INDEX SUBJECT INDEX ANALOG DEVICES PARTS INDEX BASIC LINEAR DESIGN INDEX SUBJECT INDEX A Aasnaes, Hans Bent, 6.84 AAVID Thermal Technologies, Inc. General Catalog, 12.96 Absolute accuracy, definition, 6.122-123 Absolute maximum ratings: data sheet, example, 6.189 op amp, 1.76-78 typical, table, 1.90 Absorption, shielding loss, 11.43-44 AC coupling, 1.23 AC current path, ground plane resistance, 12.72 ACCEL Technologies, Inc., 13.91, 13.92 Accelerometer, 3.15-18 basic unit cell sensor building block, 3.15 Coriolis, 3.20-21 internal signal conditioning, diagram, 3.16 low-g, tilt measurement, 3.16-17 Accuracy: absolute, definition, 6.122-123 logarithmic, definition, 6.123 relative, definition, 6.123 ACLR, see: Adjacent channel leakage ratio Acquisition time: definition, 6.173 SHA, 7.59 Active feedback amplifier, 2.49-51 CMR independent of resistor bridge, 2.49 Active feedback CMR/gain calculator, screen, 13.45 Active filter: antialiasing design, 8.121-127 element, limitations, 8.114-115 Active inductor, diagram, 8.69 Active mixer: advantages, 4.7 basic operation, 4.8-9 classic, circuit, 4.8 gain, 4.9 RF/IF circuit, 4.8-9 AD2S90, integrated RDC, 6.79 AD210: 3-port isolator, 2.34-36 in motor control current sensing, circuit, 2.35 schematic diagram, 2.35 AD215: low distortion two-port isolator, 2.36-37 block diagram, 2.37 AD260/AD261, high speed digital isolators, 2.40-42 AD526: monolithic software PGA in-amp: circuit, 2.89 latched digital interface, 2.90 AD534, four-quadrant multiplier based on Gilbert cell, 4.17 AD536A: monolithic rms/dc converter, 2.85-86 diagram, 2.86 AD538, monolithic analog computer, block diagram, 2.57 AD539: wideband dual two-quadrant multiplier, 2.77-78, 2.81, 4.13-14 block diagram, 2.78, 4.14 AD549, FET input op amp, 1.51 AD574, industry-standard ADC, encoder, 5.22 AD580, precision band gap reference, with Brokaw Cell, 7.4, 7.5 AD586, buried zener reference, circuit, 7.9 AD587, buried zener reference, noise reduction pin, 7.15 AD588, load cell amplifier, 3.96 diagram, 3.96 single supply load cell amplifier, 3.97 diagram, 3.97 AD589, strain gage sensor amplifier, 3.95 Diaram, 3.95 AD590: current output temperature sensor, 3.33 multiplexed, 3.33 AD594, Type J thermocouple, 3.43 AD594/AD595, monolithic thermocouple amplifier with cold-junction compensator, diagram, 3.42-43 AD595, Type K thermocouple, 3.43 AD598: LVDT signal conditioner, 3.3-4 diagram, 3.4 AD598 and AD698 data sheet, 3.27 AD600, gain vs. differential control voltage, 4.36 AD602, gain vs. differential control voltage, 4.36 AD620: In-amp, in-motor control current sensing, circuit, 2.35 CMR vs. frequency, graph, 2.24 gain-bandwidth pattern, 2.27 monolithic IC in-amp: composite application, 2.15-16 schematic, 2.13-14 PSRR vs. frequency, graphs, 2.25 Strain gage sensor amplifier, 3.95 Index 1 BASIC LINEAR DESIGN AD620B, bridge amplifier, dc error budget, 2.28 Load cell amplifier, 3.96 Diagram 3.96 AD621, pin-programmable-gain in-amp, 2.22 AD621B, load cell amplifier 3.96 diagram. 3.96 single cell load cell amplifier, 3.97 diagram, 3.97 AD623, fixed gain difference amplifier, 12.12-13 AD624C, monolithic in-amp, gain error, 2.22 AD629: difference amplifier, 12.12-13 differential-to-single-ended amplifier, application circuit, 2.9 AD641: monolithic log amp: block diagram, 4.25 error curve, 4.25 transfer function, 4.25 waveform effect on log linearity, 4.26 AD645, FET input op amp, 1.51 AD698: LVDT signal conditioner: with half-bridge, 3.4-5 synchronous demodulation, 3.3-5 diagram, 3.4 AD768, 16-bit BiCMOS precision DAC, 6.27 AD780, reference, 2.63 AD790: comparator with hysteresis, 2.68 block diagram, 2.69 AD797, low noise op amp, 2.90-91 AD811, CFB op amp, comparison with model, graphs, 13.13 AD817, video op amp driver, power dissipation vs. power, graph, 12.89 AD822, JFET-input dual rail-to-rail output op amp, 2.15-16 AD825, 8-bit, dual, high speed FET input op amp, 8.137-138, 8.141 AD830, active feedback amplifiers, 2.49 AD830/AD8129/AD8130, active feedback amplifiers, circuit, 2.49 AD831 data sheet, 4.10 AD834: 8-pin basic four-quadrant multiplier, block diagram, 4.19 multiplier, implicit conversion, circuit, 2.84 transformer coupled multiplier, block diagram, 4.19 AD847: high frequency amplifier: Bode plot, 8.120 Q-enhancement effects, 8.119 Op amp: convergence, circuit and graphs, 13.16 Index 2 open loop gain, graph, 1.12 parasitics, circuit and graphs, 13.15 AD848, op amp, open loop gain, graph, 1.12 AD849, op amp, open loop gain, graph, 1.12 AD1879, dual audio ADC, 6.98 AD813X, differential amplifier, 6.27-28 AD1170, modular ADC, 6.72 AD1580: shunt mode IC reference, 7.5-6 circuit, 7.6 AD1582-85 series: Band gap references: advantages, 7.7-8 circuit, 7.7 connection diagram, 7.7 LDO, 7.7 AD185X series, audio DACs, data scrambling, 6.109-110 AD1853, dual 24-bit, 92 kSPS DAC, 6.110 AD1871: 24-bit 96 kSPS stereo audio multibit sigma-delta ADC: block diagram, 6.99 digital filter characteristics, 6.100 second order modulator and data scrambler, 6.100 AD1955: multibit sigma-delta audio DAC diagram, 6.110 AD1900/AD1902/AD19004/AD1906: Class-D audio power amplifier,2.107-2.117 AD3300 60 mA LDO regulator, evaluation board, 9.18 AD3300, 60 mA LDO regulator, circuit, 9.16 AD5535, 32-channel, 14-bit, 200 V output DAC, evaluation board, 13.73 AD6645: 14-bit, 80 MSPS wideband ADC: noise figure calculation, 6.154 Nyquist conditions, 6.153 SFDR, graph, 6.139 SFDR vs. input power level, graph, 6.140 SNR performance, 6.160 SNR vs. aperture jitter, graph, 6.160 two-tone SFDR: graph, 6.142 vs. input amplitude, graph, 6.142 14-bit 80 MSPS/105 MSPS XFCB ADC, 6.182- 185, 6.188, 6.193-194, 6.202 52-lead Power Quad 4 package, 12.94 application circuit, 6.202 14-bit 105 MSPS ADC, with SHA, circuit, 7.62 encode command specifications, table, 6.178 sample timing specifications, table, 6.178 INDEX AD7111, LOGDAC, multiplying DAC, circuit, 6.38-39 AD7450, 12-bit, 1 MSPS ADC, evaluation board, 13.74 AD7524: CMOS DAC, block diagram, 6.14 quad CMOS DAC, block diagram, 6.14 AD7528, 8-bit dual MDAC, 8.137-138, 8.141 AD7677: 16-bit 1 MSPS switched capacitor PulSAR ADC, 6.48-49 circuit, 6.49 AD77XX series: 24-bit high sigma-delta ADC, 6.101, 6.103 high resolution ADC: in cold-junction compensation, 3.44 and RTD, 3.49-50 AD7710: sigma-delta ADC with PGA, 2.93-94 circuit, 2.94 AD7710-series, 22-bit ADC, 7.19 AD7711, sigma-delta ADC with PGA, 2.93 AD7712, sigma-delta ADC with PGA, 2.93 AD7713, sigma-delta ADC with PGA, 2.93 AD7730: 24-bit bridge transducer sigma-delta ADC, evaluation board, 13.72-73 application circuit, 6.202 direct conditioning of bridge circuit, 3.98 ratiometric AC or DC drive w. Kelvin sencing 3.85,3.96 sigma-delta ADC, 6.115 configuration assistant, 13.46-48 screen, 13.47 digital filter response, graph, 6.101 single-supply bridge: block diagram, 6.103 bridge application, schematic, 6.107 digital filter response, graph, 6.105 digital filter settling time, 6.106 oversampling, 6.104 resolution vs. output data and gain, 6.104 AD7846, 16-bit converter, 2.91-92 AD7943/AD7945/AD7948: 2-quadrant multiplying DAC, schematic diagram, 6.19 4-quadrant multiplying DAC, schematic diagram, 6.19 AD8001: absolute maximum ratings, table, 1.76 feedback resistor values, packages, chart, 1.68 high speed current feedback amplifier, 12.31-32 evaluation board, 12.32 high speed current-feedback amplifier: evaluation board, 13.70-71 stray capacitance, pulse response, 12.32 maximum power chart, 1.77 op amp: optimum feedback resistor vs. package, table, 1.18 packages, recommended components, 13.89 AD8016: 20-lead PSOP3 package, copper slug for heat transfer, 12.88 PSOP3 and BATWING packages, thermal characteristic curves, 12.87 AD8017AR: 8-pin SOIC op amp, 12.83-86 maximum power dissipation data sheet, 12.83 standard and Thermal Coastline packages, thermal rating curves, 12.86 thermal rating curves, 12.86 AD8029, PSRR, 12.77 AD8036, and output clamp amplifier, graph, 2.61 AD8036/AD8037: clamp amplifier: distortion near clamping region, graph, 2.62 equivalent circuit, 2.59 overdrive recovery, graph, 2.62 performance, 2.60 AD8037, clamp amplifier, driving flash converter, circuit, 2.62-63 AD8051, op amp, phase margin, graph, 1.13 AD8051/AD8052/AD8054, high speed VFB op amp, 1.83, 1.86 AD8054, phase margin, graph, 1.70 AD8055, single supply op amp, 6.26 AD8057, single op amp, thermal packaging, 12.90 AD8058, dual op amp, thermal packaging, 12.90 AD8074, triple voltage feedback fixed-gain video transmission line driver, 2.4 AD8074/AD8075, 500 MHz triple buffer, 2.3 AD8075: triple video buffer, 1.66 triple voltage feedback fixed-gain video transmission line driver, 2.4 AD8079A/AD8079B: 260 MHz buffer, 2.4 dual voltage feedback fixed-gain video transmission line driver, 2.4 AD8108/AD9109, video 8 × 8 crosspoint switch, 7.45 AD8110/AD8111, 260 MHz, 16 × 8 buffered crosspoint switch, 7.45 Index 3 BASIC LINEAR DESIGN AD8113, audio/video 60 MHz, 16 × 16 crosspoint switch, 7.45 AD8114/AD8115, 225 MHz, 16 × 16 crosspoint switch, 7.45 AD8116, 16 × 16, 200-MHz buffered video crosspoint switch, circuit, 7.45 AD8129, low noise, high gain active feedback amplifier, 2.50-51 AD8129/AD8130: active feedback amplifiers, 2.49-51 differential input single-ended output gain block, 2.5 AD813X: differential ADC driver, block diagram and equivalent circuit, 2.31 differential amplifier, DAC buffer circuit, 2.32 AD8130, CMR vs. frequency, graph, 2.50 AD8152, 3.2 Gbps, 34 × 34 asynchronous digital crosspoint switch, circuit, 7.46 AD8170: bipolar video multiplexer, block diagram, 7.42 dual source RGB multiplexer, using three 2:1 muxes, circuit, 7.43 AD8174: 4:1 mux, 7.44 bipolar video multiplexer, block diagram, 7.42 AD8180, bipolar video multiplexer, block diagram, 7.42 AD8182, bipolar video multiplexer, block diagram, 7.42 AD8183/AD8185, video multiplexer, block diagram, 7.43 AD8183/AD8185/AD8186/AD8187, triple 2:1 mux, 7.43 AD8184, 4:1 mux, 7.44 AD8186/AD8187, video multiplexer, singlesupply, block diagram, 7.43 AD8230, auto-zeroing in-amp with high CMR, 3.45-46 AD8330, VGA, block diagram, 4.34 AD8345, silicon FRIC quadrature modulator, block diagram, 4.11 AD8350, differential in/differential out gain block, 2.6 AD8354, gain block fixed-gain amplifier, circuit, 2.5 AD8362: true rms-responding power detector: block diagram, 4.29 internal structure, 4.30 typical application, 4.31 AD8367: high performance 45dB VGA: block diagram, 4.38 linear-in-dB gain, 4.37 Index 4 AD8370: VGA with precision gain control, 4.38-39 block diagram, 4.39 AD8531/32/34: ordering guide for packaging, 1.92 single-supply op amp, 1.83, 1.92 AD8551: chopper-stabilized amplifier, 12.11 in grounded circuit, 12.12 AD8551/AD8552/AD8554: auto-zero amplifiers: noise comparison, 2.123 output spectrum, graphs, 2.122 AD8571/AD8572/AD8574, auto-zero amplifiers, output voltage, graphs, 2.122 AD9002, 8-bit, 125 MSPS flash converter, 2.62-63 AD9042: 12-bit, 41 MSPS ADC, 7.60-61 with SHA, circuit, 7.61 AD9054A, 8-bit, 200 MSPS ADC, functional diagram, 6.63 AD9226, 12-bit, 65 MSPS ADC, SINAD and ENOB, graph, 6.136-137 AD9235: 12-bit, 65 MSPS pipelined ADC, 6.55 timing, graph, 6.55 AD9245: 14-bit 80 MSPS 3V CMOS ADC: lead-frame chip-scale package, 12.92 power dissipation vs. sample rate, graph, 12.91 AD9410, 10-bit, 210 MSPS ADC, 6.51 AD9430: 12-bit, 170 MSPS ADC, noise/power ratio, graph, 6.148 12-bit, 170 MSPS/210 MSPS 3.3V BiCMOS ADC, 12.92-93 100-lead 3-PAD TQFP, 12.93 output driver, 12.49 packaging, 12.93 supply current vs. sample rate, graph, 12.93 12-bit, 210 MSPS pipelined ADC, 6.55 AD9510: Clock distribution circuit 7.73-83 AD9514 Clock generation circuit 7.67-72 AD9620, monolithic open-loop buffer, 2.3 AD9630, monolithic open-loop buffer, 2.3 AD9631, op amp, inadequate decoupling effects, 12.79 AD976X, TxDAC, 6.24 AD977X, TxDAC, 6.24 AD9772, TxDAC, DAC harmonic images calculator, screen, 13.51 AD9773, 12-bit Transmit DAC (TxDAC), 6.34 INDEX AD9775: 14-bit 160 MSPS TxDAC, 6.34 14-bit 160 MSPS/400 MSPS TxDAC, core, diagram, 6.21-22 AD9777: 16-bit, 160 MSPS dual interpolating DAC, 12.94 16-bit, 160 MSPS transmit DAC (TxDAC), 6.34 SFDR, graph, 6.171 AD985X series, DDS ICs, 12.94 AD9850: DDS, 13.48-50 register configuration assistant, screen, 13.49 DDS/DAC synthesizer, 4.46-47 diagram, 4.46 AD9870, IF digitizing subsystem, 6.109 AD22100, temperature sensor, ratiometric, 3.34 AD22105, thermostatic switch, 3.58-59 AD22151: linear output magnetic field sensor: diagram, 3.8 using Hall technology, 3.7-8 AD22151 data sheet, 3.27 Adams, R., 6.113 Adams, Robert, 2.127, 6.113 Adams, Robert W., 6.113 Adams, R.W., 6.113 ADC: 1-bit, comparator, 6.44 3-bit binary ripple, input and residue waveforms, graph, 6.60 3-bit serial, binary output, diagram, 6.59 5-bit counting, circuit, 6.64 10-/11-/12-bit ADC, theoretical noise power ratio, graphs, 6.147 12-bit: noise floor, graph, 6.130 SFDR, ratio of sampling clock to input frequency, graphs, 6.129 analog bandwidth, 6.137-138 antialiasing suppression assistant, screen, 13.53 architectures, 6.40-84 basic function, diagram, 6.40 binary, single-state transfer function, graphs, 6.58 bit error rate, 6.163-166 buffering, logic noise, 12.29-30 charge run-down, 6.65 converter analog bandwidth, graph, 13.22 converter performance vs. analog input frequency, graph, 13.22 converter performance vs. sample rate, graph, 13.21 ADC (cont) counting and integrating architectures, 6.64 digital output, handling, 12.62-64 DNL, typical, graph, 13.20 dual slope/multislope, 6.73-75 dynamic performance analysis, diagram, 6.129 error corrected, 6.52-57 gain and ENOB vs. frequency, graph, 6.138 generalized bit-per-stage architecture, diagram, 6.58 Gray coded (folding), 6.58-63 high resolution, with VFC and frequency counter, 6.68 high speed: CMOS buffer/latch, diagram, 12.30 logic noise, 12.29-30 high impedance, differential input, 12.14 input and output definitions, 5.1 input structures, typical, diagrams, 13.20 internal reference, 6.40-41 metastable states, 6.163-166 model, showing noise and distortion sources, 6.131 multibit and 1-bit pipelined core combination, diagram, 6.57 no specification of IMD, 6.145 noise figure, calculation, 6.149 output, with error codes, graph, 6.164 overvoltage, 11.1 pipelined, 6.52-57 ramp run-up, 6.65-66 reference and buffer, diagram, 6.41 sampling: containing SHA, 7.51 using integral SHA, 6.161 sampling clock, 6.42 SAR, 6.42, 6.45-47 selection guide, samples, 6.209-211 serial bit-per-stage binary, 6.58-63 SFDR specification, 6.138 sparkle codes, 6.163-166 subranging, 6.52-57 trimming error, graphs, 6.121 successive approximation, 6.37 supply voltage, 6.43 total SNR, equation, 6.160-161 tracking, 6.66-67 transfer function, graph, 13.23 transient response and overvoltage recovery, 6.161-163 ADC Analyzer, 13.74-75 ADC FIFO Evaluation Kit: functional block diagram, 13.76 illustration, 13.77 ADF439F, trench-isolated LLCMOS multiplexer, 7.50 Index 5 BASIC LINEAR DESIGN ADF4112, PLL, 4.67 ADG200 series, CMOS switches/multiplexers, 7.23 ADG201 series, linear-compatible CMOS switches/multiplexers, 7.23 ADG438F, trench-isolated LLCMOS multiplexer, 7.50 ADG508F, trench-isolated LLCMOS multiplexer, 7.50 ADG509F, trench-isolated LLCMOS multiplexer, 7.50 ADG511, single-supply switch, 2.92-93 ADG528F, trench-isolated LLCMOS multiplexer, 7.50 ADG708: 8-channel multiplexer: crosstalk vs. frequency, graph, 7.33 off-isolation vs. frequency, graph, 7.30 ADG8XX-series, CMOS switch, 7.26 ADG801/ADG802, CMOS switch, in-resistance vs. input signal, graph, 7.26 ADG918, 1GHz CMOS MUX/SPDT absorptive switch, circuit, 7.40-41 ADG918/ADG919, 1GHz switch, isolation and