| List of Figures and Photos | p. xiii |
| List of Tables | p. xxv |
| Acknowledgements | p. xxix |
| A Short History of References | p. 1 |
| Introduction | p. 1 |
| The first JFETs and op amps | p. 3 |
| The first bandgaps | p. 5 |
| The buried-zener debuts | p. 7 |
| Advancements in technology | p. 8 |
| Other topologies emerge | p. 9 |
| An Introduction to Current Sources | p. 13 |
| An overview | p. 13 |
| Precision resistors, networks, and trimmers | p. 21 |
| Essential development equipment | p. 29 |
| Bench power supply unit | p. 29 |
| A thermostatically controlled oven | p. 30 |
| A calibrated, precision ammeter | p. 30 |
| The P-N Junction | p. 31 |
| Characteristics of the P-N junction | p. 31 |
| Using BJTs to Create Current Sources | p. 47 |
| Characteristics of the BJT | p. 49 |
| Using the BJT as a current source | p. 67 |
| Widlar current sources | p. 74 |
| Wilson current mirrors | p. 81 |
| Wyatt current source | p. 87 |
| Multiple current mirrors | p. 89 |
| Cascode current mirrors | p. 91 |
| Current scaling | p. 95 |
| Modified current sources and example applications | p. 102 |
| Running the current source from split power supplies | p. 102 |
| Improving power supply rejection | p. 103 |
| Alternative current divider | p. 104 |
| Modified three-transisitor mirror-source | p. 104 |
| Current source linearly charges capacitor in VCO | p. 105 |
| Current source in a high-frequency laser transmitter | p. 107 |
| Temperature-compensated current sink | p. 108 |
| Compound current mirrors | p. 109 |
| Current mirrors help DACs control oscillator frequency and duty cycle | p. 110 |
| Using current sources as active loads | p. 111 |
| Modified current source squares the reference current | p. 113 |
| Digitally controlled variable current source | p. 116 |
| High-pass filter's response is set by compound current mirrors | p. 116 |
| Simple LED current sources | p. 118 |
| A low-noise AC amplifier biased by an LED current source | p. 120 |
| A composite BJT-JFET current source with very high output impedance | p. 121 |
| A composite BJT-MOSFET high-power current source | p. 121 |
| A DAC-controlled current pump uses a Wilson current source | p. 122 |
| Using Precision Matched-Pairs, Duals, and Quads | p. 125 |
| Precision BJT matched-pairs | p. 125 |
| Quality dual transistors | p. 129 |
| General-purpose BJT duals and quads | p. 133 |
| Using JFETs and CRDs to Create Current Sources | p. 137 |
| The JFET paved the way | p. 137 |
| Characteristics of the JFET | p. 140 |
| Using the JFET as a current source | p. 151 |
| The JFET cascode current source | p. 163 |
| JFET current regulator diodes | p. 166 |
| Characteristics of the CRD | p. 168 |
| A design guide | p. 175 |
| An overview of various popular CRD families | p. 175 |
| Using JFETs to create ultra-low-leakage diodes | p. 180 |
| Creating Medium-Power Current Sources with DMOS FETs | p. 185 |
| Depletion-mode DMOS FETs | p. 186 |
| The importance of silicon-gate | p. 188 |
| Characteristics of depletion-mode DMOS FETs | p. 190 |
| Depletion-mode DMOS current sources | p. 195 |
| The cascode DMOS current source | p. 197 |
| The JFET-DMOS cascode current source | p. 199 |
| Lateral depletion-mode DMOS FETs | p. 200 |
| Creating Current Sources with Power MOSFETs | p. 203 |
| Characteristics of enhancement-mode MOSFETs | p. 204 |
| Using the enhancement-mode MOSFET as a current source | p. 218 |
| Using "smart" power MOSFETS | p. 228 |
| IXYS power MOS current sources | p. 229 |
| Lateral enhancement-mode MOSFETs | p. 230 |
| Using Analog CMOS Arrays to Create Current Sources | p. 231 |
| RCA pioneered CMOS | p. 231 |
| Characteristics of CMOS FETs | p. 235 |
| Using CMOS linear arrays to create current sources | p. 241 |
| CMOS cascode current sources | p. 245 |
| Using ALD's programmable EPADs to create precision current sources | p. 252 |
| ALD breaks the gate-threshold barrier | p. 253 |
| Using Monolithic IC Current Sources and Mirrors | p. 261 |
| National's LM134-a monolithic IC current source | p. 261 |
| Current source applications for the LM134 | p. 266 |
| Using the LM134 as a temperature sensor | p. 271 |
| TI/Burr-Brown's REF-200 monolithic current source | p. 273 |
| Creating Precision Current Sources with Op Amps and Voltage References | p. 281 |
| How op amps evolved | p. 281 |
| Some op amp characteristics | p. 286 |
| Op amp supply bypassing and input protection | p. 294 |
| Creating current sources with op amps | p. 296 |
