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Basic Digital Electronics PDF

231 Pages·1991·4.27 MB·English
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Basic Digital Electronics 'Contrariwise,' continued Tweedledee, 'if it was so, it might be; and if it were so, it would be: but as it isn't, it ain't. That's logic' (Carroll: Alice Through the Looking Glass) PHYSICS AND ITS APPLICATIONS Series Editor E.R. Dobbs University of London This series of short texts on advanced topics for students, scientists and engineers will appeal to readers seeking to broaden their knowledge of the physics underlying modern technology. Each text provides a concise review of the fundamental physics and current developments in the area, with references to treatises and the primary literature to facilitate further study. Additionally texts providing a core course in physics are included to form a ready reference collection. The rapid pace of technological change today is based on the most recent scientific advances. This series is, therefore, particularly suitable for those engaged in research and development, who frequently require a rapid summary of another topic in physics or a new application of physical principles in their work. Many of the texts will also be suitable for final year undergraduate and postgraduate courses. 1. Electrons in Metals and Semiconductors R. G. Chambers 2. Basic Digital Electronics J. A. Strong 3. AC and DC Network Theory Anthony J. Pointon and Harry M. Howarth 4. Nuclear and Particle Physics R. J. Blin-Stoyle Basic Digital Electronics J.A. 5trong Reader in Experimental Physics University of London SPRINGER-SCIENCE+BUSINESS MEDIA, B.v. First edition 1991 © 1991 J. A. Strong Originally published by CHAPMAN AND HALL 1991 Typeset in 10/12 Times by Thomson Press (India) Ltd, New Delhi ISBN 978-0-412-39990-9 AII rights reserved. No part of this publication may be reproduced Of transmitted, in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, or stored in any retrieval system of any nature, without the written permission of the copyright holder and the publisher, application for which shall be made to the publisher. The publisher makes no representation, express or implied, with regard to the accuracy of the information contained in this book and cannot accept any legal responsibility or liability for any errors or omissions that may be made. British Library Cataloguing in Publication Data Strong, J. A. Basic digital electronics 1. Electronics I. Title II. Series 537.5 ISBN 978-0-412-39990-9 Library ofCongress Cataloging-in-Publication Data Strong, J. A. (John A.), 1941- Basic digital electronics / J. A. Strong.-lst ed. p. cm.-(Physics and its applications; 2) Includes bibliographical references and index. ISBN 978-0-412-39990-9 ISBN 978-94-011-3118-6 (eBook) DOI 10.1007/978-94-011-3118-6 1. Digital electronics. I. Title. II. Series. TK7868.D5S79 1991 621.381-dc20 90-2689 CIP Contents Preface ix Acknowledgements xi 1 Introduction 1 1.1 Preamble 1 1.2 History 2 1.3 Sentence analysis and truth tables 2 1.4 Number systems 4 1.5 Gates and memories 6 1.6 Integrated circuits 6 Problems 8 2 Basic gates 10 2.1 Introduction 10 2.2 Logic levels 10 2.3 Gating functions 12 2.4 Basic gates and symbols 12 2.5 Boolean algebra and truth tables 15 2.6 Universal logic elements 18 2.7 Gate minimization 20 2.8 NAND and NOR implementation 24 2.9 Limitations of the minimization process 25 2.10 Don't care and can't happen conditions 27 2.11 Hazards and glitches 28 2.12 Alternative symbols 31 2.13 Chip list 32 Problems 32 Practical exercises 35 vi Contents 3 Gating circuits 37 3.1 Introduction 37 3.2 Decoders 37 3.3 Decoders as logic elements 41 3.4 Multiplexers 42 3.5 Multiplexers as logic elements 45 3.6 Parity 46 3.7 Memories as logic elements 48 3.8 Programmable logic 49 3.9 Binary addition 54 3.10 Full-adder circuits 57 3.11 Look-ahead carry circuits 59 3.12 Decimal addition 60 3.13 Binary subtraction 62 3.14 Multiplication 64 3.15 Division 66 3.16 Chip list 66 Problems 67 Practical exercises 70 4 Latches and flip-flops 73 4.1 Introduction 73 4.2 Aims 73 4.3 The set-reset flip-flop 74 4.4 The set-reset flip-flop as a switch debouncer 77 4.5 The data latch 77 4.6 The data flip-flop 80 4.7 Synchronization of external signals 