frequency response, graphs, 7.40 ADG919, 1GHz CMOS MUX/SPDT reflective switch, circuit, 7.40 ADIsimADC: data converter modeling, 13.18-25 behavioral model, 13.18 distortion, 13.22-23 gain, offset, and dc linearity, 13.19-20 hardware considerations, 13.18-19 jitter, 13.24-25 latency, 13.25 sample rate and bandwidth, 13.21 ADIsimPLL, 13.26-29 advantages, 13.26 frequency domain results, 13.30 graphs, 13.28 and phase noise, 13.26 schematic output, circuit, 13.29 software, version 2.5, enhancements, 13.27 time domain results, 13.29 graphs, 13.28 Adjacent channel/leakage ratio, definition, 6.145 Adjacent channel/power ratio, definition, 6.145 ADLH0033, bipolar open-loop hybrid buffer amplifier, circuit, 2.1 ADM1201: microprocessor temperature monitor, 3.6163 block diagram, 3.63 input signal conditioning circuits, diagram, 3.62 ADP1147, switch modulation, 9.47 Index 6 ADP1148, buck PWM regulator with variable frequency, 9.62 ADP3000: switching regulator, 9.48 switching regulator IC using PBM, 9.52 ADP330X, LDO anyCAP regulator, schematic, 9.13 ADP3300 series, LDO pre-regulators, 7.15 ADP3310: PMOS FET 1A LDO regulator controller: diagram, 9.21 external current sense resistor, 9.23-25 ADP3603/ADP3604/ADP3605, regulated –3V output voltage inverters, application circuit, 9.93 ADP3603/ADP3604/ADP3605/ADP3607: regulated −3V output voltage inverters, 9.91-93 circuit, 9.92 ADP3607, regulated −3V output voltage inverter, resistor value, 9.93 ADP3607-5: regulated 5 V output voltage inverter: circuit, 9.95 voltages, 9.94 ADR380, 7.7 ADR381, 7.7 ADSP-21060L SHARC, output rise times and fall times, graph, 12.43 ADSP-21160 SHARC, internal PLL, grounding, 12.69-70 ADSpice macromodel: characteristics, 13.4-5 model transient response, 13.9-10 op amp, 13.5 CFB, 13.5, 13.11-13 input and gain stages, circuit, 13.12 frequency shaping stages, 13.7-8 noise model, 13.10-11 output stages, 13.8-9 circuit, 13.8 pulse response comparisons, graphs, 13.9 stages, circuits, 13.7 VFB, 13.5 input and gain/pole stage, circuits, 13.6 support, 13.17 ADT45/ADT0, sensor, packaging, 3.34 ADT70: RTD signal conditioner, 3.49-51 diagram, 3.50 ADT71, RTD signal conditioner, packaging, 3.51 ADuM130X/ADuM140X: multichannel isolator, 2.46-48 multichannel products, 2.46-48 ADuM140X, die photograph, 2.47 INDEX ADuM1100: architecture, single-channel digital isolator, 2.42-46 single-channel 100 Mbps digital isolator, 2.42-46 cross-section, 2.43 magnetic field immunity, 2.45 performance, 2.44 ADuM1400, block diagram, 2.48 ADuM1401, block diagram, 2.48 ADuM1402, block diagram, 2.48 ADXL-family micromachined accelerometer, diagram, 3.15 ADXL202, dual-axis ±2g accelerometer, diagram, 3.17-18 ADXRS gyro, 3.19-26 capacitance change resolution, 3.23-24 die, photograph, 3.25 mechanical sensor, 3.24 shock and vibration resistance, 3.26 ADXRS150, packaging, 3.25 ADXRS300, packaging, 3.25 Akazawa, Yukio, 6.81 Alexander, Mark, 13.31, 13.91, 13.92 Alias, image, 5.25 Aliasing: in DDS system, RF/IF circuit, 4.45-46 in time domain, 5.25 All bits off, definition, 6.125 All bits on, definition, 6.125 All-0s, definition, 6.125 All-1s, definition, 6.125 All-digital PLL, 4.52 All-parallel (flash) converter, diagram, 6.50 All-pole filter, response, comparisons, 8.25 Allen, P.E., 8.143 Allpass filter, 8.13 definition, 8.12 delay, 8.61 purpose, 8.12 Alternate loading DAC, 6.29-30, 6.30 Aluminum electrolytic capacitor, 9.72-73 characteristics, 10.4-5, 10.5 comparison chart, 8.113 Ammann, Stephan K., 6.84 AMP 5-330808-3, 13.87 pin socket, 12.58 AMP 5-330808-6, 13.87 pin socket, 12.58 AMP03, precision four-resistor differential amplifier, 12.12-13 Amplifier: band limited, 8.114 current-voltage characteristic, 11.3 intercept points and 1 dB compression points, definition, 6.143 programmable gain, 2.87-94 Amplifiers (cont,) speed, saturation, graph, 2.72 Amplifier Applications Guide, 2.114, 2.115, 4.28, 11.50 Amplifier input stage overvoltage, 11.1-4 Amplifier output phase reversal, caveats, 11.4 Amplifier output voltage phase reversal, 11.4-9 Amplitude, EMI, 11.28 Amplitude modulation, in DDS system, RF/IF circuit, 4.47 AN-309: Build Fast VCAs and VCFs with Analog Multipliers, 4.20 Analog bandwidth, ADC, 6.137-138 Analog comparator, overvoltage, 11.1 Analog computing circuitry, 5.2 Analog delay circuit, using SHA, 7.51 Analog Devices commitment to ESD protection, 11.20-21 Analog Devices Precision Converter: communications, 13.80 evaluation board, 13.79 hardware description, 13.80 output connector, 13.80 power supplies, 13.80 software, 13.81 Analog filter, 8.1-144 design examples, 8.121-142 filter realization, 8.63-108 frequency transformation, 8.55-62 practical problems, 8.109-120 standard responses, 8.21-54 time domain response, 8.18-20 transfer function, 8.5-17 Analog filter wizard, 13.61-67 operation modes, 13.61 schematic page, 13.67 screens, 13.62-63, 13.65-66 Analog ground, 12.55 in mixed-signal IC, 12.60-61 Analog ground pin, circuit, 12.56 Analog input variable, 5.1-2 Analog integrated circuit, overvoltage effects, 11.1-51 Analog isolation: high speed logic isolator, 2.40-42 isolation barrier, 2.33 optional noise reduction filter, 2.36 techniques, 2.33-34 two-port isolator, 2.36-37 Analog multiplexer, 7.23-50 Analog multiplier, 2.77-82 bipolar output, 4.13 block diagram, 4.13 definition, 2.77 four-quadrant, 4.13 RF/IF circuit, 4.13-20 single-quadrant, 4.13 Analog multiplier (cont.) two-quadrant, 4.13 Index 7 BASIC LINEAR DESIGN Analog switch, 7.23-50 application, 7.35-40 dummy switch in feedback, minimizing gain error, circuit, 7.38 ideal, 7.24 minimizing on resistance, 7.36 using large resistor values, circuit, 7.37 using noninverting configuration, circuit, 7.38 overvoltage, 11.1 parasitic capacitance, 7.37 switching time, dynamic performance, circuit, 7.35 unity gain inverter with switched input, circuit, 7.36 Analog-to-digital converter, see: ADC Anderson, Robin N., 6.84 Andreas, D., 6.113 ANSI/EIA-656, 13.31 Antialiasing filter: design example, 8.121-127 for undersampling, 5.30 anyCAP LDO family, 9.13-15 merged amplifier-reference design, 9.13 pole-splitting topology, 9.15-16 regulator controller, diagram, 9.20 standard lead frame SOIC, 9.19 Thermal Coastline packaging, 9.18 Thermal Coastline SOIC, 9.19 Aperture: SHA, effects on output, graph, 7.57 SHA specification, 7.54 Aperture delay, 6.156-157 SHA specification, 7.56 Aperture delay time, 6.156-159 SHA specification, 7.56 measurement, 7.56 Aperture jitter, 6.156-159, 12.64 error, 7.53 and sampling clock jitter: graph, 6.158 SNR, graph, 6.159 SHA, 7.56 Aperture time, 6.156-159 SHA specification, 7.54 Aperture uncertainty, 6.157 SHA, 7.56 Application circuit, data sheet, example, 6.202 Application specific integrated circuit, 4.2 The ARRL Handbook for Radio Amateurs, 4.73 Ask the Application Engineer-33: All About Direct Digital Synthesis, 4.50 Ask the Applications Engineer, 4.28 Aspinall, D., 6.82, 7.63 Asymptotic response, 1.16 Asynchronous VFC, 6.68 Attenuation curve, filter, 8.7 Index 8 Audio amplifier, 2.95-105, 2.95-98 auto-zero, vs. chopper, 2.121-110 implementation, 2.11 line drivers and receivers, 2.101 operation description, 2.124-113 types, 2.95-97 VCAs, 2.98-100 Audio line driver, 2.103-105 Audio line receiver, 2.101-103 definition, 2.101 Audio system, differential/balanced transmission, block diagram, 2.101 Auto-zero amplifier, 2.119-113 auto-zero phase, circuit, 2.124 implementation, 2.123 output phase, circuit, 2.124 schematic diagram, 2.120 vs. chopper amplifier, 2.121 Automatic zero, definition, 6.173 Automotive equipment: components, RF field immunity limits, 11.25 EMC, 11.25 Avalanche diode, circuit, 7.2-3 AVX Corporation, 9.79 AVX TPS-series, electrolytic capacitor, 9.75 B Bainter notch filter: design equations, 8.102 diagram, 8.82 prototype, 8.132 Bainter, J.R., 8.144 Baker, Bonnie, 12.51, 12.82 Balanced audio transmission system, circuit, 2.104 Ball grid array, PCB, 12.6 Ball, W.W. Rouse, 6.81 Band gap reference, 7.3-8 architecture, table, 7.11 basic, circuit, 7.4 Band gap temperature sensor: cell reference voltage, 3.33 diagram, 3.32 Band-pass filter, 5.30, 8.2, 8.13 bandwidth, 8.9-10 definition, 8.10 delay curve, denormalization, 8.29 peaking vs. Q, 8.10 pole frequencies, 8.57 response, graph, 8.131 response envelope, 8.29 transformations, 8.29 transfer function, 8.9-10 wideband or narrowband, 8.56 Band-pass sampling, 5.28 Band-pass sigma-delta converter, 6.108-109 replacing integrators with resonators, diagram, 6.108 INDEX Band-pass transformation, circuit, 8.131 Bandreject filter, 8.2, 8.13 definition, 8.10-12 response, graph, 8.133 transfer function, 8.11 transformation, circuit, 8.131-132 Bandwidth: for 0.1dB flatness, 1.66-67 SHA, 7.54 Barber, William L., 2.115, 4.28 Barney, K. Howard, 6.83 Barrow, Jeff, 12.51, 12.75 Base-10 code, and binary, 5.3 Baseband, sampling, 5.26 Baseband antialiasing filter, 5.26-28 oversampling, 5.27 Basic diode log amp, 2.56 BAV199, diode, 3.46 Bell Laboratories, 6.37 Benjamin, O.J., 6.113 Bennett, W.R., 6.175 Bernardi, Scott, 1.79 Bessel filter, 8.3 amplitude response, 8.25 design prototype, 8.134 design table, 8.48 impulse response, 8.18-19 poles, 8.23 response curves, 8.37 standard response, 8.23 step and impulse response, 8.25 Bessel function, 8.134 Best straight line, 6.117-118 for integral linearity error, 5.14-15 Best, R.E., 4.73 Best, R.L., 4.73 Bi-FET, in op amp, 1.26 Bias current, 1.38 compensation, SHA, 1.40 error, 6.74 minimizing, 1.41-42 Bias-compensated input structure, circuit, 1.39 Bias-compensated op amp, 1.43 BiFET op amp: input behavior, 2.75 phase reversal, 11.4-5 Billings, Keith, 9.78 Binary code, 5.12 and base-10, 5.3 and hexadecimal, relationship, 5.3 Binary R-2R DAC, 6.6 Binary-coded-decimal code, table, 5.9-10 Binary-weighted capacitive DAC, in successive approximation ADC, diagram, 6.13 Binary-weighted current mode DAC, diagram, 6.13 Binary-weighted current source, 6.12-14 Binary-weighted voltage mode resistor DAC, diagram, 6.12 Bipolar 3-bit ADC, transfer function, 5.8 Bipolar 3-bit DAC, transfer function, 5.7 Bipolar code, 5.6-10 4-bit converter, 5.6 conversions among other codes, table, 5.9 offset binary, 5.6 ones complement, 5.6 sign magnitude, 5.6 twos complement, 5.6 Bipolar converter, 5.12-13 Bipolar junction transistor, 3.31 bias current, 1.38 Bipolar output, two-quadrant operation, 2.77 Bipolar power supply, op amp, 1.7 Bipolar process, for switches/multiplexers, 7.23 Bipolar switch, in voltage converter, 9.87 Bipolar-FET transistor, in op amp, 1.26 Biquadratic filter, 8.79 diagram, 8.79 tunable, 8.79 Biquadratic filter (A), highpass, design equations, 8.98 Biquadratic filter (B), notch and allpass, design equations, 8.99 Bird’s nest breadboard wiring, 13.83 Bit error rate: ADC, 6.163-166 vs. average time between errors, sampling, table, 6.166 Black, H.S., 6.175 Blattner, Rob, 9.26 Bleaney, B., 12.51, 12.75 Bleaney, B.I., 12.51, 12.75 Blinchikoff, H.J., 8.143 Boctor notch filter, 8.83-84 High-pass, diagram, 8.84 High-pass (A), design equations, 8.104 High-pass (B), design equations, 8.105 Low-pass: design equations, 8.103 diagram, 8.83 Boctor, S.A., 8.144 Bode plot, 1.9, 1.14, 1.16, 1.30, 1.31, 7.29, 8.120, 13.35 Bode, Hendrick W., 1.79 Boltzmann's constant, 1.55, 2.79, 3.31, 4.15, 4.62 Bonadio, Steven, 4.40 Bondzeit, Frederick, 6.84 Boost converter, 9.36-41 basic: circuit, 9.37 waveforms, 9.37 constant frequency PWM, graph, 9.64 discontinuous inductor current, 9.38-39 discontinuous mode, waveform, 9.39 Index 9 BASIC LINEAR DESIGN Boost converter (cont.) gated oscillator (PBM), inductance calculation, graph, 9.60 input/output capacitors, RMS ripple current, graphs, 9.75 input/output current, waveforms, 9.70 input/output relationship, 9.38 negative in/negative out, circuit, 9.41 NPN switches in IC regulator, circuit, 9.54 point of discontinuous operation, 9.40 See also: Step-up converter Borlase, Walter, 1.79 Boser, B., 6.113 Bowers, Derek, 13.31, 13.91, 13.92 Bowers, Derek F., 2.114 Boyle model, 13.8-9 Boyle, G.R., 13.31, 13.91 Brahm, C.B., 6.112 Brandon, David, 4.50 Brannon, Brad, 6.175, 7.84, 13.31 Breadboarding, 13.3 and simulation, 13.13 Bridge circuit: 1-element, 3.71-72 2-element, 3.71-72 AC excitation, 3.85 All-element, 3.71-73 Current drive, 3.73, 3.79, 3.82 Driving, 3.90-83 Kelvin sensing, 3.82 Linearizing, 3.76-79 Ratiometric operation, 3.77 Thermocouple effect, 3.84 Voltage drive, 3.76 Bridge output, 5.2 Broadband Amplifier Applications, 2.115, 4.28 Brokaw band gap cell, 7.6 Brokaw Cell, 3.32, 7.4 Brokaw, Paul, 3.64, 7.21, 9.26, 11.50, 12.51, 12.75, 12.82 Brown, Edmund R., 2.115, 4.28 Brown, Marty, 9.78 Brushless resolver, 6.76 Bryant, James, 12.51, 12.75 Bryant, James M., 2.114, 4.10, 6.84 Buck converter: basic: diagram, 9.31 waveforms, 9.32 constant frequency (PWM), inductance calculation, graph, 9.61 constant off-time variable frequency PWM, graph, 9.63 fixed off-time variable frequency pulse width modulation, 9.47 gated oscillator (PBM), inductance calculation, graph, 9.59 Index 10 Buck converter (cont) input/output capacitors, rms ripple current, graphs, 9.75 input/output current, waveforms, 9.70 input/output relationships, 9.33 negative in/negative out, circuit, 9.41 NPN switches in IC regulator, circuit, 9.54 point of discontinuous operation, 9.36 synchronous switch, with P- and Nchannel MOSFETS, circuit, 9.57 waveforms, discontinuous mode, 9.34 see also: Step-down converter Buck regulator, gated oscillator control, output voltage waveform, 9.53 Buck-boost converter: cascaded, 9.43 circuits, 9.42-43 flyback, circuit, 9.45 topologies, 9.42-43 Bucklen, Willard K., 6.81 Budak, Aram, 8.143 BUF03, monolithic open-loop buffer, circuit, 2.2 BUF04, unity gain buffer, 2.3 Buffer: definition, 2.1 frequency compensated, circuit, 2.3 simple unity-gain monolithic, circuit, 2.3 Buffer amplifier, 2.1-4, 6.6 Buffer register, 12.62 Buffered Kelvin-Varley divider, 6.6 Bulk metal resistor, table, 10.21 Bulk metal/metal foil resistor, comparison chart, 8.112 Buried zener, drift, 7.13 Buried zener reference, 7.8-9 architecture, table, 7.11 noise performance, 7.8-9 Burton, L.T., 8.144 Busy, 6.42 Butterworth filter, 5.27, 8.3, 8.23-24, 6.172, 13.65 amplitude response, 8.25 design table, 8.42 disadvantages, 8.128 impulse response, 8.18 noise bandwidth, 6.150 order, 8.109 response, 8.121-122 response curves, 8.31 standard response, 8.21 step and impulse response, 8.25 Buxton, Joe, 13.31, 13.91, 13.92 Bypass capacitor, voltage reference, 7.17, 7.19 C Cable: electrically long, 11.34 EMI, 11.29 radiation, and EMI, 11.27 INDEX Cable (cont) shielded, as antenna, 11.33-35 shielding, 11.47-49 electrical length, 11.46-47 and precision sensors, 11.49 CAD files, 12.4 CAD layout files, 13.72 Cage jack, 12.58, 13.87 Calculator, not a simulator, 13.48 Candy, J.C., 6.112, 6.113 Capacitance: parallel plates, 12.27 stray, 12.27-28 symmetric stripline, calculation, 12.41 Capacitive binary-weighted DAC, in successive approximation ADC, diagram, 6.13 Capacitive coupling: DAC, 6.168 equivalent circuit model, 12.28 Capacitive load: large, stable reference, circuit and graph, 7.18 reduces phase margin, 1.70 Capacitive noise, 12.28-29 Capacitive reactance, definition, 10.3 Capacitive sensing, 3.23-25 Capacitively-coupled isolation amplifier, 2.33 Capacitor, 10.3-14 basics, 10.3 characteristics, 8.110 table, 10.5 charge redistribution, 9.85 charge transfer, 9.83-87 charging from voltage source, diagrams, 9.84 comparison, table, 8.113, 10.5 considerations, 9.69-75 damping components, 10.4, 10.6 for decoupling, 12.77 definition, 10.3 dielectric absorption, 7.58, 10.11-13 dielectric types, 10.3-9 dissipation