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E-raamat: Analog and Pulse Circuits [Taylor & Francis e-raamat]

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  • Formaat: 176 pages, 196 Line drawings, black and white; 196 Illustrations, black and white
  • Ilmumisaeg: 10-Mar-2022
  • Kirjastus: CRC Press
  • ISBN-13: 9781003274582
Teised raamatud teemal:
  • Taylor & Francis e-raamat
  • Hind: 133,87 €*
  • * hind, mis tagab piiramatu üheaegsete kasutajate arvuga ligipääsu piiramatuks ajaks
  • Tavahind: 191,24 €
  • Säästad 30%
Analog and Pulse CircuitsSuurem pilt
  • Formaat: 176 pages, 196 Line drawings, black and white; 196 Illustrations, black and white
  • Ilmumisaeg: 10-Mar-2022
  • Kirjastus: CRC Press
  • ISBN-13: 9781003274582
Teised raamatud teemal:
Taylor & Francis e-raamatudRohkem infot Taylor & Francis e-raamatute kohta
Raamatu kodulehekülg: https://www.taylorfrancis.com/books/9781003274582
This book is intended for anyone who has an interest to learn the analysis and design of analog and digital systems. The book covers the foundation of analysis and design of all analog and pulse circuits.
Note: T& F does not sell or distribute the Hardback in India, Pakistan, Nepal, Bhutan, Bangladesh and Sri Lanka.

