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๐Ÿ“

Op amps for everyone

โœ Scribed by Carter, Bruce

Publisher
Newnes
Year
2013
Tongue
English
Leaves
284
Edition
4th ed
Category
Library
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โœฆ Synopsis

Op Amps for Everyone is an indispensable guide and reference for designing circuits that are reliable, have low power consumption, and are as small and low-cost as possible. Operational amplifiers are essential in modern electronics design, and are used in medical devices, communications technology, optical networks, and sensor interfacing.

This book is informed by the authors' years of experience, wisdom and expertise, giving engineers all the methods, techniques and tricks that they need to optimize their analog electronic designs.

With this book you will learn:

  • Single op amp designs that get the most out of every amplifier
  • Which specifications are of most importance to your design, enabling you to narrow down the list of amplifiers to those few that are most suitable
  • Strategies for making simple "tweaks" to the design โ€“ changes that are often apparent once a prototype has been constructed
  • How to design for hostile environments โ€“ extreme temperatures, high levels of shock, vibration, and radiation โ€“ by knowing what circuit parameters are likely to degrade and how to counteract that degradation

New to this edition:

  • Unified design procedures for gain and offset circuits, and filter circuits
  • Techniques for voltage regulator design
  • Inclusion of design utilities for filter design, gain and offset, and voltage regulation
  • Analysis of manufacturer design aids
  • Companion website with downloadable material
  • A complete, cookbook-style guide for designing and building analog circuits
  • A multitude of workable designs that are ready to use, based on real-world component values from leading manufacturers using readily available components
  • A treasure trove of practical wisdom: strategies to tweak a design; guidelines for developing the entire signal chain; designing for hostile environments, and more