factor, 10.13 electrolytic: characteristics, 10.4-5 impedance vs. frequency, graph, 9.71 equivalent circuit: diagrams, 8.111 parasitics, 10.10 equivalent series inductance, 9.83 equivalent series resistance, 9.83 fundamentals, 9.28-30 graph, 9.29 insulation resistance, 10.10 manufacturers, 9.79 maximum working temperature, 10.9 organic types, advantages, 10.9 Capacitor (cont) parasitics, 8.111, 10.10, 10.13-14 best types, 10.13 and dissipation, 10.13-14 passive filter component, problems, 8.109-113 response to current step, 9.71 selection guide, chart, 9.72 stored charge, diagram, 9.83 temperature coefficient, 10.9 tolerance, temperature, and other effects, 10.9 voltage coefficient, 10.9 Carbon composition resistor, 10.15 comparison chart, 8.112 table, 10.21 Carrier, 6.136 Cascaded network, two-stage, example, 6.155 Cattermole, K.W., 5.20, 6.175 Cauer filter, definition, 8.26-27 Cauer, W., 8.143 Caveney, R.D., 6.82 CCD, 3.65-68 applications, 3.65 linear array, diagram, 3.65 noise source, 3.66 output waveform, 3.66 pixels, 3.65 sample-to-sample variation, 3.66 CD reconstruction filter: design, 8.134-136 final filter design, 8.135 normalized FDNR, 8.135 passive prototype, 8.135 performance, graphs, 8.136 transformation in S-plane, 8.135 CDMA, measurement, Tru-Power detector, 4.29 Centripetal motion, 3.21 Ceramic capacitor, 9.72, 9.74 CFB: advantages, 1.19 frequency response, graph, 1.18 CFB op amp, 1.17 common-mode input impedance, specification, 1.42-43 current noise, 1.49 difference from VFB, 1.17-19 frequency dependence, 1.68-69 noise model, 1.59 open-loop: gain, 1.68 graph, 1.32 transresistance, 1.32 Chadwick, P.E., 2.114, 4.10 Channel separation, op amp, 1.75 Channel-to-channel isolation, definition, 6.173 Charge control, 9.51 Charge injection, CMOS switch, 7.31 Index 11 BASIC LINEAR DESIGN Charge pump: continuous switching, circuit, 9.85 leakage current, 4.70-71 in PLL, 4.52 Charge run-down ADC, 6.65 diagram, 6.65 Charge transfer, definition, 6.173 Charge-balance VFC, 6.68 diagram, 6.69 Charge-coupled device, see: CCD Charge-redistribution DAC, 6.47 Charged device model, ESD, 11.12-13 Charpentier, A., 6.113 Chasek, N.E., 6.82 Chebyshev filter, 13.61 0.01dB: design table, 8.43 response, 8.32 0.1dB: design table, 8.44 response, 8.33 0.25dB: design table, 8.45 response, 8.34 0.5dB: design table, 8.46 response, 8.35 1dB: design table, 8.47 response, 8.36 amplitude response, 8.25 bandwidth chart, 8.23 impulse response, 8.18-19 low-pass prototype: circuit, 8.128 disadvantage, 8.129 normalization, 8.22 poles, 8.22 relative attenuation, 8.22 standard response, 8.21-23 step and impulse response, 8.25 transition region, 8.21-22 Chesnut, Bill, 12.82 Chevyshev, see: Chebyshev Chip cap, low inductance, 10.6 Chip select, 6.42 Choke, EMI protection, 11.35 Chop mode, 6.104 Chopper amplifier, 2.119-108 schematic diagram, 2.119 Chopper-stabilized op amp, 1.26, 2.119 compared with precision amps, 2.123 Christie, S.H., 3.60 Chryssis, George, 9.78 Circuit: tuned: formed from inductor/capacitor, 12.25 Q, 12.25 Index 12 Circuit board: layout issues, 9.25 printed, copper resistances, chart, 9.24 Circuit design, considerations, 10.14 Circuit diagram, data sheet, example, 6.198 Clamping amplifier, high speed, 2.59-63 Clamping diode, unnecessary on OPX91 family, 11.6 Class-D audio power amplifiers, 2.105-117 Clelland, Ian, 9.78, 10.27 Clock distribution: end-of-line termination, 12.47 source terminated transmission lines, 12.47 Clock generation and distribution, 7.65-83 Clock driver, PCB, 12.3 Closed-loop bandwidth, 1.57 and noise gain, 1.68 Closed-loop gain, 4.52 op amp, 1.13 op amp circuit, stabilizing, 13.36 in VCO, 4.64 CMOS: latched buffer, 12.30 for switches/multiplexers, 7.23 CMOS ADC, differential SHA, equivalent input circuit, 7.60 CMOS buffer/latch, for high speed ADC IC, 12.62 CMOS DAC Application Guide, 8.144 CMOS multiplexer, parasitic latchup, 7.47-50 CMOS op amp, 1.26 lower supplies, 1.44 CMOS switch: 1GHz, 7.40-41 adjacent, equivalent circuit, 7.27 basic, complementary pair, circuit, 7.25 basic considerations, 7.24-26 bipolar transistor equivalent circuit, with parasitic SCR latch, 7.48 Bode plot, transfer function in on-state, graph and equations, 7.29 charge coupling, dynamic settling time transient, circuit, 7.32 charge injection model: dynamic performance, circuit, 7.31 effect on input, circuit, 7.31 crosstalk, 7.33 diode protection scheme, 7.48 dynamic performance: off isolation, graph and equation, 7.29 transfer accuracy vs. frequency, graph, 7.28 error sources, 7.26-34 feedthrough, 7.30 input protection, using Schottky diode, 7.49 junction-isolation, cross-section, 7.47 model, with leakage currents and junction capacitances, 7.26-27 off condition, dc performance, circuit, 7.28 INDEX on condition, dc performance, circuit and equations, 7.27 on resistance vs. signal voltage, graph, 7.25 CMOS switch (cont) overcurrent protection, using external resistor, circuit, 7.49 parasitic components, 7.28 parasitic latchup, 7.47-50 in poorly designed PGA, circuit, 7.39 single-pole, settling time, constants, table, 7.34 CMR, definition, 6.124 CMRR: in bias current compensation, 1.40 op amp: calculation, 1.71 output offset voltage error, 1.71 CMV, definition, 6.124 Code, 5.2 conversion relationship, 5.2 hexadecimal, 5.3 natural, 5.3 straight binary, 5.3 Code centers, 5.12 CODEC, grounding, 12.67 Coding and quantizing, 5.1-20 COG capacitor, characteristics, 10.6 Coilcraft, 9.79 Coiltronics, 9.79 Cold-junction: compensation, 3.36-44 diagram, 3.40 temperature sensor, 3.40-41 definition, 3.37, 3.39 Colton, Evan T., 6.82 Commercial equipment, EMC, 11.23-24 Common-mode error, definition, 6.124 Common-mode range, definition, 6.124 Common-mode rejection, see: CMR Common-mode rejection ratio, see: CMRR Common-mode voltage, see: CMV Communication theory, classic paper by Shannon, 5.24 Companding, 6.37 Comparator, 2.65-76 1-bit ADC, 2.65, 6.44 definition, 2.65 latch and compare, 2.69 logic types, 2.72 op amp, 2.71 input circuitry, 2.75-76 output, 2.72-74 speed, 2.71-72 output, 72-74 response, hysteresis, 2.68 speed, 2.71-72 symbol, diagram, 2.65 window, 2.69 Complementary bipolar process, for switches/multiplexers, 7.23 Complementary code, 5.10 uses, 5.10 Complex impedance, definition, 10.23 Compliance-voltage, DAC output, 6.24 Compliance-voltage range, definition, 6.125 Compound input stage, 1.22 Computer equipment, radiated emission limits, table, 11.24 Conduction, EMI, 11.27 Conductivity, infinite, 12.9 Conductor, resistance, 12.5-6 Configuration assistant, 13.46-58 Connector leakage, and EMI, 11.27 Connelly, J.A., 12.51, 12.75, 12.82 Continuous switching: charge pump, circuit, 9.85 pump capacitor, circuit, 9.86 Controller, set-point, 3.58-60 Conversion relationship, code, 5.2 Converter: ideal step-up (boost), 9.36-41 rms to dc, 2.83-86 Copper resistance, printed circuit, chart, 9.24 Core, electronic, manufacturers, 9.79 Coriolis acceleration: definition, 3.20 example, 3.20 measurement, 3.22-23 to measure angular rate, 3.20-21 Coriolis accelerometer, 3.20-21 Coriolis effect: demonstration, 3.22 displacement, 3.23 Correlated double sampling, 3.66 diagram, 3.67 Couch, L.W., 4.73 Counts, L., 2.114 Counts, Lew, 2.115 Coupling: EMI, 11.37 and mutual inductance, within signal cabling, 12.24 Coussens, P.J.M., 3.27 Coxeter, H.S.M., 6.81 Crosstalk, 7.33 definition, 6.173 EMI, 11.37 op amp, 1.75 PCB, 12.3 Crowbar, EMI protection, 11.35 Crystal Oscillators: MF Electronics, 12.52 Crystal Oscillators: Wenzel Associates, Inc., 12.52 Cűk converter, 9.44 Current feedback input resistance, circuit, 1.43 Current feedback integrator, noninverting, 8.117 Index 13 BASIC LINEAR DESIGN Current feedback op amp: choosing between VFB and CFB, 1.19 differences from VFB, 1.17-19 effects of overdrive on inputs, 1.27-28 low power and micropower, 1.25-26 phase reversal, 1.25 rail-to-rail, 1.25 single supply: circuit design, 1.23-24 considerations, 1.20-22 supply voltage, 1.19-20 see also: CFB Current noise, op amp, 1.47, 1.49 Current source: schematic and layout: PCB, 12.71 dc current flow, 12.71 Current-mode binary weighted DAC, diagram, 6.13 Current-mode control, 9.50 Current-mode R-2R ladder network DAC, diagram, 6.17 Current-out temperature sensor, 3.33 Current-steering multivibrator VFC, 6.68 diagram, 6.69 Current-to-voltage converter, see: I/V Curtin, Mike, 4.73 Cutler, C.C., 6.112 Cut-off frequency, filter, 8.1-2 D DAC: 3-bit switched-capacitor, circuit, 6.47 8-bit, nonlinear transfer function, 6.37- 38 12-bit, SFDR, FFT, 4.48 architecture, 6.3-39 R-2R ladder, 6.14-18 basic, diagram, 6.3 charge-redistribution, 6.47 current-output architecture, 6.9 deglitcher, using SHA, 7.51 digital interfacing, 6.28-32 distortion, 6.167, 6.170 double buffered, 6.28 complex input structures, diagram, 6.29 dynamic performance, 6.167 fully decoded, 6.9-11 gain, in R-2R ladder, 6.16 general nonlinear, diagram, 6.39 glitch impulse area, 6.168-169 high speed: alternate loading, diagram, 6.30 buffering using differentia amplifier, 6.28 output, model, 6.24 ideal 12-bit, SFDR, output spectrum, 4.44 input and output definitions, 5.1 intentionally nonlinear, 6.37-39 Index 14 DAC (cont.) multiplying: in feedback loop, 2.91-92 performance, 2.92 nonlinear 6-bit segmented, diagram, 6.38 output: buffered with op amps, 6.23 graph, 6.36 output compliance voltage, 6.24 ping-pong, 6.29-30 settling time, 6.167-168 SFDR, 6.167, 6.170-172 test setup, 6.171 SNR, 6.170-172 measurement, analog spectrum analyzer, 6.172 string, 6.4-5 switched-capacitor, 6.47 thermometer, 6.9-11 transitions, with glitch, graph, 6.168 DAC-08, block diagram, 6.16 Dale Electronics, Inc., 9.79 Damped oscillation, 1.64 Damping ratio, 8.7 Damping resistor: fast logic, minimizing EMI/RFI, circuits, 12.44 series, high speed DSP interconnections, 12.45 Daniels, R.W., 8.143 Darlington NPN, pass device, 9.6 Darlington pass connection, 9.7 Data bus: interface, example, 6.199 parallel vs. serial, 6.206 Data converter, 6.1-211 ac errors, 6.129-176 ac specifications, 6.173-174 analog switches and multiplexers, 7.23-50 choosing, 6.205-211 code transition noise and DNL, graphs, 6.122 dc and ac specifications, 6.115 dynamic performance, 6.133 table, 6.134 gain error, 5.14 intercept points, significance, 6.144 least significant bit, for 2 V full scale input, table, 6.116 logic, timing, 6.33 metastable comparator output, error codes, diagram, 6.165 offset error, 5.14 offset and gain error, graphs, 6.117 parameters, 6.205-206 part selection, 6.206-211 primary dc errors, 6.117 resolution, 6.205 table, 6.116 sample rate, 6.205 SHA circuits, 7.51-63 specifications, defining, 6.115-116 INDEX Data converters (cont.) static transfer functions and dc errors, 6.117-127 support circuits, 7.1-63 thermal considerations, 12.90-95 timing specifications, 6.177-179 transfer functions for nonideal 3-bit DAC and ADC, graphs, 6.119 voltage references, 7.1-21 Data directed scrambling, 6.110 Data distribution system, using SHA, 7.51 Data ready, 6.42 Data scrambling, 6.110 Data sheet: absolute maximums, 1.89-91, 6.188-189 application circuits, 6.202 circuit description, 6.198 defining the specifications, 6.192 equivalent circuits, 6.193 evaluation boards, 6.203 front page, 1.83, 6.181 graphs, 1.92, 6.194-197 how to read, 6.181-203 interface, 6.199-200 main body, 1.93, 6.198 for op amp, 1.93-94 ordering guide, 1.92, 6.189-190 pin description, 6.191-192 reading, 1.83-94, 6.181-203 register description, 6.201 specification tables, 1.83-89, 6.181-188 Data Sheet for AD815 High Output Current Differential Driver, 12.96 Data Sheet for AD8011 300 MHz, 1mA Current Feedback Amplifier, 1.82 Data Sheet for AD8016 Low Power, High Output Current xDSL Line Driver, 12.96 Data Sheet for AD8017 Dual High Output Current High Speed Amplifier, 12.96 Data Sheet for AD8551/AD8552/AD8554 ZeroDrift, Single-Supply, Rail-to-Rail Input/Output, 1.82 Data Sheet for AD8571/AD8572/AD8574 ZeroDrift, Single-Supply, Rail-to-Rail Input/Output, 1.82 Data Sheet for OP777/OP727/OP747 Precision Micropower Single-Supply Operational Amplifiers, 1.82 Data Sheet for OP1177/OP2177/OP4177 Precision Low Noise, Low Input Bias Current Operational Amplifiers, 1.82 Dattorro, J., 6.113 DC error source, in-amp, 2.22-25 DC errors, 6.117-127 DDS, 6.170 aliasing, 4.45-46 basic system, high resolution, 4.44 configuration assistant, 13.49 flexible system, diagram, 4.42 DDS (cont) fundamental, 4.41 harmonics, 4.46 RF/IF circuit, 4.41-44 sampled data system, 4.41 tuning equation, 4.43 vs. PLL-based system, 4.46 DDS Design, 4.50 DDS system: ADC clock driver, 4.46-47 amplitude modulation, 4.47 dither, for quantization noise and SFDR, 4.49 harmonics, 4.47 SFDR considerations, 4.47-49 De Jager, F., 6.112 Dead time, DAC settling time, 6.167 Decimation, 6.90-91 Decoupling, 12.77-82 inadequate, effects, 12.78-79 local high frequency, 12.77-80 supply filter, circuits, 12.78 PCB, 12.77-82 power line, forms resonant circuit, 12.80 surface-mount multilayer ceramics, 12.77 voltage reference, 7.2 Decoupling capacitor, in-amp, 2.24 Decoupling point, 12.63 Del Signore, B.P., 6.113 Delay constant, surface microstrip, 12.39 Delay dispersion, graph, 2.66 Delay skew, 12.50 Deloraine, E.M., 6.112 Delta modulation, 6.85 circuit, 6.85 quantization, graph, 6.86 Delta phase register, 4.42 Delyiannis, T., 8.143 Dempsey, Dennis, 6.7 Demultiplexed data bus, 12.50 Denormalization, filter, 8.29 Derating curves, 12.85 Derjavitch, B., 6.112 Design development: evaluation boards and prototyping, 13.69- 92 online tools and wizards, 13.33-68 simulation, 13.3-32 tools, 13.1-92 Design wizard: analog filter wizard, 13.61-67 photodiode wizard, 13.58-60 Designing for EMC (Workshop Notes), 11.50 Detecting, architecture, 4.21 Detecting Fast RF Bursts Using Log Amps, 4.28 Detecting log amp, 2.55-56 Detector, True Power, RF/IF circuit, 4.29-31 Development of an Extensive SPICE Macromodel for "Current-Feedback" Amplifiers, 13.31, 13.91 Index 15 BASIC LINEAR DESIGN Dickinson, Arthur H., 6.83 Dielectric, types, 10.3-9 Dielectric absorption, 10.10-13 capacitor, 10.11-13 circuit example, 10.11 material characteristic, 10.12 PCB, 12.19 circuit, 12.20 sample-and-hold errors, 10.12 SHA, 7.58 circuit and graph, 7.59 Dielectric hysteresis, 10.11 Difference amplifier: circuit, 2.9 definition, 2.8 Differential amp: calculator, manual and automatic modes, 13.44 CMR/gain/noise calculator, screen, 13.44 Differential amplifier, 2.31-32 advantages, 2.31 Differential analog input capacitance, definition, 6.125 Differential analog input impedance, definition, 6.125 Differential analog input resistance, definition, 6.125 Differential analog input voltage range, definition, 6.125 Differential current-to-differential voltage conversion, 6.27-28 Differential DC-coupled output: with dual-supply op amp, circuit, 6.25 with single-supply op amp, circuit, 6.26 Differential gain: definition, 1.73, 6.173 example, 1.74 Differential input voltage, op amp, 1.44 Differential linearity error, 6.117 Differential nonlinearity, 6.118 ADC, 5.17 graph, 6.120 and code transition noise, 5.19 converter, 5.15 DAC: details, 5.16 graph, 6.119 distortion effect, 6.133-135 Differential nonlinearity error, in ADC/DAC, graphs, 6.134 Differential nonlinearity temperature coefficient, 6.123-124 Differential PCM, 6.85 circuit, 6.85 Differential phase: definition, 1.75 specifications, 1.74 Differential phase, definition, 6.173 Index 16 Differential transformer coupling, circuit, 6.25 Digi-Trim, in op amp, 1.26 Digiphase, 4.59 Digital corrected subranging, 6.54 Digital crosspoint switch, 7.46 Digital crosstalk, definition, 6.173 Digital