A practical guide to analog and mixed-signal electronics, with an emphasis on design problems and applications
This book provides an in-depth coverage of essential analog and mixed-signal topics such as power amplifiers, active filters, noise and dynamic range, analog-to-digital and digital-to-analog conversion techniques, phase-locked loops, and switching power supplies. Readers will learn the basics of linear systems, types of nonlinearities and their effects, op-amp circuits, the high-gain analog filter-amplifier, and signal generation. The author uses system design examples to motivate theoretical explanations and covers system-level topics not found in most textbooks.
Provides references for further study and problems at the end of each chapter
Includes an appendix describing test equipment useful for analog and mixed-signal work
Examines the basics of linear systems, types of nonlinearities and their effects, op-amp circuits, the high-gain analog filter-amplifier, and signal generation
Comprehensive and detailed, Analog and Mixed-Signal Electronics is a great introduction to analog and mixed-signal electronics for EE undergraduates, advanced electronics students, and for those involved in computer engineering, biomedical engineering, computer science, and physics.
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1 INTRODUCTION TO ANALOG AND MIXED-SIGNAL ELECTRONICS
1.1 INTRODUCTION
âIn the beginning, there were only analog electronics and vacuum tubes and huge, heavy, hot equipment that did hardly anything. Then came the digitalâenabled by integrated circuits and the rapid progress in computers and softwareâand electronics became smaller, lighter, cheaper, faster, and just better all around, all because it was digital.â Thatâs the gist of a sort of urban legend that has grown up about the nature of analog electronics and mixed-signal electronics, which means simply electronics that has both analog and digital circuitry in it.
Like most legends, this one has some truth to it. Most electronic systems, ever since the time that there was anything around to apply the word âelectronicsâ to, were analog in nature for most of the twentieth century. In electronics, an analog signal is a voltage or current whose value is proportional to (an analog of) some physical quantity such as sound pressure, light intensity, or even an abstract numerical value in an analog computer. Digital signals, by contrast, ideally take on only one of two values or ranges of values and by doing so represent the discrete binary ones and zeros that form the language of digital computers. To give you an idea of how things used to be done with purely analog systems, Figure 1.1 shows on the left a two-channel vacuum-tube audio amplifier that can produce about 70 W per channel.
The vacuum-tube amplifier measures 30 cm Ă 43 cm Ă 20 cm and weighs 17.2 kg (38 lb) and was state-of-the-art technology in about 1955. On its right is a solid-state class D amplifier designed in 2008 that can produce about the same amount of output power. It is a mixed-signal (analog and digital) design. It measures only 15 cm Ă 10 cm Ă 4 cm and weighs only 0.33 kg, not including the power supply, which is of comparable size and weight. The newer amplifier uses its power devices as switches and is much more efficient than the vacuum-tube unit, which is about 50 times its size and weight. So the claim that many analog designs have been made completely obsolete by newer digital and mixed-signal designs is true, as far as it goes.
Sometimes, you will hear defenders of analog technology argue that âthe world is essentially analog, and so analog electronics will never go away completely.â Again, thereâs some truth to that, but it depends on your point of view. The physics of quantum mechanics tells us that not only are all material objects made of discrete things called atoms but many forms of energy appear as discrete packets called quanta (photons, in the case of electromagnetic radiation). So you can make just as good an argument for the case that the whole world is essentially digital, not analog, because it can be represented as bits of quanta and atoms that are either there or not there at all.
The fact of the matter is that while the bulk of todayâs electronics technology is implemented by means of digital circuits and powerful software, a smaller but essential part of what goes into most electronic devices involves analog circuitry. Even if the analog part is as simple as a battery for the power supply, no one has yet developed a battery that behaves digitally: that is, one that provides an absolutely constant voltage until it depletes and drops abruptly to zero. So even designers of an otherwise totally digital system have to deal with the analog problem of power-supply characteristics.