83 4.8 The JK flip-flop 84 4.9 The T flip-flop 86 4.10 Multivibrators 87 4.11 Chip list 90 Problems 90 Practical exercises 92 5 Registers and counters 95 5.1 Introduction 95 5.2 Aims 96 5.3 Basic register 96 Contents VB 5.4 Shift register 97 5.5 Ring counters 100 5.6 Counters 103 5.7 Asynchronous counters 104 5.8 Modulo-n asynchronous counters 107 5.9 Synchronous counters 110 5.10 Synchronous system design 115 5.11 Modulo-5 counter using JK flip-flops 115 5.12 Modulo-5 counter using T flip-flops 118 5.13 Modulo-3 up/down counter using JK flip-flops 120 5.14 Decade counter using D flip-flops 123 5.15 Chip list 125 Problems 126 Practical exercises 130 6 Memories 131 6.1 Introduction and aims 131 6.2 Memory types and uses 132 6.3 Memory architecture 133 6.4 Memory arrays and buses 137 6.5 Memory read and write cycles 138 6.6 A practical memory circuit 141 6.7 Chip list 142 Problems 143 Practical exercises 144 7 The analogue connection 146 7.1 Introduction 146 7.2 Aims 147 7.3 Digital-to-analogue conversion 148 7.4 The R -2R ladder 149 7.5 Practical DACs 152 7.6 A microprocessor-compatible DAC 152 7.7 A multiplying DAC 154 7.8 Uses for DACs 157 7.9 Accuracy and resolution of DACs 157 7.10 Analogue-to-digital conversion 159 7.11 Integrator ADCs 159 7.12 Single-slope conversion 160 7.13 Dual-slope ADC 162 viii Contents 7.14 Other ADCs using integrators 164 7.15 Analogue-to-digital conversion using DACs 165 7.16 The tracking ADC 165 7.17 The successive-approximation ADC 167 7.18 Flash ADCs 170 7.19 Chip list 172 Problems 173 Practical exercises 174 Appendix 1 Boolean algebra 178 AU Rules 178 At.2 Algebraic minimization 179 At.3 Minimization in product-of-sums form 181 Appendix 2 Logic families 182 A2.1 TTL circuits 182 A2.2 Open-collector output 185 A2.3 Tri-state output 186 A2A Schmitt trigger inputs 187 A2.5 Schottky TTL 189 A2.6 Emitter-coupled logic (ECL) 190 A2.7 MOS logic 191 A2.8 Conversion between TTL and CMOS 193 A2.9 A CMOS oscillator circuit 195 Appendix 3 Designing and testing 196 A3.1 Designs and diagrams 196 A3.2 Proto typing methods 198 A3.3 Testing 199 Answers to problems 201 Further reading 210 Index 212 Preface Modern electronics is the most visible result of research in solid state physics. Transistors and integrated circuits are used everywhere in ever increasing numbers. The microprocessor controlled coffee-pot exists. Most experimental physicists, and, indeed, experimental scientists in most disciplines, study their subject with the aid of apparatus containing significant amounts of electronics and much of that electronics is digital. In order to design experiments and apparatus or simply to understand how a piece of equipment works, an under standing of electronics has become increasingly important. In recognition that electronics has pervaded so many areas, courses in digital electronics are now a recommended part of physics and many other science degree courses. At the introductory level, digital electronics is, primarily, a practical subject with relatively few basic concepts and any complex ity arises from the coupling together of many simple circuits and the extensive use of feedback. Designing an electronic circuit and then getting it to work correctly provides an experience, and a sense of achievement, which is significantly different from most undergradu ate work as it more closely resembles project work than standard laboratory practicals. For many years, I have been convinced of the value to students of understanding electronics and have taught a number of courses at different levels. This book is based on the introductory material given to physics and computer science students over several years but with extensive updating in an attempt to keep pace with rapid changes in the field. I have concentrated on the basic ideas and provided examples of the circuits and techniques used together with a

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Modern electronics is the most visible result of research in solid state physics. Transistors and integrated circuits are used everywhere in ever increasing numbers. The microprocessor controlled coffee-pot exists. Most experimental physicists, and, indeed, experimental scientists in most discipline
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