current, high, multiple PCB, diagram, 12.68 Digital data bus noise, immunity in highspeed ADC IC, 12.62 Digital error correction, 6.54 Digital filter, in sigma-delta ADC, 6.100- 101 Digital filtering, 6.90 Digital ground, 12.55 in mixed-signal IC, 12.60-61 Digital ground pin, circuit, 12.56 Digital interface, 6.28-32 Digital isolation: AD260/AD261 high speed logic isolators, 2.40-42 ADuM130X/ADuM140X multichannel products, 2.46-48 ADuM1100 architecture, 2.42-46 in data acquisition system, 2.41 iCoupler technology, 2.42 techniques, 2.39-48 using LED/photodiode optocoupler, 2.40 using LED/phototransistor optocoupler, 2.39 Digital noise, in mixed-signal IC, 12.60-61 Digital phase wheel, 4.43 Digital phase-frequency detector: in PLL synthesizer, 4.54 using D-type flip flops, circuit, 4.54 waveforms, 4.55 Digital phosphor scope, acquisition time measurement, 7.59 Digital PLL, 4.52 Digital pot, 6.7-9 two times programmable, diagram, 6.9 Digital potentiometer, 6.7-9 advantages, 6.8 internal timer, 6.8 Digital sampling scope, acquisition time measurement, 7.59 Digital signal processor, see: DSP Digital switch, crosspoint, 7.46 Digital word, 6.1 Digital-output temperature sensor, 3.56-58 Digitally controlled VGA, 4.38-39 RF/IF circuit, 4.38-39 DigiTrim technology: circuit offset adjustment, 1.34-35 schematic, 1.35 Diode: input protection, 11.2 junction capacitance, 11.8 for parasitic SCR latch-up protection, 7.48 INDEX Diode-ring mixer: diagram, 4.7 performance limitations, 4.7 RF/IF circuit, 4.3-6 Diode/op amp log amp, disadvantages, 4.21 DiPilato, Joe, 6.114 Direct Digital Frequency Synthesizers, 4.50 Direct digital synthesis, see: DDS Direct IF to digital conversion, 5.28 Discrete time sampling, 5.22 Dispersion, comparator, 2.65 Dissipation factor, definition, 10.13-14 Distance, EMI, 11.28 Distortion: CFB op amp, 1.19 harmonic, 1.60 intercept points, 1.60 intermodulation distortion, 1.60 multitone power ratio, 1.60 op amp, definition, 1.60 SFDR, 1.60 SHA, 7.54 static and dynamic, 13.22-23 total harmonic, 1.60 plus noise, 1.60 Distortion products, location, graph, 6.135 Dither, 4.48 Dither signal, 6.130 Divider: circuit, 2.82 with multiplier and op amp, inverting/noninverting modes, circuit, 2.81 DNL: and sampling clock jitter, quantization noise, SNR, and input noise, graph, 6.160 see also: Differential nonlinearity Dobkin, Robert C., 9.26 Doeling, W., 12.51 Dominant pole frequency, 1.30 Dorey, Howard A., 6.84 Dostal, J., 1.81 Doublet glitch, 6.168 Downing, Salina, 13.31 Drift: reference temperature, table, 7.14 voltage reference, 7.13 Drift with time, op amp, 1.33 Drift/gain error, 13.39, 13.41 Droop: hold mode, 7.58 rate, 7.53 Dropout voltage, 9.5 DSP: grounding, 12.67 output rise times and fall times, graph, 12.43 Dual amplifier band-pass filter: design equations, 8.100 diagram, 8.80 Dual slope ADC: advantages, 6.74 diagram, 6.73 integrator output waveforms, 6.73 Dual slope/multislope ADC, 6.73-75 Dual-modulus prescaler, 4.57-58 Duff, David, 6.175 Dummer, G.W.A., 12.51 Duty cycle, waveform, 1.24 Dynamic range, log amp, 4.24 Dynamic settling time, transient, charge coupling, graph, 7.32 E E-Series LVDT Data Sheet, 3.27 Early effects, 3.31 Earnshaw, J.B., 6.80 Eckbauer, F., 6.113 ECL, 5.2 EDN Magazine, 11.23 EDN's Designer's Guide to Electromagnetic Compatibility, 11.50 Edson, J.O., 1.80, 5.20, 6.80, 6.82, 6.175, 7.63 Edwards, D.B.G., 6.82, 7.63 Effective aperture delay time, 6.156-157 and ADC input, graph, 6.157 graph, 7.56 SHA specification, 7.56 Effective input noise, definition, 6.126 Effective number of bits, see: ENOB Effective resolution, 6.132 Effective temperature differential, calculation, 12.84 EIAJ ED-4701 Test Method C-11, Electrostatic Discharges, 11.51 EIAJ Specification ED-4701 Test Method C-111 Condition A, 11.13 Eichhoff Electronics, Inc., 10.27 80C51, microcontroller, 3.57 Electric-field intensity, RFI, 11.30 Electrically long, cable, 11.46-48 Electrically short, cable, 11.46-47 Electrolytic capacitor: characteristics, 10.4-5 impedance vs. frequency, graph, 10.7 life, 10.14 polarized, 9.72 ripple current, 9.74-75 types, 9.72 Electromagnetic compatibility, see: EMC Electromagnetic interference, 9.66 Electrostatic discharge, see: ESD Electrostatic potential, modeling, 11.12-17 Elliott, Michael, 6.83, 7.63 Index 17 BASIC LINEAR DESIGN Elliott, Michael, R., 6.83 Elliptical filter, 5.27 definition, 8.26 Embedding: advantages and disadvantages, 11.39 traces, 12.42 EMC: regulations: design impact, 11.25 industries, 11.23-25 EMC Test and Design, 11.50 EMI: diagnostic framework, table, 11.27 generated by power line disturbances, 11.35 model, source/receptor/path, 11.26-27 regulation: by FCC and VDE, 11.23 radiated emissions, 11.23 troubleshooting, philosophy, 11.48-49 waveguide, via enclosure openings, 11.43 EMI/RFI: and analog circuit, 11.23-49 considerations, 11.23-49 Emitter-coupled logic, see: ECL Encoder, early ADC, 5.22 Encoding process, differential nonlinearity, 6.133 End point, 6.117-118 End point method, for integral linearity error, 5.14-15 End termination: both ends, for single transmission line, 12.48 microstrip transmission lines, 12.46 End-of-conversion (EOC), 6.42 Engelhardt, E., 6.113 ENOB, 6.90, 13.54 definition, 1.63, 6.136-137 Equivalent input referred noise, 6.131-132 Equivalent noise bandwidth, 1.48 Equivalent number of bits, see: ENOB Equivalent pin circuit, data sheet, example, 6.193 Equivalent series inductance, 10.10, 10.13 capacitor, 9.69, 9.83 capacitor loss element, 10.3 Equivalent series resistance, 10.10, 10.13 capacitor, 9.69, 9.83 filter loss element, 10.3 temperature dependence, 10.7 Erdi, George, 1.79-80, 2.114 Error: ADC/DAC DNL, graphs, 6.134 in design, strategy, 12.26 drift/gain, 13.39 resolution, 13.39 Error budget calculator: for in-amp, 13.42 Index 18 Error budget calculator (cont) for op amp, 13.39-42 screen, 13.40-41 Error corrected ADC, 6.52-57 Error vector magnitude, 13.27 Error voltage, from digital current flowing in analog return path, 12.58 ESD: catastrophic failure, 11.1 damage, 11.17 considerations, 11.18 prevention in ICs, 11.18 definitions, 11.1 effects, 11.11-21 elimination, keys, 11.1 failure threshold, 11.1 generation, 11.12 IC protection, protocols, 11.20 integrated circuit protection, 11.11-21 model: comparison, table, 11.15 discharge waveforms, comparison, 11.15-16 schematic representation, and discharge waveforms, 11.14 models, 11.12 sensitive devices: handling, workstation, 11.19 recognition, 11.19 ESD Association Draft Standard DS5.3 for Electrostatic Discharge (ESD) Sensitivity Testing-Charged Device Model (CDM) Component Testing, 11.51 ESD Association Specification S5.2, 11.13 ESD Association Standard S5.2 for Electrostatic Discharge (ESD) Sensitivity Testing-Machine Model (MM)-Component Level, 11.51 ESD Prevention Manual, 11.50 European cordless telephone system DECT, with open-loop modulation, 4.70 Evaluation board, 13.69 clocking description, 13.76-78 clocking with interleaved data, 13.78 data converter, 13.72-73 data sheet, 6.203 full prototype board, 13.89 high speed FIFO system, 13.74-75 ADC Analyzer, 13.74-75 theory of operation, 13.75-76 versions, 13.75 Op amp dedicated, 13.70-71 illustrations, 13.71 general purpose, 13.69-81 illustration, 13.69 PCB, 12.3 layout, 12.4 precision ADC, 13.79-81 INDEX Evaluation boards (cont) prototyping, 13.82-87 additional information, 13.88-89 sockets, 13.87-88 Excess noise, resistor, 10.21-22 Exclusive-or (EXOR) gate, in PLL synthesizer, 4.54 Expandor, 6.37 Explicit method, conversion by analog circuit, 2.83 Exponential amplifier, X-AMP, 4.35 External clock jitter, 12.64 External current, 12.9 External offset adjustment, circuits, 1.36 External trim, 1.36-37 F Fague, D.E., 4.74 Failure, resistor, effects, 10.20 Fair-Rite Linear Ferrites Catalog, 10.27 Fall time: graph, 6.177 op amp, 1.70 timing specification, 6.177 Faraday screen, 12.27 Faraday shield, 12.3, 12.24, 12.28-30 definition, 12.28 in isolation transformer, EMI protection, 11.36-37 model, 12.29 Farrand Controls, Inc., Inductosyn, 3.13 Fast Fourier transform, 5.21, 6.129 FAST Step mode, in AD7730 digital filter settling time, 6.106 FAT-ID concept, for EMI problems, 11.28 FDMA, noise/power ratio, 6.146 FDNR, 8.70-71 FDNR filter: for CD reconstruction, 8.134 op amp requirements, 8.115 Feedthrough protection, 11.32 Feedback counter: N-divider, 4.56 in PLL synthesizer, 4.53, 4.56-58 Feedback divider, in PLL, 4.52 Feedthrough: CMOS switch, 7.30 definition, 6.174 Feedthrough error, definition, 6.174 Ferguson, P.F., Jr., 6.113, 6.114 Ferguson, P., Jr., 6.113 Ferrite, 10.25 impedance, 10.25 inductor core, 9.68 leaded, 10.25 nonconductive ceramics, 10.25 FET input amp, 1.41 capacitance, 8.115 Fetterman, Scott, 6.82 Fiedler, Udo, 6.83 Film capacitor, 9.72 characteristics, 10.4-5, 10.6 poor temperature coefficient, graph, 8.110 Filter: 60 Hz notch, 8.141-142 active, antialiasing, design, 8.121-127 analog, 8.1-144 antialiasing, 5.26 requirements, 5.28 in undersampling, 5.29-31 for undersampling, 5.30 attenuation curve, 8.7 band-pass, 5.30, 8.2 band-reject, 8.2 baseband antialiasing, 5.26-28 Butterworth, 5.27 circuit and component quality factors, 8.63 components, passive, problems, 8.109-113 cut-off frequency F0, 8.7 damping ratio, 8.7 definition, 8.1 design equations, 8.88-107 design examples, 8.121-142 design tables, 8.42-52 design wizard, 13.54 elliptic, 5.27 frequency response vs. DAC control word, graph, 8.138 frequency transformation, 8.55-62 low-pass to all-pass, 8.61-62 low-pass to band-pass, 8.56-59 low-pass to band-reject (notch), 8.59-61 low-pass to high-pass, 8.55-56 high-pass, 8.2 implementation, problems, 8.109-120 inductive and/or resistive, 11.33 inverse Chebyshev, 8.27-28 key parameters, 8.3 leakage, RFI, 11.31 low-pass: and high-pass response, graph, 8.130 idealized, 8.2 and RFI, 11.32 maximally flat delay with Chebyshev stopband, 8.27 multistage, and RFI, 11.32 nonzero, 11.33 notch, 8.2 order, determination, graph, 8.121 passive, normalized implementation, circuit, 8.122 phase response, 8.14-16 practical applications, 8.1 quality factor Q, 8.7 realization, 8.63-108 reconstruction, 6.35 Index 19 BASIC LINEAR DESIGN Filter (cont) response curve, low-pass prototype, allpole, 8.29-41 S-plane, 8.5-7 second-order responses, chart, 8.13 selection, using configuration assistant, 13.54 standard responses, 8.21-54 theory, low-pass prototype, 8.128 time domain response, 8.18-19 transfer function, 8.18 transformation, 8.128-133 table, 8.67 Finite amplitude resolution due to quantization, 5.22 First order all-pass filter: design equations, 8.106 diagram, 8.86 Fisher, J., 6.113 Flash ADC, 6.50-51 Flash converter, 6.50-51 3-bit all-parallel, diagram, 6.50 disadvantages, 6.50 interpolation, 6.51 Flett, F.P., 3.27 Flicker, eliminated in-tracking ADC, 6.67 Flicker noise, op amp, 51-52 Flicker-free code resolution, 6.132-133 calculation from input-referred noise, 6.133 Flyback converter, circuit, 9.45 Flyers, 6.164 Folding converter, 6.59 Folding stage: functional equivalent circuit, 6.60 transfer function, 6.60 Forward-biased diode, circuit, 7.2 Fourier analysis, 8.14 Fourier transform, 8.18 Fractional binary code, 5.3 Fractional-N synthesizer, 4.59-60 diagram, 4.59 disadvantages, 4.60 Franco, S., 8.143 Franco, Sergio, 1.79, 1.81 Fraschilla, J.L., 6.82 Frederiksen, Thomas M., 1.81 Frequency, EMI, 11.28 Frequency dependent negative resistance filter, implementation, circuit, 8.125 Frequency dependent negative resistor: 1/s transformation, 8.71 versions, 8.70 Frequency division multiple access, see: FDMA Frequency response, log amp, 4.24 Frequency synthesis, RF/IF circuit, 4.41-50 Index 20 Frequency synthesizer: definition, 4.41 using PLLs, 4.41 Frequency-to-voltage converter, as receiver, 2.42 Friend, J.J., 8.143 Friis equation, 6.154 Front page: data sheet: example, 6.182 for op amp, 1.83 F (subzero), definition, 8.7 Fu, Dennis, 3.27, 6.84 Full wave rectifier, 3.3 Full-power bandwidth, 6.138 definition, 1.65-66 Full-scale, definition, 6.125 Full-scale range, definition, 6.125 Fully decoded DAC, 6.9-11 current-output thermometer, simplest, diagram, 6.10 Fundamental frequency, 6.137 G Gaalaas, Eric, 2.127 Gailus, Paul H., 6.114 Gain: definition, 6.126 definitions, 1.15 SHA, 7.54 variation vs. DAC control word, graph, 8.139 Gain block, 2.5-6 Gain error, 5.13, 6.117 Gain tempco, definition, 6.123 Gain-bandwidth product: definition, 1.67 not in CFB op amp, 1.17 op amp, 1.11 Gallium-arsenide diode, 4.6 Ganesan, A., 6.113 Garcia, Adolfo, 13.91, 13.92 Gardner, F.M., 4.73 Gas discharge tube, EMI protection, 11.35 Gated oscillator control: buck regulator, output voltage waveform, 9.53 pulse burst modulation, 9.51-54 Gauss, magnetic flux density, 9.65 Gaussian distribution, 4.37 Gaussian filter, 4.71, 8.24 6 dB: design table, 8.52 response, 8.40 12 dB: design table, 8.51 response, 8.40 Gaussian modeled jitter, 13.25 Gaussian noise, 1.54, 6.146 source, 1.48 INDEX Gaussian system, noise, 7.15 Gay, M.S., 2.115, 4.28 Geffe, P.R., 8.143 General impedance converter, block diagram, 8.68 General Instrument, Power Semiconductor Division, 9.80 Gerber files, 6.203, 12.4, 13.72, 13.86 Germano, Antonio, 13.92 Gilbert cell, 2.79-81, 4.15-16 disadvantages, 2.80, 4.16 four-quadrant, circuit, 2.80 Gilbert, Barrie, 2.79-80, 2.114, 2.115, 4.10, 4.15, 4.40 Gilbert, Roswell W., 6.84 Giles, James N., 6.80 Ginzton, Edward L., 1.80 Glitch: code-dependent, 6.170 effect on spectral output, graph, 6.170 Glitch energy, 6.168 Glitch impulse area: DAC, 6.168-169 net, DAC, calculation, 6.169 Goodall, W.M., 6.81 Goodenough, Frank, 3.28, 9.26 Goodman, D.J., 6.112 Gorbatenko, G.G., 6.82 Gordon, Bernard M., 6.81, 6.82, 6.83 Gorman, Christopher, 6.7 Gosser, Roy, 1.81, 2.3, 6.82, 7.63 Gosser, Royal A., 1.80, 2.114 Goto, E., 6.80 Gottlieb, Irving M., 9.78 Gowanda Electronics, 9.79 GPS navigation, using gyroscopes, 3.20 Graham, Martin, 12.51, 12.75 Grame, Jerald, 12.51, 12.82 Graphs: data sheet, for op amp, 1.92 performance, op amp, 1.93 Gray bit, 6.60-61 Gray code, 5.12, 6.62-63 Gray, Frank, 5.20, 6.80 Gray, G.A., 6.175 Gray, J.R., 6.82, 7.63 Gray, Paul R., 1.81 Grift, Rob E.J. van der, 6.83 Gross, George F., Jr., 6.82 Ground, filter effectiveness reduction, 11.33-35 Ground isolation, 12.11-14 amplifier, 12.12 Ground loop, 12.9-11 circuit, 12.11 Ground noise, 12.9-11 in high frequency system, 12.71 Ground plane, 12.36, 12.56-59, 12.70 breaks, 12.73-74 circuit inductance, 12.73 low-impedance, 12.57 slit, and current flow, advantage, 12.59 Grounded-input histogram, 6.131-132 Grounding, 12.53-75 high frequency, 12.70-73 improper, 12.53 mixed-signal, confusion, 12.66 mixed-signal devices: high digital currents, multicard system, 12.68-69 low digital currents, multicard system, 12.67-68 mixed-signal ICs, evaluation board, 12.66 PCB, 12.53-75 summary, 12.70 Grounding point, 12.63 Grounding system, source-to-load, 12.10 Group delay, filters, equations, 8.16 Guarding, PCB, 12.17 Gyroscope: angular-rate-sensing, 3.19-26 applications, 3.19-20 axes of rotational sensitivity, 3.19 iMEMS angular-rate-sensing, 3.19-26 description, 3.19-20 mechanical schematic, 3.22 H HAD-ADC-EVALA-SC, high speed FIFO system, 13.75 Hageman, Steve, 10.27 Halford, Phillip, 4.40 Hall effect, 3.6 applications, 3.6-7 magnetic sensor, 3.6-8 as rotational sensor, 3.7 Hall switch, 3.6 Hall voltage, 3.6 Handbook of Chemistry and Physics, 3.64, 3.68 Hard limiter, 6.144 Harmonic distortion: DAC, 6.170 definition, 6.135-136 inadequate decoupling effects, 12.78- 79 Harmonic images calculator, spurs and SFDR, 13.52 Harmonic sampling, 5.28 Harmonics, converter, 13.23 Harrington, M.B., 3.28 