| Creating precision current regulators with op amps | p. 311 |
| An Introduction to Voltage References | p. 319 |
| Introduction and history | p. 319 |
| Understanding voltage reference specifications | p. 324 |
| Initial accuracy (initial error) | p. 326 |
| Temperature drift (tempco, TC[subscript Vo]) | p. 326 |
| Long-term drift | p. 332 |
| Noise | p. 333 |
| Thermal hysteresis | p. 335 |
| Line regulation | p. 336 |
| Load regulation | p. 336 |
| Maximum output current rating (I[subscript OUT]; mA) | p. 336 |
| Supply voltage range | p. 336 |
| Supply current (I[subscript S]) or quiescent current (I[subscript Q]) | p. 337 |
| Dropout voltage | p. 338 |
| Turn-on settling time (t[subscript on]; [mu]S) | p. 338 |
| Turn-on drift (dV/T) | p. 338 |
| Transient response | p. 338 |
| Sleep/Enable | p. 338 |
| Power dissipation | p. 338 |
| Enhancing the voltage reference design | p. 339 |
| Input and output bypassing | p. 339 |
| Noise reduction | p. 341 |
| Trimming | p. 346 |
| Unused terminals on the package | p. 354 |
| Package types | p. 355 |
| PCB layout | p. 356 |
| Why not do it yourself? | p. 356 |
| Comparing precision | p. 359 |
| The zener Diode and the TC zener Reference | p. 363 |
| Introduction | p. 363 |
| Characteristics of the zener diode | p. 365 |
| Some simple zener applications | p. 382 |
| Temperature-compensated zeners | p. 393 |
| Characteristics of Monolithic Voltage References | p. 403 |
| Bandgap voltage references | p. 404 |
| Buried-zener voltage references | p. 415 |
| The XFET voltage reference | p. 421 |
| The Intersil/Xicor FGA voltage reference | p. 424 |
| Low-voltage considerations | p. 426 |
| Comparing the different topologies | p. 433 |
| A Review of Some Outstanding Monolithic Voltage References and Their Applications | p. 437 |
| Introduction | p. 437 |
| Applying the bandgap shunt reference | p. 438 |
| Analog Devices ADR510 | p. 441 |
| Analog Devices ADR520 | p. 442 |
| National Semiconductor LM4051-ADJ | p. 444 |
| Maxim MAX6138 | p. 446 |
| Maxim MAX6006 | p. 448 |
| Linear Technology LT1634 | p. 449 |
| Linear Technology LT1389 | p. 449 |
| Applying fixed-series bandgap references | p. 451 |
| Linear Technology LT1461 | p. 453 |
| National Semiconductor LM4140 | p. 455 |
| National Semiconductor LM4130 | p. 457 |
| Analog Devices ADR390 | p. 458 |
| Analog Devices ADR280 | p. 459 |
| Analog Devices AD780 | p. 461 |
| Maxim MAX6129 | p. 463 |
| Maxim MAX6126 | p. 465 |
| Applying adjustable-series bandgaps | p. 466 |
| Linear Technology LT6650 | p. 466 |
| Maxim MAX6325 | p. 469 |
| Maxim MAX6037-ADJ | p. 470 |
| Intersil/Xicor x60250 | p. 472 |
| Analog Devices ADR01 | p. 474 |
| Digital compensation | p. 476 |
| Using the Analog Devices' XFET reference | p. 478 |
| Analog Devices ADR431A | p. 479 |
| Applying buried-zener references | p. 483 |
| Analog Devices AD688 | p. 484 |
| Analog Devices AD586 | p. 486 |
| Texas Instruments REF102 | p. 488 |
| Linear Technology LT1021 | p. 490 |
| Linear Technology LTZ1000 | p. 491 |
| Applying the Intersil/Xicor FGA X60008 | p. 494 |
| Intersil/Xicor x60008 | p. 495 |
| Creating precision current source circuits | p. 498 |
| ISL60002 | p. 498 |
| ISL60007 | p. 498 |
| Multiple voltage references and multiple loads | p. 501 |
| Digitally selectable 5-reference calibrator | p. 502 |
| Same voltage to multiple loads | p. 503 |
| Monolithic voltage references-a look to the future | p. 506 |
| References and Tables | p. 513 |
| Power of 10 and Equivalents | p. 513 |
| Temperature scale conversion | p. 515 |
| Precision resistor comparisons | p. 515 |
| Gain vs. dB conversion Table | p. 516 |
| Reactance chart for filter design | p. 517 |
| Small signal model for the BJT | p. 518 |
| Simplified BJT models | p. 518 |
| BJT operating modes Table | p. 519 |
| JFET models | p. 519 |
| MOS transistor models | p. 520 |
| PPM to % converter | p. 521 |
| Allowable noise levels for n-bit systems | p. 521 |
| Different voltage reference configurations | p. 522 |
| Allowable tempco requirements | p. 523 |
| Glossary | p. 525 |
| Bibliography | p. 535 |
| Part I-Current Sources | p. 535 |
| Part II-Voltage References | p. 540 |
| Contact Information | p. 543 |
| Semiconductor Manufacturers | p. 543 |
| Electronics Distributors | p. 549 |
| Precision Passives Manufacturers | p. 550 |
| Instrumentation Manufacturers | p. 555 |
| Magazines & Periodicals | p. 557 |
| Index | p. 559 |
| Table of Contents provided by Ingram. All Rights Reserved. |
