ideal and non-ideal properties of operational amplifiers. Determine the operation of various related circuits (inverting and non-inverting amplifiers, buffer amplifier, summing amplifier) 2. Describe the use of an operational amplifier for PWM generation, for triangular and sine wave generation, as a comparator, and its integration into a 555 timer. 3. Explore other basic firing and driving circuits by focusing on requirements and control features such as based on specific power devices and operational amplifier. Part 3: Analyse the use of uncontrolled and controlled single-phase rectifiers in various electrical power applications. 1. Determine the performance characteristics of uncontrolled single-phase, half-wave and full-wave rectifiers, with resistive and inductive loads. 2. Determine the performance characteristics of controlled single-phase, half-wave and full-wave rectifiers with resistive and inductive loads. 3. Determine the change in power factor when using uncontrolled and controlled rectifiers. Define input distortion and displacement factor. 4. Describe how power inversion may be achieved by varying the firing angle in controlled rectifiers. Part 4: Investigate the DC-to-DC power conversion circuits used in power applications. 1. State the principle of step-down and step-up operations. 2. Explain the DC chopper classification and describe switch-mode regulators 3. Explain the operation of buck, boost 4. Explain the operation buck-boost regulators.
Author: Amit Bhattacharyya Publisher: diplom.de ISBN: 3954894734 Category : Science Languages : en Pages : 103
Book Description
Power Electronics is a field which combines Power (electric power), Electronics and Control systems. Power engineering deals with the static and rotating power equipment for the generation, transmission and distribution of electric power. Electronics deals with the study of solid state semiconductor power devices and circuits for Power conversion to meet the desired control objectives (to control the output voltage and output power). Power electronics may be defined as the subject of applications of solid state power semiconductor devices (Thyristors) for the control and conversion of electric power. Power electronics deals with the study and design of Thyristorised power controllers for a variety of applications like Heat control, Light/Illumination control, Motor control, AC/DC motor drives used in industries, High voltage power supplies, Vehicle propulsion systems, and High voltage direct current (HVDC) transmission.
Author: Stefanos Manias Publisher: Independently Published ISBN: 9781720255246 Category : Study Aids Languages : en Pages : 162
Book Description
The use of fast review notes for a power electronics course by a student can provide the following opportunities: 1) Makes understand clearly the specific course material, 2) The waveforms and equations of a specific power converter are presented in a table form within 3 to 6 pages, 3) Since all the material of a power electronics course is written in a concentrated table form allows the student to grasp quite easy the material of the specific course, 4) The fast review notes are easy accessible material in hard copy or ebook form, helping the students to study them anytime and anywhere they want and 5) Provides the student to select out of 150 pages the necessary material that needs to review very fast before going to examination.
Author: Vančo B. Litovski Publisher: Springer Nature ISBN: 9811965285 Category : Technology & Engineering Languages : en Pages : 374
Book Description
This book discusses larger signal amplifiers (denoted as PA). Large signal amplifiers are dealing with signals whose magnitude is such that the operation of the active element can no longer be considered linear. They are usually designed to get as much power gain and efficiency as possible. That is why they are often called power amplifiers. In this book, two implementations of PA are considered. First, it is of interest to obtain large signals (current or voltage) at the output of a cascade of direct coupled amplifiers. In this case, linearity, frequency response, and speed are the most important requirements. Second are real power amplifiers where the power delivered to the load is of primary interest. Of course, efficiency, linearity, and high frequency response are of interest, too. A very special attention is paid to modern power electronic components such as Power BJT, VDMOS, IGBT, SiC MOS, and GaN HEMT. DC and switching properties of all these devices are studied in much detail. This book also includes a set of appendices which cover: solved problems, SPICE simulation results for selected set of circuits, and a short review of microelectronic technology process
Author: Vatché Vorpérian Publisher: Cambridge University Press ISBN: 9781139433235 Category : Technology & Engineering Languages : en Pages : 502
Book Description
The only method of circuit analysis known to most engineers and students is nodal or loop analysis. Although this works well for obtaining numerical solutions, it is almost useless for obtaining analytical solutions in all but the simplest cases. In this unusual 2002 book, Vorpérian describes remarkable alternative techniques to solve, almost by inspection, complicated linear circuits in symbolic form and obtain meaningful analytical answers for any transfer function or impedance. Although not intended to replace traditional computer-based methods, these techniques provide engineers with a powerful set of tools for tackling circuit design problems. They also have great value in enhancing students' understanding of circuit operation, making this an ideal course book, and numerous problems and worked examples are included. Originally developed by Professor David Middlebrook and others at Caltech (California Institute of Technology), the techniques described here are now widely taught at institutions and companies around the world.
Author: Dr. Hidaia Mahmood Alassouli
Author: Dr. Hidaia Mahmood Alassouli
Author: Hidaia Alassouli (Mahmood)
Author: Hidaia Alassouli
Author: Hidaia Alassouli
Author: Dr. Hidaia Mahmood Alassouli
Author: Amit Bhattacharyya
Author: Rik W. De Doncker
Author: Stefanos Manias
Author: Vančo B. Litovski
Author: Vatché Vorpérian