Harris, Ted, 7.84 Harrison, R.M., 6.82 Hartley, R.V.L., 5.24, 5.32 Hauser, Max W., 6.112 Hayes, John, 13.92 Index 21 BASIC LINEAR DESIGN Heat sink: definition, 12.85 thermal resistance, case to ambient air, 12.85 Heise, B., 6.113 Henderson, K.W., 8.143 Hendriks, Paul, 6.114 Henning, H.H., 1.80, 5.20, 6.80, 6.82, 7.63 Henry, J.L., 6.113 Hensley, Mike, 6.83, 7.63 Hexadecimal code, and binary, relationship, 5.3 High mega-ohm resistor: comparison chart, 8.112 table, 10.21 High-side downconverter, 4.3 High-side injection, 4.3 High-speed clamping amplifier, 2.59-63 High-speed logic, 12.43-48 isolator, transformer-coupled isolation, 2.40-42 PCB, 12.43-48 Higher order loop, considerations, 6.98 High-pass filter, 8.2, 8.13 definition, 8.56 transfer function, 8.8-9 Hindi, David, 13.31, 13.91 Hobbs, W., 13.31 Hold mode, 6.48 Hold mode droop, 7.58 Hold mode settling time, SHA specification, 7.54 Hold mode specification, SHA, 7.58-59 Hold signal, definition, 6.173 Hold time, timing specification, 6.177 Hold-to-track transition specification, SHA, 7.59 Horna, O.A., 6.82, 7.63 HOS-100, FET input open-loop hybrid buffer amplifier, circuit, 2.1 HP8561E, 4.68 HP8562E, 4.68 HP8563E, 4.68 HSC-ADC-EVALA-DC, high speed FIFO system, 13.75 HSpice, 13.1 Huelsman, L.P., 8.143 Hughes, Richard Smith, 2.115, 4.28 Human body model, ESD, 11.12-13 Hunt, W., 8.144 Hurricane Electronics Lab, 9.79 Hygroscopicity, PCB, 12.1 Hysteresis, 6.44 application, circuit, 2.67 calculation, 2.68 comparator, 2.66 comparator response, 2.68 effects, graph, 2.67 fast comparator, 2.70 loss, 9.67 Index 22 Hysteretic current control, 9.51 I I/O Buffer Information Specification, see: IBIS I/V converter, 6.23-28 differential current-to-differential voltage conversion, 6.27-28 differential to single-ended conversion, 6.24-25 single-ended current-to-voltage conversion, 6.27 IBIS model, advantage, 13.17 Ice point junction, definition, 3.39 Ichiki, H., 6.80 iCoupler technology: air core technology, 2.45 chip scale transformers, 2.42 electromagnetic radiation, 2.46 isolation technology, 2.42-48 Idle tone, considerations, 6.96-97 IEC Standard 801-2, 11.24 IEC Standard 801-4, 11.24 IEEE Standard 1596-1992, 6.31 IEEE Standard 1596.3, 6.31 IEEE Standard C62.41, 11.24 IF sampling, 5.28 Ikeda, K., 6.80 IMD: 1 dB compression point, 6.143-145 definition, 1.61 intercept points, and gain compression, 1.62 products, graph, 1.61 second- and third-order: graph, 6.141 intercept points, 6.143-145 third-order products, 1.61-63 iMEMS angular-rate-sensing gyroscope, 3.19- 26 Immunity, definition, 11.30 Impedance: common ground, current, errors, 12.10 comparison, wire vs. ground plane, 11.26 controlled, 12.35 PCB traces, 12.36-37 definition, 10.3 EMI, 11.28 ferrite, 10.25 high circuit, noise, 12.30-32 input, definition, 6.126 microstrip transmission line, calculation, 12.38 op amp, 1.9 skin depths, shielding materials, table, 11.45 symmetric stripline, calculation, 12.40 Implicit method, conversion by analog circuit, 2.84 Impulse function, filter, 8.18 Impulse response, related to filter order, 8.19 In-amp, 2.7-28 bridge amplifier error budget amplifier, 2.28 CMR, 2.8-9, 2.23 INDEX In-amp (cont) CMR/gain/noise calculator, screen, 13.43 DC error sources, 2.22-25 DC errors RTI, table, 2.25 definitions, 2.7-8 error budget calculator, screen, 13.42 gain calculator, 13.43 generic, circuit, 2.7 input overvoltage considerations, 2.29 input overvoltage protection, 2.29 noise sources, 2.26-27 offset voltage model, 2.23 overvoltage, 11.1 precision closed-loop gain block, 2.7 precision single-supply composite, 2.15- 17 PSR, 2.24 subtractor or difference amplifier, 2.8- 11 three op amp: advantages, 2.12 in-amp topology, 2.12-14 circuit, 2.12 two op amp in- amp topology, 2.18-21 In-amp/op amp, functionality differences, 2.8 In-band region, spectrum, 6.139 In-band SFDR, 6.139 Inductance: mutual, 12.22-24 PCB, 12.21-34 stray, 12.21 wire and strip, calculations, 12.21 Inductive coupling: basic principles, 12.23 reduction, by proper signal routing and layout, 12.23 Inductive loop, 12.72 Inductive resistance, definition, 10.23 Inductor, 10.23-27 basics, 10.23-24 calculations: buck and boost regulators, 9.58-61 caveats, 9.58, 9.61 considerations, chart, 9.58 core materials, 9.68 definition, 10.23 energy transfer, 9.29 equations, 9.30 ferrite, 10.25 fundamentals, 9.28-30 graph, 9.29 manufacturers, 9.79 parasitic effects, 12.24-25 passive filter component, problems, 8.109-113 power loss, 9.67-68 chart, 9.68 Q, 12.25 self-resonant frequency, 9.69 in switching regulator, 9.57-69 synthetic, circuit, 10.24 Inductor current: core saturation, graph, 9.66-67 equations, switch, and diode voltage effects, 9.55 Inductosyn: diagram, 3.13-14 linear position sensor, 3.13-14 operation, like resolver, 3.14 rotary, 3.14 Innovative Mixed-Signal Chipset Targets Hybrid-Fiber Coaxial Cable Modems, 4.50 Inose, H., 6.112 Input bias current, 1.38 In-amp, 2.23 compensation, 1.39-41 Input capacitance: large, 1.47 modulation: compensation, 8.116 distortion, 8.116 filter distortion, 8.115-117 op amp, 1.43 Input circuitry, comparator, 2.75-76 Input common mode voltage range, op amp, 1.43 Input impedance: definition, 6.126 op amp, 1.42-43 Input noise, and sampling clock jitter, DNL, SNR, and quantization noise, graph, 6.160 Input offset current, 1.38 Input overvoltage protection: In-amp, 2.29 circuit, 1.28 Input protection: CMOS switch, using Schottky diode, 7.49 diode, overvoltage, 11.2 op amp, 1.77 Input stage: configuration, and overvoltage, 11.2-3 overvoltage, chart, 11.2 Input voltage noise, sources, 2.26 Input-referred noise: definition, 6.126 effect on ADC grounded input histogram, 6.132 Instrumentation amplifier, see also: In-amp Insulation resistance, capacitor, 10.10 Integral linearity error, 6.117 measurement, graphs, 6.118 Integral nonlinearity, distortion effect, 6.133-135 Integrated Micro Electro Mechanical Systems, see: iMEMS Integrated VGA Aids Precise Gain Control, 4.40 Integrating ADC, frequency response, graph, 6.74 Integrator, diagram, 8.67 Intentionally nonlinear DAC, 6.37-39 Intercept point, log amp, 4.24 Intercept voltage, 2.54 Interconnection stability, resistor, 10.17 Interconnects, and EMI, 11.27 Index 23 BASIC LINEAR DESIGN Interface, data sheet, 6.199-200 Interference: EMI: circuit/system immunity, 11.27-28 conduction/radiation, 11.27 emission, 11.27 internal, 11.28 susceptibility, 11.27-28 frequency bands, separation, 11.32 Intermodulation distortion, see: IMD Internal aperture jitter, 12.64 Internal SHA, for IC ADC, 7.59-62 International Rectifier, 9.79, 9.80 Interpolating DAC, 6.33-35 Interpolating TxDAC, 6.33-35 Interpolation, 4.35 in flash converter, 6.51 Intersymbol distortion, DAC, 6.11 An Introduction to the Imaging CCD Array, 3.68 Inverse Chebyshev filter, 8.27-28 Inverse function, generation, circuit, 2.82 Inverting mode guard, circuit, 12.16 Isolated switching regulator: forward topology, circuit, 9.46 topologies, 9.45-46 Isolation amplifier, 2.33-38 AD210 3-port isolator, 2.34-35 analog isolation techniques, 2.33-34 Isolation amplifier (cont) capacitive coupling, 2.33 motor control, 2.35-36 optional noise reduction post filter, 2.36 two-port isolator, 2.36-37 Isolation barrier, 2.33 Isothermal block, for thermocouple terminated leads, 3.41 K Kaiser, Harold R., 6.81 Kaufman, M., 1.81 Kautz, W.H, 8.143 Kelp, Jeff, 7.84 Kelvin connection, 3.48-49, 3.52 Kelvin DAC, and digital potentiometer, 6.8 Kelvin divider, 6.4-5, 6.9 drawback, 6.4 low glitch architecture, 6.4 thermometer DAC, diagram, 6.5 variation, 6.5-7 Kelvin feedback, 12.7 Kelvin sensing, 9.25 circuit, 7.14 Kelvin-Varley divider, 6.5-7 Kemet Electronics, 9.79 KEMET T491C, tantalum capacitor, 9.18 Kerr, Richard J., 4.73 Kester, Walt, 1.79-82, 3.64, 3.68, 6.80, 6.176, 12.51, 12.75, 12.82, 12.96, 13.31 Kettle, P., 3.27-28 Key, E.L., 8.72, 8.143 Kimmel Gerke Associates, 11.23 Kimmel-Gerke, 11.26, 11.32 Kinniment pipelined ADC architecture, 6.57 Kinniment, D.J., 6.82, 7.63 Kirchoff's Law, 8.5, 12.7-8, 12.22 Kitchin, C., 2.114 Kitchin, Charles, 2.115 Kitsopoulos, S.C., 6.82, 7.63 Kiyomo, T., 6.80 Klonowski, Paul, 6.84 Koch, R., 6.113 Kool μ, inductor core, 9.68 Kovacs, Gregory T.A., 9.26 Kroupa, Venceslav, 4.50 Kwan, Tom W., 6.113 J J-K Flip-Flop, in PLL synthesizer, 4.54 Jager, F. de, 6.112 Jantzi, S.A., 6.114 Jitter: data converter modeling, 13.24-25 Gaussian modeled, 13.25 sources, 13.24-25 vs. SNR vs. input frequency, graph, 13.24 Jitter Reduction in DDS Clock Generator Systems, 4.50 Johnson noise, 1.57-58, 5.11 definition, 1.49 resistor, 1.55 Johnson, Howard W., 12.51, 12.75 Jung, W., 8.144 Jung, Walt, 1.79, 6.84, 7.21, 9.78, 10.27, 12.82, 12.96 Jung, Walter G., 1.79, 1.81, 6.175 L Lane, Chuck, 6.81 Laplace transform, 8.18 Laser trimming, 1.34-35 Latch-enable to output delay, comparator, 2.70 Latency, data converter modeling, 13.25 LCR latchup, protection, using trench-isolation, 7.50 LDO linear regulator, 9.92 LDO pre-regulator, 7.15 LDO regulator, 9.9-12 dominant pole, 9.11 ESR zones, 9.11-12 traditional architecture, 9.9-10 Leaded ferrite bead, 10.25 Leakage: filter, RFI, 11.31 resistance, in PCB, 12.17 Leakage current, output, definition, 6.126 Least significant bit, 5.2, 5.11 Index 24 INDEX Lee, Seri, 12.96 Lee, Stephen, 4.40 Lee, Wai Laing, 6.113 Lee, W.L., 6.113 Leeson, D.B., 4.74 Leeson’s equation, noise in VCO, 4.62 Lenk, John D., 9.78 Lewis, Stephen H., 6.82 LH0033, 2.1 Li, Alan, 9.26 Lindesmith, John L., 6.84 Line driver, 2.101 Line receiver, with 4-resistor differential amplifier, circuit, 2.102 Line sensitivity, voltage reference, 7.14-15 Line termination, PCB trace, 11.40 Linear circuit, 2.1-115 analog multiplier, 2.77-82 audio amplifier, 2.95-105 auto-zero amplifier, 2.119-113 buffer amplifier, 2.1-4 comparator, 2.65-76 differential amplifier, 2.31-32 digital isolation techniques, 2.39-48 gain block, 2.5-6 high speed clamping amplifier, 2.59-63 instrumentation amplifier, 2.2-29 isolation amplifier, 2.33-38 logarithmic amplifiers, 2.53-57 PGA, 2.87-94 RMS to DC converter, 2.83-86 Linear phase with equiripple error, filter design, 8.134 Linear phase filter: equiripple error of 0.05o, 8.38 design table, 8.49 equiripple error of 0.5o, 8.39 design table, 8.50 with equiripple error, 8.24 Linear PLL, 4.52 Linear settling time, DAC settling time, 6.167 Linear variable differential transformer, see: LVDT Linear voltage regulator: any CAP LDO regulators, 9.13 basic 5 V/1 A LDO controller, 9.21 basic three terminal regulator, circuit, 9.3 basics, 9.3-5 block diagram, 9.4 controller differences, 9.20-21 design: and AC performance, 9.15 and DC performance, 9.13-15 dropout voltage, 9.5 LDO architecture, 9.9-12 LDO thermal considerations, 9.17-19 pass device: circuits, 9.6 Linear voltage regulator (cont) comparisons, 9.6 selection, 9.22 tradeoffs, 9.5-9 pole splitting, 9.15-16 power management, 9.3-25 sensing resistors for LDO controllers, 9.23-25 thermal design, 9.23 Linear-in-dB Variable Gain Amplifier Provides True rms Power Measurements, 4.40 Linearity error: differential, 5.13, 6.117 integral, 5.13, 6.117 measurement methods, 5.14 Linearity tempco, definition, 6.123 Link trimming, 1.35 Liu, Bill Yang, 2.124 LM309, fixed 5 V/1 A three terminal regulator, schematic, 9.7 LM317, adjustable three terminal regulator, schematic, 9.8 Load cell, 3.93-95 Load, large capacitive, stable reference, circuit and graph, 7.18 Load sensitivity, voltage reference, 7.14 Local high frequency bypass/decoupling, 12.77-80 Local high frequency supply filter, decoupling, circuits, 12.78 Log amp, 2.53-57 basic: graph, 2.55 multi-stage: architecture, 4.21 response (unipolar), 4.22 detecting, graph, 2.55 diode/op amp, circuit, 2.56 negative input, 2.54 RF/IF circuit, 4.21-28 specifications, 4.24 transfer function, graph, 2.54 transistor/op amp, circuit, 2.56 true, graph, 2.55 waveform, log response, 4.26 Log linearity, log amp, 4.24 Log video, 2.56 graph, 2.55 Log-Ratio Amplifier Has Six-Decade Dynamic Range, 4.28 Logarithmic accuracy, definition, 6.123 Logarithmic amplifier, see: Log amp Logarithmic converter, or log amp, 2.53-57 Logarithmic video, 2.56 LOGDAC, 17-bit voltage-mode R-2R DAC, 6.3839 Logic, high-speed, 12.43-48 Logic high level, timing specification, 6.177 Index 25 BASIC LINEAR DESIGN Logic low level, timing specification, 6.177 Lohman, R.D., 6.80 Long-term drift, op amp, 1.33 Looney, Mark, 13.31 Loop, 12.9-11 Loop bandwidth, in VCO, 4.66 Loop filter, in PLL, 4.52 Loop gain: and frequency, filter response, 8.117 op amp, definition, 1.15 Low dropout, see: LDO Low ESR electrolytic capacitor, 2.24 Low inductance ceramic capacitor, 2.24 Low noise reference, high resolution converter, 7.19-20 Low-pass filter, 13.64 Low power: definition, 1.45 op amp, 1.25-26 Low voltage differential signaling, see: LVDS Low-side downconverter, 4.3 Low-side injection, 4.3 Low-pass filter, 8.2, 8.13 elliptical function, 8.58 integrator in modulator, 6.93 Low-pass filter (cont) peaking, vs. Q, 8.8 Low-pass prototype, 8.8 LPKF Laser & Electronics, 13.91, 13.92 Lucey, D.J., 3.28 LVDS, 12.49-50 current output technology, 6.32 driver and receiver, circuit, 12.49 high-performance ADC, outputs, 12.50 logic, 5.2 output levels, diagram, 6.31 reduced EMI, 12.50 specifications, 6.31 vs. ECL, 12.49 LVDT, 3.1-6 advantages, 3.2 definition, 3.1 diagram, 3.1 half-bridge, diagram, 3.5 improved, diagram, 3.2 signal conditioning circuit, 3.2 Lyne, Niall, 3.28, 11.51 M McClaning, Kevin, 6.175 McDaniel, Wharton, 9.26 Machine model: ESD, 11.12-13 worst-case, 11.13 Machine tools, using resolvers and synchros, 6.76 Macromodel, differences from micromodel, 13.4-5 Index 26 MagAMP, 6.59 3-bit folding ADC: block diagram, 6.61 input and residue waveforms, 6.61 advantages, 6.63 current-steering gain-of-two folding stage, diagram, 6.62 Magnetic field: lines, 12.72 shielding, 12.24 Magnetic flux density, vs. inductor current, graph, 9.66 Magnetics, 9.79 Magnetism, fundamental theory, 9.65 Magnetization current, 9.46 Magnetizing inductance, 9.46 Magnitude amplifier, 6.59 Mangelsdorf, Christopher W., 6.80, 6.175 Mark, W., 12.51 Marsh, Dick, 9.78, 10.27 Martin, Steve, 6.84 MASH sigma-delta ADC, block diagram, 6.102 MASH sigma-delta converter, 6.101-102 Matsuya, Y., 6.113 Matsuzawa, A., 6.175 Maximally flat delay with Chebyshev stopband filter, 8.27 MDAC, 6.17-20 as variable gain amplifier, 6.18 Meacham, L.A., 6.81, 7.63 Medical equipment, EMC, 11.24 Melsa, James L., 1.80, 1.81 Metal film resistor: burn-in period, 10.20 comparison chart, 8.112 table, 10.21 Metal foil resistor, table, 10.21 Metal-oxide varistor, EMI protection, 11.35 Metastability, 6.164 Metastable comparator output, error codes, diagram, 6.165 Metastable states, ADC, 6.163-166 Meyer, Robert G., 1.81 MF Electronics, 12.64 Mica capacitor: characteristics, 10.5 comparison chart, 8.113 Micromodel, differences from macromodel, 13.4-5 Microphonics, in capacitors, 8.111 Micropower: definition, 1.45 op amp, 1.25-26 Microprocessor temperature monitoring, 3.61- 63 Microstrip: PCB layout, for two pairs of LVDS signals, 12.50 PCB transmission line, 12.35, 12.38 Mid-scale glitch, DAC, graph, 6.169 Mierlo, S. van, 6.112 INDEX MIL-STD-461, 11.24 MIL-STD-883 Method 3015, Electrostatic Discharge Sensitivity Classification, 11.13, 11.17, 11.51 classifying and marking ICs, 11.17 Military equipment, EMC, 11.24 Miller capacitance, 2.57 Miller, Stewart E., 1.80 Mini-Mount prototyping board, 13.85 MINIDIP, sample guard layout, 12.17-18 Minimum pass-band attenuation, 8.2 Missing code, 6.120-122 subranging ADC, 6.53 Missing codes, in ADC, 5.16 Mixed-signal devices, grounding, 12.53 Mixed-signal grounding, confusion, 