Title:
Analog integrated circuits applications
Personal Author:
Publication Information:
Upper Saddle River, N. J. : Prentice Hall, 2000
ISBN:
9780130809094
Available:*
Library | Item Barcode | Call Number | Material Type | Item Category 1 | Status |
|---|---|---|---|---|---|
Searching... | 30000004979054 | TK7874 J33 2000 | Open Access Book | Book | Searching... |
Searching... | 30000004979013 | TK7874 J33 2000 | Open Access Book | Book | Searching... |
On Order
Summary
Summary
For courses in Operational Amplifiers. This text is fully updated and revised to incorporate the latest technology.
Table of Contents
| Preface | p. viii |
| 1 Introduction to the Operational Amplifier Integrated Circuit | p. 1 |
| Objectives | p. 1 |
| 1-1 Analog Integrated Circuit | p. 2 |
| 1-2 The Ideal Operational Amplifier | p. 4 |
| 1-3 Basic Specifications and Requirements | p. 7 |
| 1-3.1 Specifications of Initial Importance | p. 8 |
| 1-3.2 Power Supply Requirements | p. 10 |
| 1-3.3 Packaging | p. 12 |
| 1-4 General Breadboarding Hints | p. 14 |
| Summary | p. 19 |
| Problems | p. 20 |
| 2 Amplifiers and Feedback | p. 22 |
| Objectives | p. 22 |
| 2-1 Open Loop Operation | p. 23 |
| 2-1.1 Op Amp Comparators | p. 23 |
| 2-1.2 Hysteresis | p. 31 |
| 2-1.3 The LM339 Comparator Integrated Circuit | p. 35 |
| 2-1.4 The LM311 Comparator Integrated Circuit | p. 40 |
| 2-1.5 LED Drivers | p. 43 |
| 2-2 Effects of Negative Feedback | p. 48 |
| 2-3 Voltage Follower | p. 51 |
| 2-4 Noninverting Amplifier | p. 54 |
| 2-5 Inverting Amplifier | p. 58 |
| 2-6 Inverting Summer | p. 61 |
| 2-7 Difference Amplifier | p. 67 |
| 2-8 A General Approach | p. 72 |
| Summary | p. 79 |
| Problems | p. 81 |
| Comparator Analysis Lab Exercise | p. 91 |
| Noninverting Amplifiers Lab Exercise | p. 94 |
| 3 Digital Control of Analog Functions | p. 96 |
| Objectives | p. 96 |
| 3-1 Analog Switch | p. 97 |
| 3-2 Digital Potentiometer | p. 104 |
| 3-3 Digital to Analog Converters | p. 111 |
| 3-3.1 Overview of Digital to Analog Converters | p. 112 |
| 3-3.2 Current Out Digital to Analog Converters | p. 115 |
| 3-3.3 Voltage Out Digital to Analog Converters | p. 120 |
| Summary | p. 124 |
| Problems | p. 126 |
| Digital to Analog Converter Lab Exercise | p. 129 |
| 4 Power Supplies and Integrated Circuit Regulators | p. 132 |
| Objectives | p. 132 |
| 4-1 Full Wave Rectified, Capacitive Filtered Power Supplies | p. 133 |
| 4-1.1 Light Load Capacitive Filtering | p. 133 |
| 4-1.2 Rectifier Surge Current | p. 136 |
| 4-1.3 Heavy Load Capacitive Filtering | p. 137 |
| 4-2 Simple Op amp Regulator | p. 142 |
| 4-3 Three-Terminal Regulators | p. 146 |
| 4-3.1 Characteristics | p. 147 |
| 4-3.2 Regulator Circuit Components | p. 149 |
| 4-3.3 Heat Sinks | p. 150 |
| 4-3.4 Adjustable Voltage Supplies | p. 154 |
| 4-3.5 Dual Voltage Supplies | p. 156 |
| 4-4 Switched Capacitor Voltage Conversion | p. 159 |
| 4-5 Switching Power Supplies | p. 166 |
| 4-5.1 The Buck Regulator | p. 167 |
| 4-5.2 Continuous and Discontinuous Operation | p. 173 |
| 4-5.3 Integrated Circuit Buck Regulator | p. 176 |
| 4-5.4 Boost Regulator | p. 181 |
| 4-5.5 Other Switching Regulator Topologies | p. 193 |
| Summary | p. 199 |
| Problems | p. 200 |
| Dual Tracking Regulator Lab Exercise | p. 205 |
| Switched Capacitor Voltage Converter Lab Experiment | p. 206 |
| 5 Operational Amplifier Characteristics | p. 207 |
| Objectives | p. 207 |
| 5-1 DC Characteristics | p. 208 |
| 5-1.1 Input Offset Voltage | p. 208 |
| 5-1.2 Bias Currents | p. 211 |
| 5-1.3 Offset Currents | p. 214 |
| 5-1.4 Combined Effects | p. 216 |
| 5-1.5 Characteristic Measurements | p. 218 |
| 5-1.6 Drift | p. 223 |
| 5-2 AC Characteristics | p. 224 |
| 5-2.1 Gain Bandwidth Product | p. 224 |