This book is intended for anyone who has an interest to learn the analysis and design of analog and digital systems. The book covers the foundation of analysis and design of all analog and pulse circuits. The book is organized into seven chapters. In each chapter, practical derivations are explained step by step.
Note: T& F does not sell or distribute the Hardback in India, Pakistan, Nepal, Bhutan, Bangladesh and Sri Lanka.
Preface v
Chapter 1 Linear Wave Shaping
1(41)
1.1 Introduction
1(1)
1.2 High Pass RC Circuit
1(1)
1.3 Sinusoidal Input
2(1)
1.4 Step Input Voltage
3(2)
1.5 Pulse Input
5(2)
1.6 Square-Wave Input
7(4)
1.7 Ramp Input
11(2)
1.8 Exponential Input (HPF)
13(2)
1.9 Sinusoidal Input
15(2)
1.10 High Pass RC Circuit as a Differentiator
17(1)
1.11 Low-pass RC Circuit
18(2)
1.12 Step Voltage Input
20(3)
1.13 Pulse Input Voltage
23(2)
1.14 Square Wave Input
25(2)
1.15 Exponential Input: (LPF)
27(2)
1.16 Low Pass RC Circuit as an Integrator
29(1)
1.17 Attenuators
30(1)
1.18 Step Input Response
31(2)
1.19 High Pass RC Circuit
33(2)
1.20 Step Input Voltage of High Pass RL Circuit
35(1)
1.21 Low Pass RL Circuit
36(1)
1.22 Step Input Voltage of Low Pass RC Circuit
37(1)
1.23 Ringing Circuit
38(1)
1.24 RLC Series Circuit
39(2)
1.25 RLC Parallel Circuit
41(1)
Chapter 2 Non Linear Wave Shaping
42(30)
2.1 Introduction
42(1)
2.2 Clipper Circuit (or) Limiter
42(1)
2.3 Series Negative Clipper Circuit
43(2)
2.4 Series Positive Clipper Circuit
45(1)
2.5 Clipping above Reference Voltage VR
46(1)
2.6 Clipping below Reference Voltage VR
47(2)
2.7 Additional DC Supply in Series with Diode
49(1)
2.8 Parallel Positive Clipper
50(1)
2.9 Parallel Positive Clipper with Cutin Voltage Diode
51(1)
2.10 Parallel Negative Clipper
52(1)
2.11 Parallel Clipper with Reference Voltage Vr
53(2)
2.12 Parallel Negative Clipper with VR (Reference Voltage)
55(2)
2.13 Two Way Parallel Clipper Circuit
57(1)
2.14 Transistor Clipper
58(2)
2.15 Emitter Coupled Clipper
60(2)
2.16 Voltage Comparator
62(2)
2.17 Clamper Circuits
64(2)
2.18 Clamping Circuit Theorem
66(2)
2.19 Clipper Circuits and Waveform
68(4)
Chapter 3 Switching Characteristics of Devices
72(14)
3.1 Introduction
72(1)
3.2 Switching Characteristics of Junction Diodes
72(1)
3.3 Switching Times of PN Junction Diode
73(2)
3.4 Breakdown Mechanisms in PN Junction Diode
75(2)
3.5 Transistors as a Switch
77(2)
3.6 Transistor Breakdown Voltage
79(5)
3.7 Transistor Switching Times
84(2)
Chapter 4 Multi-vibrator
86(22)
4.1 Introduction
86(1)
4.2 Bistable Multi-vibrator
87(2)
4.3 Collector Catching Diodes using a Fixed-bias Binary Multi-vibrator
89(1)
4.4 Self Biased Transistor Bistable Multi-vibrator
89(1)
4.5 Speed-up Capacitor (or) Commutating Capacitor
90(1)
4.6 Non-saturating Binary
91(1)
4.7 Unsymmetrical Triggering of Bistable Multi vibrator
92(2)
4.8 Unsymmetrical Triggering using Unilateral Device (Diode)
94(1)
4.9 Triggering Symmetrically Through a Unilateral Device
95(2)
4.10 Direct-connection Binary
97(1)
4.11 Mono Stable Multi-vibrator
98(5)
4.12 Emitter Coupled Mono Stable Multi-vibrator
103(3)
4.13 Triggering of Mono Stable Multi-vibrator
106(2)
Chapter 5 Time Base Generator
108(22)
5.1 Errors of Generation of Sweep Waveform
108(1)
5.2 Displacement Error (Ed)
108(1)
5.3 Transmission Error
109(6)
5.4 UJT Saw Tooth Generators
115(2)
5.5 Separate Supply Voltage of UJT Saw Tooth Generator
117(1)
5.6 A Transistor Constant Current Sweep
118(3)
5.7 Miller Voltage Generators
121(2)
5.8 Bootstrap Voltage Generators
123(2)
5.9 Practical Bootstrap Sweep Generator
125(5)
Chapter 6 Logic Gates
130(21)
6.1 The and Gate
130(1)
6.2 The not Gate (Inverter)
131(2)
6.3 The Universal Gates
133(4)
6.4 The Derived Gates
137(2)
6.5 CMOS Logic Families
139(7)
6.6 Characteristics of Logic Family
146(1)
6.7 Two-input TTL N and Gate (Standard TTL)
147(1)
6.8 Totem-pole Output
148(1)
6.9 Open-collector Gates
149(2)
Chapter 7 Sampling Gates
151
7.1 Introduction
151(1)
7.2 Basic Operating Principle of Sampling Gates
151(1)
7.3 Unidirectional Sampling Gates
152(2)
7.4 Unidirectional Sampling Gates for more than one Input Signal
154(1)
7.5 Sampling Gate with Multiple Gate Signals
155(1)
7.6 Sampling Gate not Sensitive to Higher Level of Gate Signal
155(1)
7.7 Bidirectional Sampling Gates
155(2)
7.8 Bidirectional Diode Sampling Gate
157(2)
7.9 Four Diode Sampling Gate
159(2)
7.10 Six Diode Sampling Gate
161(2)
7.11 Chopper Stabilized Amplifier
163
Dayaydi Lakshmaiah, SIIET, Hyderabad, Telangana, India

C. B. Ramarao, National Institute of Technology, Warangal, Telangana, India

K. Kishan Rao, National Institute of Technology, Warangal, Telangana, India
Püsilink: https://www.kriso.ee/db/9781003274582_pe.html
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