12.66 Mixed-signal IC, grounding and decoupling, using low digital currents, 12.60-61 Mixer: active, advantages, 4.7 high performance, diode-ring, 4.6 high level, 4.11 mixing process, 4.3 Mixer (cont.) RF/IF circuit, 4.3-10 switching: diagram, 4.4 ideal, inputs and output, diagram, 4.5 output spectrum, diagram, 4.6 Model accuracy, 13.3 Model verification, 13.3 Modulator: balanced, 4.11 doubly-balanced, 4.11 RF/IF circuit, 4.11 definition, 4.11 sign-changer, 4.11 Moghimi, Reza, 2.114 Moghimi, Rheza, 4.28 Molypermalloy, inductor core, 9.68 Monolithic ceramic (high K) capacitor: characteristics, 10.5 comparison chart, 8.113 Monte Carlo analysis, 13.64 Spice option, 13.16 Montrose, Mark, 12.52, 12.75 Morajkar, Rajeev, 2.124 Moreland, Carl, 6.83, 7.63 Moreland, Carl W., 6.83 Morrison, Ralph, 3.68, 11.50, 12.51, 12.75 Morrow, P., 2.124 MOSFET, manufacturers, 9.79 MOSFET switch, in voltage converter, 9.87 MOSFET transistor: in analog switch, 7.24 bilateral, voltage controlled resistance, 7.24 on resistance vs. signal voltage, graph, 7.24 Most significant bit, 5.2 Motchenbacher, C.D., 12.51, 12.75, 12.82 Motion, two-dimensional, 3.21-23 Motorola MC1496, mixer, 4.7 Motorola Semiconductor, 9.79, 9.80 MQE520-1880, Murata VCO, 4.67 Mu-metal, 12.24 Multitone SFDR, 6.142 Multilayer ceramic chip-cap, 9.74 Multiple feedback filter, 8.75-76 Band-pass: circuit, 8.118 design equations, 8.94 diagram, 8.76 high-pass, design equations, 8.93 implementation, circuit, 8.124 low-pass: design equations, 8.92 diagram, 8.75 Multiple feedback topology, 8.130 Multiple ground pins, PCB, 12.3 Multiplexer: analog, 7.23-50 Multiplexer (cont.) parasitic latchup, 7.47-50 settling time: calculator, 13.38 circuit and equations, 7.34 video, 7.42-44 Multiplexing, charge coupling, dynamic settling time transient, circuit, 7.32 Multiplication: four-quadrant operation, 2.77 using log amps, 4.14 Multiplier: analog, 4.13-20 definition, 2.77 block diagram, 2.77 definition, 4.13 input/output relationships, table, 2.77 mathematical, 4.4 in op amp feedback loop, uses, 2.82 quadrants, definition, 4.13 simple, circuit, 2.79 transconductance, basic, circuit diagram, 4.15 translinear, four-quadrant, circuit diagram, 4.17 using log amps, diagrams, 2.78 Multiplying DAC, 6.17-20 as variable gain amplifier, 6.18 Multistage filter, and RFI, 11.32 Multistage noise shaping, see: MASH Murakami, J., 6.112 Muranyi, A., 13.31 Murden, Frank, 6.82, 6.83, 7.63 Murphy, Troy, 13.92 Murray, Aengus, 3.27-28 Mutual inductance, 12.22-24 and coupling, within signal cabling, 12.24 Index 27 BASIC LINEAR DESIGN N Nagel, L.W., 13.31, 13.91 Narrow-band filter: as notch filter, 8.59 pole frequencies, 8.60 power line frequency (hum) elimination, 8.60 Nash, Eamon, 4.40 NDP6020P (Fairchild), 9.21-23 NDP6020P/NDB6020P P-Channel Logic Level Enhancement Mode Field Effect Transistor, 9.26 Neelands, Lewis J., 6.84 Negative feedback, op amp input, 2.76 Negative temperature coefficient, see: NTC Nielsen, Karsten, 2.124 Nelson, David A., 1.80 Neper frequency, 8.5 Newman, Eric, 4.40 Newton, A.R., 13.31, 13.91 Nguyen, Khiem, 6.113 Nicholas, Henry T., III, 4.73 Nishimura, Naoki, 2.125 Noise: in ADC with SHA, 6.131 bandwidth: and 3-dB bandwidth, Butterworth filter, table, 6.150 filter, 6.150 op amp, 1.48 calculation, 13.55 capacitive, 12.28-29 comparison, precision amps vs. chopper-stabilized amps, 2.123 conducted, 9.28 dominant source, input impedance, 1.50 equivalent input referred, 6.131-132 excess, resistor, 10.21-22 gain, 1.57 and closed-loop bandwidth, 1.68 op amp, 1.10, 1.14-15 circuits, 1.15 gate, 2.96 index, resistor, 10.22 log amp, 4.24 model, in-amp, 2.26 op amp, 1.47 peak-to-peak, 6.132 quantization, 6.37 radiated, 9.28 reduction pin, in buried zener reference, 7.15 referred to the input, 1.55 SHA, 7.54 sources: in-amp, 2.26-27 sum, 1.49 spectral density, function of frequency, 1.53 uncorrelated, 2.26 voltage reference, 7.15-16 Noise factor, 6.148-155 Index 28 Noise figure, 6.148-155 for ADC: from SNR, sampling rate, and input power, calculation, 6.152 using RF transformers, 6.154 cascaded, using Friis equation, 6.154 op amp, 1.48 Noise model: design considerations, 13.10-11 pole/zero cell impedance reduction, 13.10 Spice, components, circuit, 13.11 Noise/power ratio, 6.146-148 measurements, 6.146 theoretical maximum, for 8-bit to 16-bit ADCs, 6.148 Noise-free code resolution, 6.132-133 calculation from input-referred noise, 6.133 definition, 6.126 Noise-gain manipulation, op amp circuit, circuits, 13.36 Nonideal 3-bit ADC, transfer function, 5.15 Nonideal 3-bit DAC, transfer function, 5.15 Noninverting mode guard, circuit, 12.16 Nonmonotonic ADC: missing code, 5.17 graph, 6.120 Nonmonotonic DAC, 5.16, 6.119 Nonsampling ADC, input frequency limitations, 5.22 Nonlinear phase, filter, effects, 8.16-17 Nonlinearity: definition, 2.22 error, resistor, 10.16 SHA, 7.54 Norsworth, S.R., 2.124 North Carolina State University, 13.32 Notch filter, 8.2, 8.13 construction, 8.59 definition, 8.10-12 high-pass, 8.11 low-pass, 8.11 as narrow-band filter, 8.59 phase response, graph, 8.15 standard, 8.11 transfer function, 8.11 width vs. frequency, 8.12 NPO ceramic capacitor: characteristics, 10.5-6 comparison chart, 8.113 Nulling amplifier, 2.123 Nulling stage, 2.120 Number, 5.2 Numerically Controlled Oscillator, see: NCO Nyquist band, 6.90 Nyquist bandwidth, 4.41, 4.46-47, 5.25-26, 6.138, 6.151, 6.172 Nyquist conditions, 6.153 INDEX Nyquist criteria, 4.45, 5.24-26, 5.29 aliasing, 5.24 sampling frequency requirements, 5.24 Nyquist criterion, 6.91 Nyquist frequency, 4.45, 5.26, 6.36, 8.3, 8.121, 13.48, 13.52 Nyquist rate, 6.86 Nyquist zone, 5.25-26, 5.28, 5.29-31, 6.145146, 6.205, 13.50, 13.52 undersampling and frequency translation, 5.28-29 Nyquist, H., 5.32 Nyquist, Harry, mathematical basis of sampling, 5.24 O O’Brien, Paul, 4.73 Octave, definition, 1.30 Oersted, magnetic field strength, 9.65 Offset: DAC control, circuits, 1.37 servo control, circuits, 1.37 SHA, 7.54 Offset adjustment pins, circuit, 1.34 Offset binary code, 4-bit converter, 5.6-7 Offset code, 5.12 Offset current, specification, 1.40 Offset error, 5.13, 6.117 Offset step, definition, 6.173 Offset tempco, definition, 6.124 Offset voltage: aging, 1.33 correction, 1.34 minimizing, 1.41-42 model, in-amp, 2.23 op amp, 1.33 drift, 1.33 Ohm’s law, 8.5 and error in conductor, 12.6 Oliver, Bernard M., 6.83 Oliver, B.M., 6.175 Olshausen, Richard, 6.84 Omega Temperature Measurement Handbook, 3.64 Online tools and wizards: configuration assistants, 13.46-58 design wizards, 13.58-67 simple calculators, 13.33-45, 13.33-68 0.1 dB gain flatness, 1.67 1-band-pass notch filter: diagrams, 8.85 inverting and non-inverting, 8.85 1 dB compression point, definition, 1.63, 6.143-144 1/F corner frequency, 1.51 1/F noise: bandwidth, 1.51 op amp, 51-52 1N821, temperature-compensated zener reference, 7.3 Offse1 Voltage (cont) 1N829, temperature-compensated zener reference, 7.3 1N5712, Schottky diode, 2.63 1N5818, Schottky diode, low forward drop, 9.54 Ones complement code, 4-bit converter, 5.6, 5.8 Ones-density, 6.92 Op amp, 1.1-99 ac specifications: 1/f noise, 1.51-52 1dB compression point, 1.63 −3 dB small signal bandwidth, 1.66 absolute maximum rating, 1.76-78 bandwidth for 0.1dB flatness, 1.66-67 CFB frequency dependence, 1.68-69 CFB model, 1.17-28 channel separation, 1.75 CMRR, 1.71 current noise, 1.49 differential gain, 1.73-74 differential phase, 1.75 distortion, 1.60 ENOB, 1.63 full power bandwidth, 1.65-66 gain-bandwidth product, 1.67 intercept points, third and second order, 1.61-63 intermodulation distortion, 1.61 noise, 1.47 bandwidth, 1.47 figure, 1.48 flicker, 1.51-52 rms, 1.53-54 total, 1.49-51 total output, 1.55-59 phase margin, 1.70-71 phase reversal, 1.75 popcorn noise, 1.52-53 PSRR, 1.72-73 rise time and fall time, 1.70 settling time, 1.69-70 SFDR, 1.64 slew rate, 1.64-65 SNR, 1.63 THD + N, 1.60 THD, 1.60 voltage noise, 1.47 basic operation, 1.4-5 capacitive load: circuit stabilizing, 13.35-36 noise-gain manipulation, 13.36 out-of-loop compensation, 13.36 choices, 1.95-99 determining parameters, 1.95 prioritizing parameters, 1.96 selecting the part, 1.96-99 comparator, 2.71 CMOS driver, 2.74 driving ECL logic, circuit, 2.73 Index 29 BASIC LINEAR DESIGN Op amp (c0nt) driving TTL or CMOS logic, circuit, 2.73 data sheets, 1.83-94 DC specifications, 1.30-46 compensating for bias current, 1.39-40 correction for offset voltage, 1.34 differential input voltage, 1.44 DigiTrim technology, 1.34-35 drift with time, 1.33 external trim, 1.36-37 input bias current, 1.38 input capacitance, 1.43 input common mode voltage range, 1.43 input impedance, 1.42-43 input offset current, 1.38 offset voltage, 1.33 drift, 1.33 open-loop gain, 1.30-32 open-loop transresistance, 1.32-33 output current, 1.47-48 output voltage swing, 1.45 quiescent current, 1.44-45 short circuit current, 1.47-48 supply voltages, 1.44 total offset error calculation, 1.41-42 error budget calculator, screen, 13.40 filter element, limitations, 8.114-115 gain, definition, 1.10 ideal, attributes, 1.4 impedance, and filter response, 8.117 input structure, protection, circuit, 2.75 inverting: circuit, 1.5 gain, 1.7 negative feedback, 1.8 noninverting: circuit, 1.6 gain, 1.8 open-loop gain, 1.30-32 open-loop response, 13.64 operation, 1.3-28 overvoltage, 11.1 parameters, 1.95-96 processes, bipolar transistors, 1.26 selection, 1.96-99 settling time, definition, 1.69-70 single-supply, input overvoltage and output voltage phase reversal, protection, circuit, 11.7 specifications, 1.29-82 ac, 1.47-78 dc, 1.30-46 topology dependent, 1.29 stability tool, screen, 13.37 standard symbol, 1.3 standard topology, 1.20 VFB model, 1.3-16 characteristics, 1.3-4 voltage phase reversal, 11.4 Index 30 Op Amps Combine Superb DC Precision and Fast Settling, 1.80 OP07, bias-compensated op amp, 2.75 OP90: DC precision amplifier: Bode plot, 8.120 Q-enhancement effects, 8.119 OP177: CMRR, graph, 1.71 Load Cell amplifier, 3.96 Diagram, 3.96 Strain gage sensor, 3.95 Diagram, 3.95 Single supply load cell amplifier, 3.97 Diagram, 3.97 precision op amp, 10.19 OP213: low-drift low-noise amplifier, 2.91 noise in 0.1 Hz to 10 Hz bandwidth: graph, 1.52 peak-to-peak, 1.54 Single supply load cell amplifier, 3.97 Diagram, 3.97 OP284, dual IC op amp, 2.18 OP291, rail-to-rail input/output op amp, circuit, 11.7 OP297, dual IC op amp, 2.18 OPX91 family: input stage, circuit, 11.5 rail-to-rail input/output op amp, 11.5 overvoltage protection, graph, 11.6 OP1177/OP2177/OP4177, precision op amp, 1.83-84, 1.93 Open-loop modulation, block diagram, 4.71 Open-loop nonlinearity, graph, 1.31 Open-loop gain, 6.62 Bode plot, 1.9 CFB op amp, graph, 1.32 graph, 1.30 op amp, 1.9, 1.30-32 Openings, EMI, 11.29 Optical measurements, 5.2 Optocoupler: architecture, 2.40 for digital isolation, 2.39-40 typical, 2.39 Optoelectronics Data Book, 3.68 Optoisolator, 2.33, 3.56 see also: Optocoupler Order, filter, 8.2 Ordering guide: data sheet, example, 6.190 for op amp, 1.92 OS-CON, electrolytic capacitor, 9.75 OS-CON Aluminum Electrolytic Capacitor 93/94 Technical Book, 9.78, 10.27 OS-CON electrolytic capacitor, 9.21, 9.72 characteristics, 10.4-5 impedance characteristics, 10.7 INDEX Oscillation, op amp, 1.11 Oscillator system: long-term frequency stability, 4.60 noise, 4.60 phase noise, 4.60 short-term stability, 4.60 Ott, Henry, 10.27, 11.50 Ott, Henry W., 3.68, 12.51, 12.75, 12.82 Out of range message, 13.39, 13.43, 13.55 Out-of-band region, spectrum, 6.139 Out-of-band SFDR, 6.139 Output current, op amp, 1.45-46 Output impedance, load sensitivity, 7.14 Output latch, effects, 2.70 Output leakage current, definition, 6.126 Output propagation delay, definition, 6.126 Output ripple current, 9.76 Output stage, op amp, 1.22 Output voltage ripple, 9.70, 9.82 Output voltage tolerance, definition, 6.126 Overdrive, effects on op amp input, 1.27-28 Overlap bits, 6.54 Overload, definition, 6.126 Overrange, overvoltage, definition, 6.126 Oversampling, 5.27, 6.90, 6.205 ADC noise figure, 6.153 filter requirements, 6.33 graphs, 6.34 ratio, 6.90 Overshoot, 1.65 filter, 8.19 Overvoltage: amplifier input stage, 11.1-4 analog circuit, 11.1-51 effects, 11.1-9, 11.3 op amp, 1.76 protection, 1.77 worst-case condition, 11.4 Overvoltage overrange, definition, 6.126 Overvoltage recovery time: definition, 6.126, 6.163 graph, 6.163 P Package dimension drawing, op amp, 1.94 PADS Software, 13.91, 13.92 Pallas-Areny, Ramon, 3.27, 3.64 Palmer, Wyn, 1.80 Panasonic, 9.79 Parallel ADCs, 6.50-51 Parametric search, data sheet, example, 6.211 Parasitic capacitance, 12.30-32 analog switch, 7.37 filter, 8.111 op amp, 1.7 Parasitic component, CMOS switch, 7.28 Parasitic coupling, 13.89 Parasitic effect, 2.123 in inductor, 12.24-25 Parasitic inductance, 11.26 Parasitic latch-up, 1.27 Parasitic SCR, in CMOS switch, 7.47 Parasitic thermocouple, 10.18 Parasitics: capacitor, 10.10, 10.13-14 PCB, 13.14-16 pin socket, 13.88 Partitioning, PCB, 12.3-4 Parzefall, F., 6.113 Pass device: comparisons, 9.6 Darlington NPN, 9.6 PMOS, 9.6 PNP/NPN, 9.6 single NPN, 9.6 single PNP, 9.6 Pass-band filter, 8.1-2 Pass-band ripple, 8.2 Passive component, 10.1-28 capacitor, 10.3-14 EMI protection, 11.25-29 filter construction: circuit analysis, 8.109-110 parasitic capacitance, 8.11 problems, 8.109-113 temperature effects, 8.110 inductor, 10.23-27 potentiometer, 10.15-22 resistor, 10.15-22 Passive filter: impedances, 8.66 normalized implementation, circuit, 8.122 Passive LC section, passive blocks, 8.65-66 Pattavina, Jeffrey S., 12.51, 12.82 PCB: copper, resistance, calculation, 12.5-6 decoupling, 12.77-82 design: considerations, 12.1-96 and EMI, 11.41 dynamic effects, 12.19-20 embedding, 11.39 EMI protection, 11.37-42 grounding, 12.53-75 guard, implementing, 12.17 guard pattern: using MINIDIP package, 12.18 using SOIC package, 12.18-19 hook, 12.20 hygroscopicity, 12.1 impedance, calculation, 11.41 inductance, 12.21-34 layout, analog/digital circuit partitioning, layout, 12.4 multilayer, embedding traces, 12.42 partitioning, 12.3-4 for EMI protection, 11.39 static effects, 12.15-17 Index 31 BASIC LINEAR DESIGN PCB (cont) thermal management, 12.83-96 trace spacing, diagram, 6.32 traces, 12.5-52 termination, rule, 12.43 track length, maximum, calculation, 12.44 PCM, voiceband digitization, 6.37 Peak clipping, 6.86 Peak detector, using SHA, 7.51 Peak glitch, 6.168 Peak spurious spectral content, 6.138 Peak-to-peak noise, specification, 1.54 Pease, Bob, 13.83 Pease, Robert A., 13.91, 13.92 Pederson, D.O., 13.31, 13.91 Pedestal error, SHA specification, 7.54 Performance graph, data sheet, example, 6.194-197 Permeability, ferromagnetic core, 9.65 Peterson, E., 6.81, 7.63 Peterson, J., 6.81 PFD chargepump, output current pulses, 4.69 PGA, 2.87-94 alternate configuration: circuit, 2.89 minimizing on-resistance, circuit, 7.39 caveats, circuit, 2.88 definition, 2.87 diagram, 2.87 noninverting circuit, 2.92 poor design, using CMOS switches, circuit, 7.39 single-supply in-amp, circuit, 2.93 very low noise, circuit, 2.90 within sigma-delta ADC, circuit, 2.94 Phase accumulator, 4.42 Phase detector, in PLL, 4.52 Phase-locked loop, see: PLL Phase margin: op amp, 1.13, 1.70-71 op amp circuit, 13.35 Phase noise: definition, 4.67 free-running and PLL-connected VCO, 4.66 measurement, 4.67-69 with spectrum analyzer, 4.68 in oscillator, 4.60 phasor representation, 4.61 in VCO, 4.61 closing the loop, 4.64-66 minimizing, 4.63 Phase response: filters, equations, 8.14-16 and inadequate decoupling, 12.79 notch filter, graph, 8.15 vs. frequency, graph, 8.15 Phase reversal: with JFET input