This book is intended for anyone who has an interest in understanding or designing systems involving analog or mixed-signal electronics. That includes undergraduates with a basic sophomore-level understanding of electronics, as well as more advanced undergraduates, graduate students, and professionals in engineering, science, or other fields whose work requires them to learn about or deal with these types of electronic systems. The emphasis is practical rather than theoretical, although enough theory to enable an understanding of the essentials will be presented as needed throughout. Many textbooks present electronics concepts in isolation without any indication of how a component or circuit can be used to meet a practical need, and we will try to avoid that error in this book. Practical applications of the various circuits and systems described will appear as examples, as paper or computer-simulation design exercises, and as lab projects.
1.2 ORGANIZATION OF THE BOOK
The book is divided into three main sections: devices and linear systems (Chapters 2 and 3), linear and nonlinear analog circuits and applications (Chapters 4â7), and special topics of analog and mixed-signal design (Chapters 8â12). A chapter-by-chapter summary follows.
1.2.1 Chapter 2: Basics of Electronic Components and Devices
In this chapter, you will learn enough about the various types of two- and three-terminal electronic devices to use them in simple designs. This includes rectifier, signal, and light-emitting diodes and the various types of three-terminal devices: field-effect transistors (FETs), bipolar junction transistors (BJTs), and power devices. Despite the bewildering number of different devices available from manufacturers, there are usually only a few specifications that you need to know about each type in order to use them safely and efficiently. In this chapter, we present basic circuit models for each type of device and how to incorporate the essential specifications into the model.
1.2.2 Chapter 3: Linear System Analysis
This chapter presents the basics of linear systems: how to characterize a âblack boxâ circuit as an element in a more complex system, how to deal with characteristics such as gain and frequency response, and how to define a systemâs overall specifications in terms that can be translated into circuit designs. The power of linear analysis is that it can deal with complex systems using fairly simple mathematics. You also learn about some basic principles of noise sources and their effects on electronic systems.
1.2.3 Chapter 4: Nonlinearities in Analog Electronics
While linear analysis covers a great deal of analog-circuit territory, nonlinear effects can both cause problems in designs and provide solutions to other design problems. Noise of various kinds is always present to some degree in any circuit, and in the case of high-gain and high-sensitivity systems dealing with low-level signals, noise can determine the performance limits of the entire system. You will be introduced to the basics of nonlinearities and noise in this chapter and learn ways of dealing with these issues and minimizing problems that may arise from them.
1.2.4 Chapter 5: Op Amp Circuits in Analog Electronics
The workhorse of analog electronics is the operational amplifier (âop ampâ for short). Originally developed for use in World War II era analog computers, in integrated-circuit form the op amp now plays essential roles in most analog electronics systems of any complexity. This chapter describes op amps in a simplified ideal form and outlines the more complex characteristics shown by actual op amps. Basic op amp circuits and ...
Table of contents
COVER
TITLE PAGE
TABLE OF CONTENTS
PREFACE
ACKNOWLEDGMENTS
ABOUT THE COMPANION WEBSITE
1 INTRODUCTION TO ANALOG AND MIXED-SIGNAL ELECTRONICS
2 BASICS OF ELECTRONIC COMPONENTS AND DEVICES
3 LINEAR SYSTEMS ANALYSIS
4 NONLINEARITIES IN ANALOG ELECTRONICS
5 OP AMP CIRCUITS IN ANALOG ELECTRONICS
6 THE HIGH-GAIN ANALOG FILTER AMPLIFIER
7 WAVEFORM GENERATION
8 ANALOG-TO-DIGITAL AND DIGITAL-TO-ANALOG CONVERSION
9 PHASE-LOCKED LOOPS
10 POWER ELECTRONICS
11 HIGH-FREQUENCY (RF) ELECTRONICS
12 ELECTROMAGNETIC COMPATIBILITY
APPENDIX: TEST EQUIPMENT FOR ANALOG AND MIXED-SIGNAL ELECTRONICS