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| POWER SOURCES AND SUPPLIES: WORLD CLASS DESIGNS
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To order this title, and for more information, click here
By
Marty Brown, Engineer, Microchip Technologies, Chandler, AZ, USA
Included in series
World Class Designs,
Description
Newnes has worked with Marty Brown, a leader in the field of power design to select the very best design-specific material from the Newnes
portfolio. Marty selected material for its timelessness, its relevance to current power supply design needs, and its real-world approach
to design issues. Special attention is given to switching power supplies and their design issues, including component selection, minimization
of EMI, toroid selection, and breadboarding of designs. Emphasis is also placed on design strategies for power supplies, including case
histories and design examples. This is a book that belongs on the workbench of every power supply designer!
Audience
Power supply designers and engineers
Contents
Chapter 1. An Introduction to the Linear Regulator
1.1 Basic Linear Regulator Operation
1.2 General Linear Regulator Considerations
1.3 Linear Power Supply Design Examples
Chapter 2. Basic Switching Circuits
2.1 Energy Storage Basics
2.2 Buck Converter
2.3
Boost Converter
2.4 Inverting Boost Converter
2.5 Buck-Boost Converter
2.6 Transformer Isolated Converters
2.7 Synchronous Rectification
2.8 Charge Pumps
Chapter 3 DC-DC Converter Design and Magnetics
3.1 DC Transfer Functions
3.2 The DC Level and the ?Swing? of
the Inductor Current Waveform
3.3 Defining the AC, DC, and Peak Currents
3.4 Understanding the AC, DC and Peak Currents
3.5
Defining the ?Worst-case? Input Voltage
3.6 The Current Ripple Ratio ?r'
3.7 Relating r to the Inductance
3.8 The Optimum
Value of r
3.9 Do We Mean Inductor? Or Inductance?
3.10 How Inductance and Inductor Size Depend on Frequency
3.11 How Inductance
and Inductor Size Depend on Load Current
3.12 How Vendors Specify the Current Rating of an Off-the-shelf Inductor and How to Select
It
3.13 What Is the Inductor Current Rating We Need to Consider for a Given Application?
3.14 The Spread and Tolerance of the Current
Limit
3.15 Worked Example (1)
3.16 Worked Examples (2, 3, and 4)
3.17 Worked Example (5) – When Not to Increase the Number of Turns
3.18 Worked Example (6) – Characterizing an Off-the-shelf Inductor in a Specific Application
3.19 Calculating the ?Other? Worst-case
Stresses
Chapter 4 Control Circuits
4.1 Basic Control Circuits
4.2 The Error Amplifier
4.3 Error Amplifier Compensation
4.4
A Representative Voltage Mode PWM Controller
4.5 Current Mode Control
4.6 A Representative Current Mode PWM Controller
4.7 Charge
Pump Circuits
4.8 Multiple Phase PWM Controllers
4.9 Resonant Mode Controllers
Chapter 5 Non-Isolated Circuits
5.1 General Design
Method
5.2 Buck Converter Designs
5.3 Boost Converter Designs
5.4 Inverting Designs
5.5 Step Up/Step Down (Buck/Boost) Designs
5.6 Charge Pump Designs
5.7 Layout Considerations
Chapter 6 Transformer Isolated Circuits
6.1 Feedback Mechanisms
6.2 Flyback
Circuits
6.3 Practical Flyback Circuit Design
6.4 Off-Line Flyback Example
6.5 Non-Isolated Flyback Example
6.6 Forward Converter
Circuits
6.7 Practical Forward Converter Design
6.8 Off-Line Forward Converter Example
6.9 Non-Isolated Forward Converter Example
6.10 Push-Pull Circuits
6.11 Practical Push-Pull Circuit Design
6.12 Half Bridge Circuits
6.13 Practical Half Bridge Circuit
Design
6.14 Full Bridge Circuits
Chapter 7 Power Semiconductors
7.1 Introduction
7.2 Power Diodes and Thyristors
7.3 Gate Turn-Off
Thyristors
7.4 Bipolar Power Transistors
7.5 Power MOSFETs
7.6 Insulated Gate Bipolar Transistor (IGBT)
7.7 MOS Controlled Thyristor
(MCT)
7.8 References
7.9 Bibliography
Chapter 8 Conduction and Switching Losses
8.1 Switching a Resistive Load
8.2 Switching
an Inductive Load
8.3 Switching Losses and Conduction Loss
8.4 A Simplified Model of the Mosfet for Studying Inductive Switching
Losses
8.5 The Parasitic Capacitances Expressed in an Alternate System
8.6 Gate Threshold Voltage
8.7 The Turn-on Transition
8.8 The Turn-off Transition
8.9 Gate Charge Factors
8.10 Worked Example
8.11 Applying the Switching Loss Analysis to Switching Topologies
8.12 Worst-case Input Voltage for Switching Losses
8.13 How Switching Losses Vary with the Parasitic Capacitances
8.14 Optimizing
Driver Capability vis- -vis Mosfet Characteristics
Chapter 9 Power Factor Correction
9.1 A Universal Input, 180W, Active Power Factor
Correction Circuit
Chapter 10 Off-line Converter Design and Magnetics
10.1 Flyback Converter Magnetics
10.2 Forward Converter Magnetics
Chapter 11 A ?True Sine Wave? Inverter Design Example
11.1 Design Requirements
11.2 Design Description
11.3 Preregulator Detailed
Design
11.4 Output Converter Detailed Design
11.5 H Bridge Detailed Design
11.6 Bridge Drive Detailed Design
Chapter 12 Thermal
Analysis and Design
12.1 Developing the Thermal Model
12.2 Power Packages on a Heatsink (TO-3, TO-220, TO-218, etc.)
12.3 Power
Packages Not on a Heatsink (Free Standing)
12.4 Radial-leaded Diodes
12.5 Surface Mount Parts
12.6 Examples of Some Thermal Applications
| Bibliographic details |
Paperback, 400 pages, publication date: DEC-2007
ISBN-13: 978-0-7506-8626-6
Imprint: NEWNES
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| Price and Ordering |
Price:
EUR 28.95
GBP 23.99
USD 39.95
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Last update: 25 Nov 2009
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