amplifier, 11.4 op amp, 1.25 Index 32 Phase reversal (cont) and input common mode, 1.75 Phase shift, filter, 8.12 Phase-frequency detector, in PLL synthesizer, 4.53 Phase-Locked Loop Design Fundamentals, 4.73 Photodiode 1991 Catalog, 3.68 Photodiode, 1.17 error budget analysis tool, 13.55 screen, 13.56-57 Photodiode amp, input capacitance, 1.43 Photodiode wizard, 13.58-60 amplifier solution, 13.59-60 parametric values, 13.58 screens, 13.58-60 Photolithography, 6.47 Photosite, in CCD, 3.65 Pierce, J.R., 6.175 Pilot tube, 3.95-96 Pin description, data sheet, example, 6.191- 192 Pin socket, 12.58, 13.87-88 diagram, 13.88 Ping-pong DAC, 6.29-30 Pipeline delay, 6.56 Pipelined ADC, 6.52-57 basic, identical stages, 6.56 clock issues, 6.55 Pipelined architecture, 6.54 Pipelined subranging ADC, timing diagram, 6.55 Pixel, in CCD, 3.65 Plassche, R.J. van de, 6.112 Plassche, Rudy J. van de, 6.83 Plated-through holes, 13.70 none in milled PCB prototyping board, 13.87 PLL: basic model, 4.52, 4.69-70 charge pump leakage current, RF/IF circuit, 4.70-71 closing the loop, RF/IF circuit, 4.64-66 components for loop gain, 4.52 definition, 4.51 feedback counter N, RF/IF circuit, 4.56- 58 fractional-N synthesizer, RF/IF circuit, 4.59-60 internal grounding DSPs, 12.69 Leeson’s equation, RF/IF circuit, 4.62-63 noise in oscillator system, RF/IF circuit, 4.60 phase noise, in voltage-controlledoscillator, RF/IF circuit, 4.61 phase noise measurement, RF/IF circuit, 4.67-69 reference counter, RF/IF circuit, 4.56 reference spur, 4.69-70 reference spurs, RF/IF circuit, 4.69-70 RF/IF circuit, 4.51-73, 4.51-74 synthesizer basics, RF/IF circuit, 4.53- 56 PLL prototype, using Solder-Mount, 13.85 PLL synthesizer: basic building blocks, 4.53-56 fractional-N, 4.59-60 INDEX PLL-phase-noise contributor, 4.64 overall, equations, 4.65 PNP input stage, 1.21 Pole splitting, 9.15-16 Polycarbonate capacitor, 9.73 characteristics, 10.5 comparison chart, 8.113 Polyester capacitor: characteristics, 10.5 comparison chart, 8.113 Polyester film capacitor, 9.72 Polypropylene capacitor: characteristics, 10.5 comparison chart, 8.113 Polystyrene capacitor: characteristics, 10.5 comparison chart, 8.113 Popcorn noise, 1.52-53 Popping, 2.95 Positive-emitter-coupled-logic, 5.2 Positive-true, definition, 6.125 Potentiometer, 5.2, 10.22 trimming, 10.22 Power dissipation, vs. percent full scale, graph, 1.91 Power dissipation calculator, 13.33-34 screen, 13.34 Power line: disturbances, EMI, 11.35 filter, schematic, 11.36 Power loss, in switched capacitor voltage converter, 9.90-91 Power management, 9.1-96 circuit components, 9.1 definition, 9.1 linear voltage regulator, 9.3-25 switch mode regulator, 9.27-80 switched capacitor voltage converter, 9.81-96 Power MOSFET switch: boost converter, circuit, 9.56 buck converter, circuit, 9.56 Power supply: filtering and signal line snubbing, EMI protection, 11.38 RFI coupling, 11.31 separate for analog and digital circuits, 12.63 Power supply decoupling, 1.73 Power-down, 6.42 Power-saving operation, 9.51 Power-supply rejection ratio, see: PSRR Power-supply sensitivity, definition, 6.127 Precision absolute value circuit, 3.3 Precision ADC controller/evaluation board, functional block diagram, 13.79 Precision single-supply composite in-amp, 2.15-17 capacitor, 2.17 Precision single-supply composite in-amp (cont) performance summary, 2.16 rail-to-rail output, circuit, 2.15 Precision voltage reference, 7.1-2 Prescaler, 4.56-57 dual-modulus, 4.57-58 Pressman, Abraham I., 9.78 Printed circuit board, see: PCB Process control equipment, EMC, 11.24-25 Process gain, ADC noise figure, 6.153 Processing gain, Fast Fourier transform, 6.130 Programmable gain amplifier, see: PGA Propagation delay: comparator, 2.65 graph, 2.66 symmetric stripline, calculation, 12.41 timing specification, 6.178 Protective packaging, for ESD-sensitive devices, 11.19 Prototyping, 13.3 deadbug, 13.82-84 breadboard illustration, 13.83 pre-drilled copper-clad printed board, 13.84 full board, 13.89 limitations, 13.88-89 milled PCB, 13.86-87 illustration, 13.86-87 solder-mount, 13.84-86 systems, 13.82-87 PSpice, 13.1 Spice support, 13.17 PSpice ferrite model, 10.25 PSpice Simulation Software, 13.92 PSRR: of ADC, 12.77 definition, 6.126 op amp, definition, 1.72-73 PulSAR, charge redistribution SAR ADC, 6.48 Pulse burst modulation, 9.48 disadvantages, 9.53 gated oscillator control, 9.51-54 Pulse code modulation, see: PCM Pulse Engineering, 9.79 Pulse skipping, 9.48 Pulse width modulation, 9.31, 9.47 current feedback, circuit, 9.50 voltage feedforward, 9.49 voltage-mode control, 9.48-49 circuit, 9.49 Pulse-frequency modulation, see: Pulse burst modulation Pulsewidth high, timing specification, 6.178 Pulsewidth low, timing specification, 6.178 Pump capacitor, continuous switching, circuit, 9.86 Index 33 BASIC LINEAR DESIGN Q Q: definition, 8.7 of inductor, 12.25 in tuned circuit, 12.25 variation vs. DAC control word, graph, 8.139 Q enhancement, 8.117-120 effects, 8.119 graph, 8.118 Q peaking, 8.117-120 Quadrature amplitude modulation, 4.2 Quality factor, see: Q Quantization: error, 5.12 size of least significant bit, 5.11 uncertainty, 5.6, 5.12 Quantization error, 6.90 Quantization noise, 6.37, 6.90 and sampling clock jitter, SNR, DNL, sampling clock jitter, and input noise, graph, 6.160 Quantization noise shaping, 6.90 Quiescent current, op amp, 1.44-45 R R-2R DAC, 6.38 R-2R ladder, 6.14-18 4-bit network, diagram, 6.14 current mode DAC, 6.16 voltage mode DAC, 6.16 Rabbits, 6.164 Radiated emission: EMI regulation, 11.23 limits for commercial equipment, table, 11.24 Radiation, EMI, 11.27, 11.37 Ragazzini, John R., 1.79 Rail-rail input stage op amp, model, 13.9 Rail-rail output stage op amp, model, 13.9 Rail-to-rail: configuration: definition, 1.25 op amp, 1.22 op amp, in LDO references, circuit, 7.17 voltage, 1.43, 1.45 Rainey, Paul M., 6.80 Ramachandran, R., 6.82 Ramp run-up ADC, 6.65-66 diagram, 6.66 Randall, Robert H., 1.79 Random noise, error generation, 6.163 Ratiometric, definition, 6.127 RDC: functional diagram, 3.10-11, 6.78 see also: Resolver-to-digital converter Reactance error, resistor, 10.17 Reay, Richard J., 9.26 Receiver, 2.101 Index 34 Recirculating ADC, 7-bit 9 MSPS pipelined architecture, 6.57 Recirculating subranging ADC, 6.56 Reconstruction filter, 6.35 Rectification, EMI, sensitive circuits, 11.29 Rectifier, full wave, 3.3 Redundant bits, 6.54 Reeves, A.H., 6.64 Reeves, Alec Harley, 6.81, 7.63 REF195. single supply load cell amplifier, 3.97 Diagram, 3.97 Reference bypass capacitor, 7.17, 7.19 Reference counter, in PLL synthesizer, 4.53, 4.56 Reference noise bandwidth, 7.15 for various systems, table, 7.16 Reference spur, 4.69-70 on output spectrum, 4.70 Referred to the input, see: RTI Reflection, shielding loss, 11.43-45 Register description, data sheet, example, 6.201 Regulated output switched capacitor, voltage converter, 9.92-95 Regulation, line sensitivity, 7.14-15 Reichenbacher, P., 12.51 Reine, Steve, 13.92 Relative accuracy, definition, 6.123 Remote sensing, current output temperature sensor, 3.33 Rempfer, William C., 12.51, 12.75 Residue output, 6.58 Resistance temperature detector, 3.47-51 Resistance temperature device, see: RTD Resistor, 10.15-22 aging, 10.20 basics, 10.15-17 as circuit error source, 10.15 comparison, table, 8.112, 10.21 discrete: comparison chart, 8.112 table, 10.21 excess noise, 10.21-22 failure mechanisms, 10.20 metal types, 10.16 network: comparison chart, 8.112 table, 10.21 noise, 1.55 nonlinearity error, 10.16 op amp, 1.9 orientation, and thermocouple voltage, 10.19-20 parasitics, 10.17-18 inductance, 8.112 types, 10.17-18 passive filter component, problems, 8.109-113 power dissipation, temperature-related gain errors, 10.16 standard value, effects, graph, 8.126 INDEX Resistance (cont) temperature change as error source, 10.15 temperature-related error, minimizing, 10.17 thermocouple formation, 10.19 thermoelectric effects, 10.18-20 value ranges, 8.110 voltage sensitivity, 10.20 wirewound, disadvantages, 2.68 Resolution error, 13.39, 13.41 Resolver, 3.9-12, 5.2 diagram, 3.9, 6.76 modern, brushless, 3.9 uses, 3.9 Resolver-to-digital converter, 6.76-79 see also: RDC Resonant circuit, from power line decoupling, 12.80 Response curves, filters, 8.31-41 RF/IF circuit, 4.1-74 analog multiplier, 4.13-20 digitally controlled variable gain amplifier, 4.38-39 frequency synthesis, 4.41-50 aliasing in DDS system, 4.45-46 amplitude modulation in DDS system, 4.47 DDS, 4.41-44 DDS system as ADC clock driver, 4.46- 47 SPDR considerations, 4.47-49 logarithmic amplifier, 4.21-28 mixer, 4.3-10 basic operation, 4.8-9 diode-ring, 4.6-8 ideal, 4.3-6 modulator, 4.11 PLLs, 4.51-74 charge pump leakage currents, 4.70-71 closing the loop, 4.64-66 feedback counter N, 4.56-58 fractional-N synthesizer, 4.59-60 Leeson's equation, 4.62-63 noise in oscillator system, 4.60 phase noise measurement, 4.67-69 phase noise in voltage-controlledoscillator, 4.61 reference counter, 4.56 reference spurs, 4.69-70 synthesizer basic building blocks, 4.53-56 True Power detectors, 4.29-31 variable gain amplifier, 4.33 voltage controlled amplifier, 4.33-34 X-amp, 4.35-38 RFI: analog circuit sensitivity, 11.31 and circuitry, 11.30-33 coupling, 11.31 RFI (cont) protection techniques, summary, 11.34 sensitivity, terminology, 11.30 RGB signal, digitizing, with 4:1 mux, circuit, 7.44 Rich, A., 11.50 Rich, Alan, 12.51, 12.75 Ringing, 1.65, 7.18, 9.34, 9.39, 12.32, 12.80-81, 13.15, 13.35 filter, 8.19 Ripple, 1.66 Ripple current: electrolytic capacitor, 9.74-75 input, 9.77 output, 9.76 Rise time: graph, 6.177 op amp, 1.70 timing specification, 6.177 RLC circuit, diagram, 8.6 RMS: definition, 2.83 explicit computation, circuit, 2.83 noise: op amp, 1.53-54 vs. peak to peak voltage, comparison chart, 1.53 wideband measurement, circuit, 2.84 RMS-to-dc converter, 2.83-86 Roberge, J.K., 1.81 Robotics, using resolvers and synchros, 6.76 Roche, P.J., 3.28 Root-mean-square, see: RMS Root-sum-of-squares, total noise, 1.49 Rosenbaum, R., 13.31 Rotary variable differential transformer, 3.5 Rotational sensor, 3.7 Rouse Ball, W.W., 6.81 RTD, 3.47-51, 3.96 current excitation warning, 3.48 definition, 3.47 interfaced to high resolution ADC, diagram, 3.50 Kelvin connection, 3.48-49 resistance vs. temperature, 3.47 temperature sensor, characteristics, 3.30 voltage drop error, 3.48 RTI CMR, calculation, 2.24 Ruscak, Steve, 6.175 Russell, Frederick A., 1.79 Ruthroff transformer, 4.18 Ruthroff, C.L., 2.114, 4.10 Rutten, Ivo W.J.M., 6.83 RVDT, 3.5 S S Series Surface Mount Current Sensing Resistors, 9.26 Index 35 BASIC LINEAR DESIGN S-plane: filter, 8.5-7 pole and zero plot, 8.6 Saber model, advantage, 13.17 SAE Standard J113, 11.25 SAE Standard J551, 11.25 Sallen-Key filter, 8.72-74, 8.85, 13.63 Band-pass: design equations, 8.91 diagram, 8.73 High-pass: design equations, 8.90 diagram, 8.73 implementation, circuit, 8.123, 8.126 limitations, 8.114-117 low-pass, 13.66-67 design equations, 8.89 diagram, 8.72 notch, 8.74 Q-sensitive, 8.72 voltage control voltage source, 8.72 Sallen-Key topology, highpass transformation, 8.128-129 Sallen, R.P., 8.72, 8.143 Sample mode, 6.48 Sample-and-hold amplifier, see: SHA Sample-to-hold offset, definition, 6.173 Sample-to-sample variation, in CCD, 3.66 Sampled data system: baseband antialiasing filters, 5.26-28 block diagram, 5.21 coding and quantizing, 5.1-20 bipolar codes, 5.6-10 complimentary codes, 5.10 DAC and ADC static transfer functions, 5.11-19 DC errors, 5.11-19 unipolar codes, 5.4-6 fundamentals, 5.1-32 Nyquist criteria, 5.24-26 sampling theory, 5.21-32 SHA, 5.22-23 undersampling, 5.28-29 Sampling, and bandwidth, 5.29 Sampling ADC, 5.22 Sampling aperture, 6.156-159 Sampling clock: distribution, ground planes, circuit, 12.65 grounding, 12.64 PCB, 12.3 Sampling clock jitter: and aperture jitter: graph, 6.158 SNR, graph, 6.159 effect on ADC SNR, 12.64 effect on SNR, 7.57 and SNR, quantization noise, DNL, and input noise, graph, 6.160 Index 36 Sampling theory, 5.21-32 Samueli, Henry, 4.73 Sanyo Corporation, 9.79 SAR ADC, 6.42, 6.45-47 algorithm, 6.49 basic: diagram, 6.45 timing diagram, 6.46 missing codes, 6.121 Sauerwald, Mark, 12.51, 12.75, 12.82 Scaled references, voltage, 7.16-17 Scannell, J.R., 3.28 Schaevitz, Herman, 3.27 Schelleng, John C., 6.81 Schindler, H.R., 6.80 Schmidt, Ernest D.D., 3.27 Schmitt trigger circuit, 2.41 Schottky diode, 1.27, 1.77, 2.29, 6.30, 7.49-50, 9.54-55, 9.57, 9.93-94, 11.5, 11.8-9, 12.69 manufacturers, 9.80 Schottky noise, 1.49 Schottky-barrier diode, 4.6 Schreier, R., 2.127 Schreier, Richard, 6.114 Schultz, Donald G., 1.80, 1.81 Schwartz, Tom, 1.79 Scott-T transformer, 6.77 SCR, 1.76 Sears, R.W., 5.20, 6.80 Second and third-order intercept points, definition, 6.144 Second-order allpass filter: design equations, 8.107 diagram, 8.87 Second-order intercept point, distortion, 1.61-63 Second-order noise, model, 1.56 Second-order system: noise gain, 1.57 noise and signal gain, graph, 1.58 Seebeck coefficient, 3.47 thermocouple, 3.37, 3.41 Segmentation, 6.20 Segmented current-output DAC: 6-bit, based on 3-bit thermometer DACs, diagram, 6.21 resistor and current-source based, diagrams, 6.20 Segmented DAC, 6.20-22 Segmented string DAC, 6.5-7 with cascaded Kelvin DACs, 6.20 unbuffered, diagram, 6.7 Segmented voltage-output DAC, diagrams, 6.6 Seitzer, Dieter, 6.83 Selection guide: for data converter, 6.207 data sheet, example, 6.210 Selection tree, op amp, 1.97-98 INDEX Semiconductor: junction temperature, 1.89 temperature sensor, 3.31-33 advantages, 3.31 basic relationships, diagram, 3.31 characteristics, 3.30 Sense connection, and feedback, 12.7 Sensor, 3.1-102 accelerometer, 3.15-18 fault, 11.1 Hall effect magnetic, 3.6-8 Inductosyn, 3.13-14 positional, 3.1-28 precision, and cable shielding, 11.49 resolver, 3.9-12 semiconductor temperature, 3.31-33 synchro, 3.9-12 temperature, 3.29-64 current and voltage output, 3.34-35 current-out, 3.33 digital output, 3.56-58 nonlinear transfer functions, 3.29 Separate analog and digital grounds, 12.55 SEPIC converter, circuit, 9.44 Serial timing diagram, DAC, example, 6.200 Serial-Gray converter, 6.59 Setpoint controller, 3.58-61 resistor, equation, 3.58 Settling time, 6.161-162 ADC, feedthrough, 6.174 critical in multiplexed applications, diagram, 6.162 DAC, 6.167-168 definition, 6.167 graph, 6.167 function of time constant, various resolutions, table, 6.162 graph, 1.69 multiplexer, circuit and equations, 7.34 op amp, definition, 1.69-70 PCB, dielectric absorption, 12.20 SHA, 7.54 Settling time calculator, 13.38 Setup time, timing specification, 6.177 74ACTQ240, Fairchild part, 12.46 74FCT3807/ 74FCT3807A, IDT part, 12.46 SFDR, 6.138-140 DAC, 6.170-172 test setup, 6.171 definition, 1.64 graph, 6.139 in-band, 6.139 out-of-band, 6.139 RF/IF circuit, 4.47-49 SHA, 5.22-23 basic circuit, 7.52 basic operation, 7.52-53 bias current compensation, 1.40 capacitor, 7.52 SHA (cont) circuit, 7.51-63 internal timing, 7.55 feedthrough, definition, 6.174 function, 5.22-23 hold mode, 7.60 specification, 7.58-59 internal, for IC ADC, 7.59-62 overvoltage, 11.1 in SAR ADC, 6.45-46 specifications, 7.53-62 track mode, 7.60 specifications, 7.53-54 waveforms, graph, 7.55 waveforms and definitions, 6.156 Shannon, C.E., 5.32, 6.175 Shannon, Claude, 5.24 Shannon, Claude E., 6.83 SHARC DSP, output rise times and fall times, graph, 12.43 Sheingold, Dan, 1.79, 1.80, 2.114, 2.115, 3.27, 3.64, 4.20, 4.28, 5.20, 6.84, 6.88, 6.176, 7.21 Shielding: cables, 11.47-49 connection, low frequency threats, 11.47 effectiveness: calculation, 11.46 compromised by openings, 11.43 