โœฆ Table of Contents

Content: Machine generated contents note: ch. 1 The Op Amp's Place in the World --
1.1. An Unbounded Gain Problem --
1.2. The Solution --
1.3. The Birth of the Op Amp as a Component --
1.3.1. The Vacuum Tube Era --
1.3.2. The Transistor Era --
1.3.3. The Integrated Circuit Era --
Reference --
ch. 2 Review of Op Amp Basics --
2.1. Introduction --
2.2. Basic Concepts --
2.2.1. Ohm's Law --
2.2.2. The Voltage Divider Rule --
2.2.3. Superposition --
2.3. Basic Op Amp Circuits --
2.3.1. The Non-Inverting Op Amp --
2.3.2. The Inverting Op Amp --
2.3.3. The Adder --
2.3.4. The Differential Amplifier --
2.4. Not So Fast! --
ch. 3 Separating and Managing AC and DC Gain --
3.1.A Small Complication --
3.2. Single Supply versus Dual Supply --
3.3. Simultaneous Equations --
3.3.1. Case 1: Vout= +mVin + b --
3.3.2. Case 2: Vout = +mVin --
b --
3.3.3. Case 3: Vout = -mVin + b --
3.3.4. Case 4: Vout = -mVin --
b --
3.4. So, Where to Now? --
3.5.A Design Procedure, and a Design Aid --
3.6. Summary --
ch. 4 Different Types of Op Amps --
4.1. Voltage Feedback Op Amps --
4.2. Uncompensated/Undercompensated Voltage Feedback Op Amps --
4.3. Current Feedback Op Amps --
4.4. Fully Differential Op Amps --
4.4.1. What Does "Fully Differential" Mean? --
4.4.2. How is the Second Output Used? --
4.4.3. Differential Gain Stages --
4.4.4. Single-Ended to Differential Conversion --
4.4.5.A New Function --
4.5. Instrumentation Amplifier --
4.6. Difference Amplifier --
4.7. Buffer Amplifiers --
4.8. Other Types of Op Amps --
ch. 5 Interfacing a Transducer to an Analog-to-Digital Converter --
5.1. Introduction --
5.2. System Information --
5.3. Power Supply Information --
5.4. Input Signal Characteristics --
5.5. Analog-to-Digital Converter Characteristics --
5.6. Interface Characteristics --
5.7. Architectural Decisions --
5.8. Conclusions --
ch. 6 Active Filter Design Techniques --
6.1. Introduction --
6.2. The Transfer Equation Method --
6.3. Fast, Practical Filter Design --
6.3.1. Picking the Response --
6.3.2. Low-Pass Filter --
6.3.3. High-Pass Filter --
6.3.4. Narrow (Single-Frequency) Bandpass Filter --
6.3.5. Wide Bandpass Filter --
6.3.6. Notch (Single-Frequency Rejection) Filter --
6.4. High-Speed Filter Design --
6.4.1. High-Speed Low-Pass Filters --
6.4.2. High-Speed High-Pass Filters --
6.4.3. High-Speed Bandpass Filters --
6.4.4. High-Speed Notch Filters --
6.5. Getting the Most Out of a Single Op Amp --
6.5.1. Three-Pole Low-Pass Filters --
6.5.2. Three-Pole High-Pass Filters --
6.5.3. Stagger-Tuned and Multiple-Peak Bandpass Filters --
6.5.4. Single-Amplifier Notch and Multiple-Notch Filters --
6.5.5.Combination Bandpass and Notch Filters --
6.6. Biquad Filters --
6.7. Design Aids --
6.7.1. Low-Pass, High-Pass, and Bandpass Filter Design Aids --
6.7.2. Notch Filter Design Aids --
6.7.3. Twin-T Design Aids --
6.7.4. Final Comments on Filter Design Aids --
6.8. Summary --
ch. 7 Using Op Amps for Radio frequency Design --
7.1. Introduction --
7.2. Voltage Feedback or Current Feedback? --
7.3. Radiofrequency Amplifier Topology --
7.4. Op Amp Parameters for Radio frequency Designers --
7.4.1. Stage Gain --
7.4.2. Phase Linearity --
7.4.3. Frequency Response Peaking --
7.4.4.-1 dB Compression Point --
7.4.5. Noise Figure --
7.5. Wireless Systems --
7.5.1. Broadband Amplifiers --
7.5.2. Intermediate-Frequency Amplifiers --
7.6. High-Speed Analog Input Drive Circuits --
7.7. Conclusions --
ch. 8 Designing Low-Voltage Op Amp Circuits --
8.1. Introduction --
8.2. Critical Specifications --
8.2.1. Output Voltage Swing --
8.2.2. Dynamic Range --
8.2.3. Input Common-Mode Range --
8.2.4. Signal-to-Noise Ratio --
8.3. Summary --
ch. 9 Extreme Applications --
9.1. Introduction --
9.2. Temperature --
9.2.1. Noise --
9.2.2. Speed --
9.2.3. Output Drive and Stage --
9.2.4. So, What Degrades at High Temperature? --
9.2.5. Final Parameter Comments --
9.3. Packaging --
9.3.1. The Integrated Circuit Itself --
9.3.2. The Integrated Circuit Package --
9.3.3. Connecting the Integrated Circuit --
9.4. When Failure Is Not an Option --
9.5. When It Has to Work for a Really Long Time --
9.6. Conclusions --
ch. 10 Voltage Regulation --
10.1. Introduction --
10.2. Regulator Cases --
10.2.1. Virtual Ground: b = 0 --
10.2.2. Positive and Negative Voltage Regulators: b&gt
0, b &lt
0 --
10.3. Make or Buy? --
10.4. Linear Regulators --
10.5. Switching Power Supplies --
10.6.A Companion Circuit --
10.7. Another Companion Circuit --
10.8. Design Aid --
10.9. Conclusions --
ch. 11 Other Applications --
11.1. Introduction --
11.2. Interfacing Digital-to-Analog Converters to Loads --
11.3. Op Amp Oscillators --
11.4. Hybrid Amplifiers and Power Boosters --
11.5. Conclusions --
ch. 12 Manufacturer Design Aids --
12.1. Introduction --
12.2. Texas Instruments Tina-TI --
12.3. Texas Instruments Filter Pro --
12.4. National Semiconductor/Texas Instruments Webench --
12.5. Analog Devices Version of NI Multisim --
12.6. Analog Devices OpAmp Error Budget --
12.7. Linear Technology LT Spice --
12.8. Printed Circuit Board Layout --
12.9. Conclusions --
ch. 13 Common Application Mistakes --
13.1. Introduction --
13.2. Op Amp Operated at Less Than Unity (or Specified) Gain --
13.3. Op Amp Used as a Comparator --
13.3.1. The Comparator --
13.3.2. The Op Amp --
13.4. Improper Termination of Unused Sections --
13.5. DC Gain --
13.6. Current Feedback Amplifier Mistakes --
13.6.1. Shorted Feedback Resistor --
13.6.2. Capacitor in the Feedback Loop --
13.7. Fully Differential Amplifier Mistakes --
13.7.1. Incorrect DC Operating Point --
13.7.2. Incorrect Common-Mode Range --
13.7.3. Incorrect Single-Ended Termination --
13.8. Improper Decoupling --
13.9. Conclusions.

โœฆ Subjects

Operational amplifiers.

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