Digital Integrated Electronics by Taub and Schilling: An Introduction to the Field

Digital Integrated Electronics By Taub And Schilling.pdf: A Comprehensive Review

If you are interested in learning about digital electronics and integrated circuits, you may have come across a book called Digital Integrated Electronics by Herbert Taub and Donald Schilling. This book was published in 1977 by McGraw-Hill and is considered a classic in the field. But what is this book about? Who are the authors? And is it still relevant and useful today? In this article, we will answer these questions and provide a comprehensive review of the book. We will also discuss its main features, advantages, and disadvantages, as well as give some recommendations for readers and learners.

Digital Integrated Electronics By Taub And Schilling.pdf

Introduction

What is digital integrated electronics?

Digital integrated electronics is a branch of electronics that deals with the design, fabrication, and application of digital circuits that are composed of many electronic components on a single chip. Digital circuits are those that operate with discrete values of voltage or current, such as binary digits (0 or 1), rather than continuous values, such as analog signals. Digital circuits are used for various purposes, such as data processing, communication, computation, control, and instrumentation.

Who are Taub and Schilling?

Herbert Taub (1918-2009) was an American electrical engineer and educator who specialized in information theory, communication systems, and digital electronics. He was a professor at Columbia University for over 40 years and authored several textbooks on electrical engineering. He was also a fellow of the Institute of Electrical and Electronics Engineers (IEEE) and received many awards for his contributions to the field.

Donald L. Schilling (1936-2017) was also an American electrical engineer and educator who specialized in digital electronics, integrated circuits, and microelectronics. He was a professor at City College of New York for over 30 years and co-authored several textbooks on electrical engineering with Taub. He was also a fellow of IEEE and received many honors for his research and teaching.

What is the purpose and scope of the book?

The purpose of the book is to provide a comprehensive introduction to the theory and practice of digital integrated electronics. The book covers both the basic concepts and principles of digital electronics as well as the design and analysis of digital integrated circuits using various technologies. The book is intended for undergraduate students of electrical engineering who have some background in circuit analysis, linear systems, electronics, and mathematics. The book can also be used as a reference for graduate students, engineers, technicians, and hobbyists who want to learn more about digital integrated electronics.

Main features of the book

Basic concepts and principles of digital electronics

The first part of the book introduces the fundamental concepts and principles of digital electronics, such as number systems and codes, Boolean algebra and logic gates, combinational logic circuits, and sequential logic circuits. These topics are essential for understanding the operation and design of digital circuits and systems. The book explains these topics in a clear and concise manner, with numerous examples and exercises to illustrate the concepts and test the understanding of the readers. The book also provides tables, charts, and diagrams to summarize the important information and facilitate the learning process.

Number systems and codes

The book starts with a review of the decimal number system, which is the most common and familiar number system used in everyday life. The book then introduces other number systems that are used in digital electronics, such as binary, octal, hexadecimal, and BCD (binary-coded decimal). The book explains how to convert between different number systems and how to perform arithmetic operations with them. The book also discusses various codes that are used to represent information in digital form, such as ASCII (American Standard Code for Information Interchange), EBCDIC (Extended Binary Coded Decimal Interchange Code), Gray code, and Hamming code. The book explains the advantages and disadvantages of different codes and how to encode and decode them.

Boolean algebra and logic gates

The book then introduces Boolean algebra, which is a branch of mathematics that deals with logical operations and expressions. The book explains the basic laws and rules of Boolean algebra, such as commutative, associative, distributive, identity, complement, De Morgan's, and duality laws. The book also shows how to simplify Boolean expressions using algebraic methods or Karnaugh maps. The book then relates Boolean algebra to logic gates, which are the basic building blocks of digital circuits. The book describes the symbols, truth tables, and functions of various logic gates, such as AND, OR, NOT, NAND, NOR, XOR, and XNOR. The book also shows how to construct complex logic circuits using combinations of logic gates.

Combinational logic circuits

The book then moves on to combinational logic circuits, which are digital circuits that produce outputs that depend only on the current inputs. The book explains how to design combinational logic circuits using various methods, such as truth tables, Boolean expressions, logic diagrams, or standard forms. The book also discusses some common types of combinational logic circuits, such as multiplexers, demultiplexers, encoders, decoders, adders, subtractors, comparators, parity generators and checkers, code converters, and magnitude comparators. The book explains the functions and applications of these circuits and how to analyze their performance.

Sequential logic circuits

The book then covers sequential logic circuits, which are digital circuits that produce outputs that depend on both the current inputs and the previous states. The book explains how to design sequential logic circuits using various methods, such as state diagrams, state tables, state equations, or state machines. The book also discusses some common types of sequential logic circuits, such as flip-flops, latches, registers, counters, shift registers, and timers. The book explains the functions and applications of these circuits and how to analyze their behavior.