| 5-2.2 Small Signal Rise Time | p. 231 |
| 5-2.3 Slew Rate | p. 232 |
| 5-2.4 Full Power Response | p. 234 |
| 5-2.5 AC Noise | p. 235 |
| 5-2.6 External Frequency Compensation | p. 240 |
| 5-3 Types of Op Amps | p. 243 |
| 5-4 Composite Amplifiers | p. 251 |
| 5-4.1 Suspended Supply | p. 252 |
| 5-4.2 Integrator Feedback | p. 256 |
| Summary | p. 262 |
| Problems | p. 263 |
| Op Amp DC Characteristic Measurements Lab Exercise | p. 269 |
| Op Amp Speed Lab Exercise | p. 270 |
| 6 Layout of Analog Circuits | p. 273 |
| Objectives | p. 273 |
| 6-1 Partition the Circuit | p. 274 |
| 6-2 Mechanical Details | p. 274 |
| 6-3 Component Placement | p. 278 |
| 6-4 Traces | p. 284 |
| 6-5 Other Common Mistakes | p. 292 |
| Summary | p. 293 |
| Problem | p. 295 |
| 7 Single Supply Amplifiers | p. 296 |
| Objectives | p. 296 |
| 7-1 Operating the Op Amp from a Single Supply | p. 297 |
| 7-2 AC Inverting Amplifier | p. 299 |
| 7-3 AC Noninverting Amplifier | p. 308 |
| 7-4 Single Supply Splitter | p. 311 |
| Summary | p. 316 |
| Problems | p. 317 |
| Single Supply Op Amp Lab Exercise | p. 319 |
| 8 Waveform Generators | p. 321 |
| Objectives | p. 321 |
| 8-1 Square Wave Generators | p. 322 |
| 8-1.1 The 555 Timer | p. 322 |
| 8-1.2 Crystal Controlled Oscillators | p. 327 |
| 8-2 Ramp Generators | p. 329 |
| 8-2.1 Triangle Wave Generator | p. 329 |
| 8-2.2 Sawtooth Generator | p. 338 |
| 8-3 Function Generator | p. 343 |
| 8-4 Digitally Controlled Frequency Synthesizers | p. 354 |
| 8-4.1 Phase Locked Loop Fundamentals | p. 355 |
| 8-4.2 PLL Synthesizers | p. 363 |
| 8-4.3 Totally Digital Synthesizer | p. 370 |
| Summary | p. 377 |
| Problems | p. 378 |
| XR-2206 Function Generator Lab Experiment | p. 386 |
| Phase Locked Loop Frequency Synthesizer Lab Exercise | p. 392 |
| References | p. 394 |
| 9 Active Filters | p. 395 |
| Objectives | p. 395 |
| 9-1 Introduction to Filtering | p. 396 |
| 9-1.1 Frequency Response | p. 396 |
| 9-1.2 Characteristics and Terminology | p. 405 |
| 9-1.3 Active versus Passive Filters | p. 409 |
| 9-2 Low Pass Filter | p. 411 |
| 9-2.1 Second-Order Sallen-Key Filter | p. 411 |
| 9-2.2 Second-Order Low Pass Sallen-Key Characteristics | p. 413 |
| 9-2.3 Higher-Order Filters | p. 423 |
| 9-3 High Pass Active Filter | p. 428 |
| 9-4 Band Pass Filter | p. 434 |
| 9-4.1 Single Op Amp Band Pass Filter | p. 435 |
| 9-4.2 Multistage Bandpass Filters | p. 442 |
| 9-5 State Variable Filter | p. 446 |
| 9-6 Notch Filter | p. 458 |
| 9-6.1 Band Pass and Summer | p. 458 |
| 9-6.2 State Variable Implementation | p. 462 |
| 9-7 Voltage Controlled Filter | p. 467 |
| 9-8 Switched Capacitor Filters | p. 477 |
| 9-8.1 Switched Capacitor Filter Fundamentals | p. 477 |
| 9-8.2 A Low Pass, Switched Capacitor, Filter IC | p. 482 |
| 9-8.3 A State Variable, Switched Capacitor, Filter IC | p. 486 |
| Summary | p. 489 |
| Problems | p. 492 |
| Sallen-Key, Low Pass, Active Filter Lab Exercise | p. 501 |
| State Variable, Active Filter Lab Exercise | p. 502 |
| 10 Nonlinear Circuits | p. 503 |
| Objectives | p. 503 |
| 10-1 Diode Feedback Circuits | p. 504 |
| 10-1.1 Ideal Rectifier | p. 504 |
| 10-1.2 Peak Detector | p. 508 |
| 10-1.3 Transfer Curve Synthesizer | p. 511 |
| 10-2 True RMS Converters | p. 525 |
| 10-3 Logarithmic and Antilogarihmic Amplifiers | p. 533 |
| 10-4 Multipliers | p. 538 |
| 10-4.1 Multiplier Characteristics | p. 538 |
| 10-4.2 Multiplier Applications | p. 541 |
| 10-4.3 Dividers | p. 545 |
| 10-4.4 Operational Transconductance Amplifier | p. 548 |
| Summary | p. 557 |
| Problems | p. 558 |
| Ideal Rectifier Lab Exercise | p. 563 |
| Operational Transconductance Amplifier Lab Exercise | p. 565 |
| Answers to Odd-Numbered Problems | p. 568 |
| Index | p. 574 |