Design and analysis of digital integrated circuits

The second part of the book focuses on the design and analysis of digital integrated circuits using various technologies. The book covers both MOSFETs (metal-oxide-semiconductor field-effect transistors) and bipolar transistors, which are the two main types of transistors used in digital integrated circuits. The book explains the characteristics, operation, and fabrication of these transistors and how they are used to implement different logic families, such as CMOS (complementary metal-oxide-semiconductor), TTL (transistor-transistor logic), ECL (emitter-coupled logic), and I2L (integrated injection logic). The book also discusses some important aspects of digital integrated circuit design, such as power dissipation, noise margin, propagation delay, fan-in, fan-out, and loading effects. The book also covers some advanced topics, such as memory devices and circuits, arithmetic and logic units, and microprocessors.

MOSFETs and CMOS logic families

The book starts with a review of MOSFETs, which are transistors that use an electric field to control the flow of current between two terminals. The book explains the structure, symbols, and operation modes of MOSFETs and how they can be classified into two types: n-channel MOSFETs and p-channel MOSFETs. ```html MOSFETs and CMOS logic families

The book starts with a review of MOSFETs, which are transistors that use an electric field to control the flow of current between two terminals. The book explains the structure, symbols, and operation modes of MOSFETs and how they can be classified into two types: n-channel MOSFETs and p-channel MOSFETs. The book then introduces CMOS logic families, which are logic families that use both n-channel and p-channel MOSFETs to form complementary pairs of logic gates. The book explains the advantages of CMOS logic families, such as low power consumption, high noise immunity, and high integration density. The book also describes the basic CMOS logic gates, such as CMOS inverters, CMOS NAND gates, CMOS NOR gates, and CMOS XOR gates. The book also shows how to design complex CMOS logic circuits using these gates.

Bipolar transistors and TTL logic families

The book then reviews bipolar transistors, which are transistors that use a small current to control a larger current between two terminals. The book explains the structure, symbols, and operation modes of bipolar transistors and how they can be classified into two types: npn transistors and pnp transistors. The book then introduces TTL logic families, which are logic families that use bipolar transistors to form logic gates. The book explains the advantages and disadvantages of TTL logic families, such as high speed, low cost, and high power consumption. The book also describes the basic TTL logic gates, such as TTL inverters, TTL NAND gates, TTL NOR gates, and TTL XOR gates. The book also shows how to design complex TTL logic circuits using these gates.

Memory devices and circuits

The book then covers memory devices and circuits, which are digital circuits that store and retrieve information in binary form. The book explains the different types of memory devices and circuits, such as ROM (read-only memory), RAM (random-access memory), PROM (programmable read-only memory), EPROM (erasable programmable read-only memory), EEPROM (electrically erasable programmable read-only memory), and flash memory. The book also discusses the characteristics and applications of these memory devices and circuits, such as capacity, access time, read/write cycle, non-volatility, and erasability. The book also shows how to design and implement memory devices and circuits using various technologies.

Arithmetic and logic units

The book then covers arithmetic and logic units (ALUs), which are digital circuits that perform arithmetic and logical operations on binary data. The book explains the functions and applications of ALUs in various digital systems, such as calculators, computers, and microprocessors. The book also shows how to design and implement ALUs using various methods and components, such as adders, subtractors, multipliers, dividers, shifters, comparators, and logic gates.

Advantages and disadvantages of the book

Pros

The book has many advantages that make it a valuable resource for learning about digital integrated electronics. Some of these advantages are:

Clear and concise explanations

The book provides clear and concise explanations of the concepts and principles of digital electronics and integrated circuits. The book uses simple language and avoids unnecessary jargon and technicalities. The book also uses examples and exercises to illustrate the concepts and reinforce the understanding of the readers. The book also provides tables, charts, and diagrams to summarize the important information and facilitate the learning process.

Numerous examples and exercises

The book provides numerous examples and exercises throughout the chapters to illustrate the concepts and test the understanding of the readers. The examples are relevant and practical, showing how the concepts can be applied in real-world situations. The exercises are challenging and varied, ranging from simple calculations to complex design problems. The exercises also have solutions at the end of the book, allowing the readers to check their answers and learn from their mistakes.

Coverage of both theory and practice

The book covers both the theory and practice of digital integrated electronics, providing a balanced and comprehensive approach to the subject. The book covers both the basic concepts and principles of digital electronics as well as the design and analysis of digital integrated circuits using various technologies. The book also covers some advanced topics, such as memory devices and circuits, arithmetic and logic units, and microprocessors. The book also provides references and suggestions for further reading at the end of each chapter, allowing the readers to explore the topics in more depth.

Cons

The book also has some disadvantages that may limit its usefulness and relevance for some readers. Some of these disadvantages are:

Outdated technology and references

The book was published in 1977, which means that some of the technology and references in the book are outdated and obsolete. The book does not cover some of the newer and more advanced technologies and developments in digital integrated electronics, such as nanotechnology, quantum computing, optical computing, and neuromorphic computing. The book also does not reflect some of the current standards and practices in digital integrated electronics, such as IEEE standards, design tools, simulation software, and testing methods.

Lack of color illustrations and diagrams

The book lacks color illustrations and diagrams, which may make it less appealing and engaging for some readers. The book uses black-and-white drawings and photographs to illustrate the concepts and components of digital integrated electronics, which may not be very clear or accurate. The book also uses schematic diagrams to represent the logic circuits, which may not be very intuitive or easy to follow. The book could benefit from using color illustrations and diagrams to enhance the visual appeal and clarity of the book.

High level of mathematical complexity

The book has a high level of mathematical complexity, which may make it difficult and intimidating for some readers. The book uses a lot of mathematical formulas, equations, and calculations to explain the concepts and principles of digital integrated electronics. The book also assumes that the readers have a solid background in circuit analysis, linear systems, electronics, and mathematics. The book could be more accessible and user-friendly by simplifying some of the mathematical expressions or providing more explanations and examples for them.

Conclusion

Summary of the main points

In conclusion, Digital Integrated Electronics by Herbert Taub and Donald Schilling is a classic book that provides a comprehensive introduction to the theory and practice of digital integrated electronics. The book covers both the basic concepts and principles of digital electronics as well as the design and analysis of digital integrated circuits using various technologies. The book also covers some advanced topics, such as memory devices and circuits, arithmetic and logic units, and microprocessors. The book has many advantages, such as clear and concise explanations, numerous examples and exercises, and coverage of both theory and practice. However, the book also has some disadvantages, such as outdated technology and references, lack of color illustrations and diagrams, and high level of mathematical complexity.

Recommendations for readers and learners

We recommend this book for readers and learners who are interested in learning about digital integrated electronics or who want to refresh their knowledge on the subject. We think this book is suitable for undergraduate students of electrical engineering who have some background in circuit analysis, linear systems, electronics, and mathematics. We also think this book can be used as a reference for graduate students, engineers, technicians, and hobbyists who want to learn more about digital integrated electronics. However, we suggest that readers and learners supplement this book with other sources that cover some of the newer and more advanced technologies and developments in digital integrated electronics. We also suggest that readers and learners use color illustrations and diagrams to enhance their understanding of the concepts and components of digital integrated electronics. We also suggest that readers and learners review some of the mathematical formulas, equations, and calculations in the book or seek help from other sources if they find them difficult or confusing.

FAQs

• Q: Where can I find a PDF version of this book?

• A: You can find a PDF version of this book on various websites, such as archive.org, doku.pub, and pdfdrive.com. However, you should be careful about the quality, legality, and safety of these websites and make sure you have permission to download or use the PDF version.

• Q: How can I cite this book in my academic work?

• A: You can cite this book in your academic work using various citation styles, such as APA, MLA, or Chicago. However, you should follow the guidelines and rules of your institution or discipline and make sure you cite the correct edition or version of the book. Here is an example of how to cite this book in APA style: Taub, H., & Schilling, D. L. (1977). Digital integrated electronics. McGraw-Hill.

• ```html Q: What are some other books that are similar or complementary to this book?

A: Some other books that are similar or complementary to this book are:

• Digital Design by M. Morris Mano and Michael D. Ciletti

• Microelectronic Circuits by Adel S. Sedra and Kenneth C. Smith

• Modern Digital Electronics by R. P. Jain

• Digital Systems: Principles and Applications by Ronald J. Tocci, Neal S. Widmer, and Gregory L. Moss

• Fundamentals of Digital Logic with Verilog Design by Stephen Brown and Zvonko Vranesic

These books cover some of the same topics as this book, but also include some newer and more advanced topics, such as Verilog design, FPGA (field-programmable gate array), and VHDL (VHSIC hardware description language).

• Q: How can I learn more about digital integrated electronics online?

A: You can learn more about digital integrated electronics online by using various resources, such as websites, videos, courses, and podcasts. Some of these resources are:

• The website of All About Circuits (https://www.allaboutcircuits.com/), which provides articles, tutorials, projects, and forums on various topics related to electronics, including digital integrated electronics.

• The YouTube channel of Neso Academy (https://www.youtube.com/c/NesoAcademy/videos), which provides videos on various topics related to electrical engineering, including digital integrated electronics.

• The course of Digital Integrated Circuits on Coursera (https://www.coursera.org/learn/digital-integrated-circuit-design), which provides lectures, quizzes, assignments, and projects on various topics related to digital integrated circuit design.

• The podcast of The Amp Hour (https://theamphour.com/), which provides interviews, discussions, and news on various topics related to electronics, including digital integrated electronics.

These resources can help you learn more about digital integrated electronics in a fun and interactive way.

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