materials, skin depths and impedance, table, 11.45 mechanism, 11.42-46 reflection and absorption, 11.42 Shock, immunity, 3.25-26 Short-circuit current, op amp, 1.45-46 Short Form Designers Guide, 1.96, 6.207 Shunt, voltage reference, 7.2-3 Sigma-delta, vs. delta-sigma, 6.88-89 Sigma-delta ADC: basics, 6.90-96 decimation, graph, 6.91 digital filtering, graph, 6.91 first-order, circuit, 6.92 grounding, 12.67 high speed clock, grounding, 12.54 internal digital filter, 7.17 multibit, circuit, 6.87 noise shaping, graph, 6.91 oversampling, graph, 6.91 as oversampling converter, 5.27-28 second-order, circuit, 6.95 single bit, circuit, 6.87 switched capacitor input, reference load, circuit, 7.18 Sigma-delta converter, 6.85-114 Band-pass, 6.108-109 high level of user programmability, 6.11 high resolution measurement, 6.103-107 historical perspective, 6.85-89 MASH, 6.101-102 Index 37 BASIC LINEAR DESIGN Sigma-delta converter (cont) multibit, 6.98-100 block diagram, 6.98 Sigma-delta DAC, 6.22, 6.109-110 multibit, diagram, 6.109 single-bit, diagram, 6.109 Sigma-delta modulator: Class-D audio power amplifier, 2.107-08 first-order, idling patterns, 6.97 higher order loops, 6.98 output, repetitive bit pattern, 6.97 oversampling vs. SNR, graph, 6.96 quantization noise, 6.96 second-order, idling patterns, 6.97 shape quantization noise, graph, 6.95 simplified frequency domain linearized model, 6.94 waveforms, 6.93 Sign magnitude code, 4-bit converter, 5.6, 5.9 Sign magnitude converter, 5.13 Signal, phase, filter effect, 8.3 Signal gain, op amp, 1.14 Signal input, RFI coupling, 11.31 Signal lead, voltage drop, 12.7 Signal output, RFI coupling, 11.31 Signal return current, 12.7-9 Signal to noise ratio, see: SNR Signal trace routing, nonideal and improved, diagrams, 12.22 Signal-to-noise ratio, see: SNR Signal-to-noise-and-distortion ratio, see: SINAD Signore, B.P. Del, 6.113 Silicon controlled rectifier, see: SCR Silicon Detector Corporation, 3.68 Silicon junction diode, 4.6 Silicon switch, in PGA, 2.87 Siliconix Inc., 9.79 Simple calculators, 13.33-68 Simpson, Chester, 9.26 Simulation, 13.3-32 ADIsimADC, 13.18-25 ADIsimPLL, 13.26-29 ADSpice op amp macromodels, 13.5-13 IBIS model, 13.17 macromodel vs. micromodel, 13.4-5 model familiarity, 13.14 model support, 13.17 not breadboarding replacement, 13.13 parasitics, 13.13 PCB parasitics, 13.14-16 SABER model, 13.17 Spice, 13.3 Spice support, 13.17 Simultaneous sampling system, using SHA, 7.51 SINAD, definition, 6.136-137 Sinc (sin(x)/x) curve, normalized, graph, 6.36 Sine wave, aliased, 5.24-25 Index 38 Singer, Larry, 6.175 Single-pole filter: High-pass, design equations, 8.88 Low-pass, design equations, 8.88 Single-pole RC: active blocks, 8.64 construction, 8.64 Single-pole response, op amp, 1.11-12 Single-supply: biasing: circuit, 1.23 headroom issues, 1.24 op amp, 1.20-22 circuit design, 1.23-24 Single-channel digital isolator, 2.42-46 Single-Chip Direct Digital Synthesis vs. the Analog PLL, 4.50 Single-ended current-to-voltage conversion, 6.27 Single-ended primary inductance (SEPIC) converter, circuit, 9.44 Sin(x)/x (sinc), 6.36 60 Hz notch filter, 8.141-142 response, graph, 8.142 60 Hz twin-T notch filter, circuit, 8.141 68HC11, microcontroller, 3.57 Skin effect, 12.33-34, 12.73 PCB conductor, diagrams, 12.33-34 Slattery, B., 11.50 Slattery, W., 8.144 Sleep, 6.42 Sleep operation, 9.51 Slew rate: CFB op amp, 1.19 converter, 13.23 and full-power bandwidth, 1.66 op amp, 8.127 definition, 1.64-65 SHA, 7.54 Slewing time, DAC settling time, 6.167 Slope clipping, 6.86 Slot antenna, EMI, 11.29 Slot and board radiation, EMI, 11.27 Small signal bandwidth, ADC, 6.137 Smith, B.D., 6.37, 6.59, 6.81, 6.82 Smith, Lewis, 1.80 Smith, Paul, 7.84 Snelgrove, M., 6.114 SNR: DAC, 6.170-172 measurement, analog spectrum analyzer, 6.172 definition, 1.63, 6.136-137 and sampling clock jitter, quantization noise, DNL, and input noise, graph, 6.160 SNR-without-harmonics, 6.137 SNR/THD/SINAD calculator, 13.34-35 screen, 13.35 Snubber, 9.35, 9.39 INDEX Soakage, 10.11 Socket, 13.87-88 Soderquist, Donn, 1.80 Sodini, C.G., 6.113 SOIC, sample guard layout, 12.17-19 Solder-Mount prototyping board, 13.85 advantages, 13.85 illustration, 13.85 Solomon, Jim, 9.26 Solutions bulletin, front page, sample, 6.208 Sonet/SDH OC-48 with Forward Error Correction, using AD8152, 7.46 SOT23, amp footprint, 12.17 Source termination: bidirectional transmission between SHARC DSPs, 12.48 microstrip transmission lines, 12.46 Span, definition, 6.125 Sparkle codes: ADC, 6.163-166 definition, 6.164 Specification page, data sheet, example, 6.183-184 Specification tables, for op amp, 1.83-89 Specifications, defining, 6.115-116 Spectrum analyzer: measuring DAC SNR, 6.172 output, 4.68 for phase noise measurement, 4.68 Spice, 13.3 definition, 13.1 SPICE2-G, 13.1 Sprague 595D-series, electrolytic capacitor, 9.75 Sprague, 9.79 Spurious-free dynamic range, see: SFDR SSM-2018: low-noise low distortion VCA, 2.98 block diagram, 2.98 distortion characteristics, 2.98 SSM-2019: microphone preamplifier: circuit, 2.95 input, 2.95 SSM-2141: monolithic IC line receiver, 2.102 gain accuracy, 2.103 SSM-2141/2143, THD + N performance, 2.104-105 SSM-2142: balanced line driver, 2.103-104 block diagram, 2.104 SSM-2143: monolithic IC line receiver, 2.102 CMR and THD, graphs, 2.103 SSM-2160, VCA with DAC, block diagram, 2.100 SSM-2165: microphone preamplifier: block diagram, 2.96 transfer characteristics, 2.96 SSM-2211: speaker driver power amplifier: application circuit, 2.97 performance, 2.97 Stable-dielectric ceramic, capacitor, 10.14 Stacked-film capacitor, 9.72-73 characteristics, 10.4-6 Staffin, R., 6.80 Standard input stage, differential pair, 1.21 Standard negative-feedback control system model, diagram, 4.51 Standard response: Butterworth filter, 8.21 filters, 8.21-54 Standby, 6.42 Star connection, damping resistor, 12.45 Star ground, 12.54 mixed-signal ICs, 12.66 Stata, Ray, 1.79 State variable filter, 8.77-78 (A), design equations, 8.95 advantages, 8.137 (B), notch, design equations, 8.96 (C), all-pass, design equations, 8.97 diagram, 8.77 digitally controlled, circuit, 8.138 digitally programmable, 8.137-140 implementation, circuit, 8.124 op amp functions, 8.114 redrawn, circuit, 8.137 Static transfer function, 6.117-127 Step response: filter, 8.19 definition, 8.19 Step-down (buck) converter: basic: diagram, 9.31 waveforms, 9.32 Step-up (boost) converter, 9.36-41 basic: circuit, 9.37 waveforms, 9.37 discontinuous mode, waveform, 9.39 input/output relationship, 9.38 point of discontinuous operation, 9.40 Stopband: filter, 8.1 frequency, 8.2 Stop, Russell, 6.83, 7.63 Storch, L., 8.143 Stout, D., 1.81 Straight binary code, 5.4 Strain gage, 3.69-70, 5.2 Bonder wire, 3.90-91 Foil, 3.90-91 Semiconductor, 3.92 Also see load cell Stray capacitance, 9.34 in mixed-signal IC, 12.60-61 Index 39 BASIC LINEAR DESIGN String DAC, 6.4-5 segmented, 6.5-7 Stripline transmission line, in PCB, 11.39 Subranging ADC, 6.52-57 improper trimming, errors, 5.18 input residue waveforms, diagram, 6.53 missing codes, graph, 6.53 N-bit two-stage, diagram, 6.52 pipeline stage, error correction, diagram, 6.54 trimming error, graphs, 6.121 Subtractor: definition, 2.8 op amp, circuit, 2.9 Successive approximation register, see: SAR Successive detection log amp, 2.56, 4.23 linearity, graph, 4.24 with log and limiter outputs, diagram, 4.23 Successive approximation ADC, 6.12, 6.37 grounding, 12.54 transient load, graph and circuit, 7.19 Sumida, 9.79 Super-beta op amp, 1.43 Super-beta transistor, input, 1.39 Superheterodyne radio receiver, diagram, 4.1 Superheterodyne radio transmitter, diagram, 4.1 Superposition, filter, 8.5 Supply range, voltage reference, 7.13-14 Supply voltage, op amp, 1.19-20, 1.44 Surface microstrip, 12.38 delay constant, 12.39 rules of thumb, 12.39 Surface zener, 7.8 Surface-mount multilayer ceramics, decoupling, 12.77 Swanson, E.J., 6.113 Swartzel, Karl D., Jr., 1.79 Sweetland, Karl, 2.124, 6.113 Switch: analog, 7.23-50 digital, crosspoint, 7.46 duty cycle, 9.33 duty ratio, 9.33 parasitic latchup, 7.47-50 power MOSFET, buck and boost converters, circuits, 9.56 thermostatic, 3.58-60 video, 7.42-44 crosspoint, 7.45 in voltage converter, 9.87 Switch capacitance, retained charge, 7.32 Switch control, gated oscillator, circuit, 9.52 Switch mode power supply, 10.23 Switch mode regulator, 9.27-80 advantages, 9.27-28 diode and switch considerations, 9.54-57 ideal step-down (buck) converter, 9.31-36 inductor and capacitor fundamentals, 9.28-30 Index 40 Switch mode regultators (cont) limitations, 9.27 power management, 9.27-80 ripple currents, 9.28 topology, basic, 9.27 Switch modulation, 9.47-48 control techniques, 9.48-51 pulse width modulation, 9.47 Switched capacitor: unregulated, inverter and doubler, 9.87- 88 voltage converter, 9.81-96 advantages, 9.82 inverter and doubler, circuits, 9.81 power loss, 9.90-91 power management, 9.81-96 voltage inverter, circuit, 9.87 Switched-capacitor DAC, 6.47 Switcher, nonisolated, topologies, 9.44 Switching capacitor, characteristics, 10.4-5 Switching electrolytic capacitor, 9.72-73 Switching regulator: capacitor role, 9.69 inductor choice, 9.57-69 input filtering, diagram, 9.77 output filtering, diagram, 9.76 Switching time, DAC settling time, 6.167 Sylvan, John, 2.114 Symmetric stripline, PCB transmission line, 12.40-41 Symmetrical bipolar voltage, 1.44 Synchro, 3.9-12, 5.2, 6.76-79 diagram, 3.9, 6.76 uses, 3.9 Synchronous rectifier, 9.28 Synchronous VFC, 6.68 diagram, 6.70 nonlinearity, graph, 6.72 quantized, 6.72 waveforms, 6.71 System Applications Guide, 2.114, 11.50 T T-Tech, Inc., 13.91, 13.92 Tadewald, T., 12.51 Talambiras, Robert P., 6.81, 6.83 Tantalum capacitor: advantages, 10.14 characteristics, 10.4-5 impedance vs. frequency, graph, 10.8 Spice model, 10.8 Tantalum electrolytic capacitor, 9.72-73 characteristics, 10.5 comparison chart, 8.113 Tantalum Electrolytic Capacitor SPICE Models, 10.27 Tantalum Electrolytic and Ceramic Capacitor Families, 9.78, 10.27 Tant, M.J., 6.175 Tchevysheff, see: Chebyshev INDEX A Technical Tutorial on Digital Signal Synthesis, 4.50 Teflon capacitor: characteristics, 10.5 comparison chart, 8.113 Telian, D., 13.31 Temes, Gabor C., 2.127, 6.113 Temperature: change, error source, 10.15 measurement, 3.29-30 microprocessor monitoring, 3.61-63 monitoring, by microprocessor, 3.61-63 passive component, filter, 8.110 Temperature coefficient: definition, 6.123-124 see also: Tempco Temperature retrace, resistor, 10.17 Temperature sensor: current and voltage output, 3.34-35 digital output, 3.56-58 Temperature-related gain error, from mismatched resistor, 10.15 A 10.7 MHz, 120 dB Logarithmic Amp, 4.40 Terman, Frederick E., 1.79, 1.80 Termination, microstrip transmission lines, circuits, 12.46 THD + N, definition, 1.60, 6.135-136 THD, definition, 1.60, 6.135-136 Thermal Coastline packaging, 9.18-19 internal details, 9.19 for op amp, 12.85 Thermal EMF, resistor, 10.18 Thermal hysteresis, XFET reference, 7.10 Thermal management, 12.83-96 PCB, 12.83-96 Thermal noise, resistor, 10.21-22 Thermal performance, comparison of op amp packaging, graph, 12.90 Thermal relationships, basic, table, 12.84 Thermal resistance, 12.83-84 design considerations, 12.88 LDO regulators, 9.17-19 measured between junction and ambient air, 12.85 op amp, 1.78 package-dependent, 12.85 Thermistor, 3.52-55 amplifier, linearized, diagram, 3.55 definition, 3.52 Kelvin connection, 3.52 nonlinearity and temperature range, 3.53 NTC, linearization, graph, 3.54 resistance characteristics, 3.52 temperature coefficient, graph, 3.53 temperature sensor, characteristics, 3.30 Thermocouple: auto-zero amplifier, 3.45-46 sampling phase diagrams, 3.45-46 basic principles, diagrams, 3.38 Thermocouple (cont) cold-junction compensation, 3.36 junction materials, table, 3.36 output, 5.2 output voltages for Types J, K, and S, graph, 3.37 principles, 3.36-44 Seebeck coefficient vs. temperature, graph, 3.38 temperature measurement, 3.39 temperature sensor, characteristics, 3.30 terminated leads, isothermal block, 3.41 Type J, 3.36-37 Type K, 3.37, 3.41 Type S, 3.36-37 Seebeck coefficient, 3.47 vs. temperature, 3.47 Thermocouple effect, resistor, 10.18 Thermoelectric effect, resistor, 10.18-20 Thermoelectric emf, 3.39 Thermometer code, 6.50 Thermometer DAC, 6.9-11 current-output, current sources, diagram, 6.10 diagram, 6.5 high speed, complementary current outputs, diagram, 6.11 Thermostatic switch, 3.58-60, 3.58-61 Thevenin equivalent output voltage, 2.63 Thevenin equivalent resistance, 13.8 Thevenin impedance, 12.45 Thevenin resistance, 9.14 Thevenin source, 13.45 Thick film resistor: comparison chart, 8.112 table, 10.21 Thin film laser trimming, for DAC, 6.99 Thin film resistor: comparison chart, 8.112 table, 10.21 Third order intercept point: determination, 1.63 distortion, 1.61-63 variation with frequency, 1.62 13dB small signal bandwidth, op amp, definition, 1.66 Thomas, L.C., 8.79, 8.143 Three op amp in-amp, 2.12-14 single +5 V supply restrictions, circuit, 2.14 Three-terminal voltage reference, 7.2 Time, EMI, 11.28 Time domain response: filter, 8.18-19 impulse response, 8.18-19 step response, 8.19 Timing specifications, 6.177-179 data sheet, example, 6.185-187 TMP01: dual setpoint temperature controller, 3.59-60 diagram, 3.60 Index 41 BASIC LINEAR DESIGN TMP03/TMP04: digital out temperature sensor: diagram, 3.56 output format, 3.57 TMP04, interfacing to microcontroller, 3.58 TMP35: temperature sensor, for cold junction compensation, 3.42 voltage output sensor, 3.41-42, 3.44 TO-99 metal can package device, 12.17 Tolerance, voltage reference, 7.13 Toomey, P., 8.144 Total effective input noise, for ADC, calculation from SNR, 6.151 Total harmonic distortion, see: THD Total harmonic distortion plus noise, see: THD + N Total input offset voltage, in-amp, definition, 2.23 Total noise: calculation, 1.50, 1.56 op amp, 1.49-51 Total offset voltage, calculation, 1.41 Total output noise: calculation, 2.27 calculations, 1.55-59 Total output offset error, calculation, 1.41-42 Total output rms noise, op amp, 1.59 Total rms jitter, 6.159 SHA, 7.57 Total unadjusted error, definition, 6.127 Tow, J., 8.79, 8.143 Trace: conductor, resistance, 12.5 embedding, 12.42 PCB, 12.5-52 Track mode, 6.48 Track mode linearity, ADC with SHA, 7.61 Track-and-hold circuit, 7.51 Track-to-hold mode: SHA: errors, graph, 7.54 specifications, 7.54-57 Tracking ADC, 6.66-67 diagram, 6.67 Transconductance multiplier, basic, circuit diagram, 4.15 Transducer, temperature, characteristics, table, 3.30 Transfer characteristic slope, log amp, 4.24 Transfer function, high-pass filter, 8.8-9 Transformer: common-mode power line isolation, EMI protection, 11.37 in isolation amplifier, 2.33-34 reset, 9.46 rotating, 3.10 Transient load, voltage reference, 7.1 Index 42 Transient power-line disturbance, 11.35 Transient response: ADC: definition, 6.161 graph, 6.161 Transient voltage suppressor, 2.29 Transimpedance, definition, 1.32 Transimpedance amp, 1.17, 1.32 Transistor, input, 1.27 Transistor/op amp log amp, disadvantages, 4.21 Transitional filter, characteristics, 8.24 Translinear multiplier, four-quadrant, circuit diagram, 4.17 Translinear variable gain cell, diagram, 4.33 Transmission line, 12.35 driving, 13.37 microstrip, 12.35 PCB, symmetric stripline, 12.40-41 termination: ECL, 12.48 and propagation delay, rule, 12.43 Transmit TxDAC family, 6.172 Transresistance, definition, 1.32 Travis, Bill, 3.27 Trefleaven, D., 8.144 Trench-isolation, LLCMOS switch, 7.50 Triboelectric charging, 11.13-14 Triboelectric effect, 11.1 Trietley, Harry L., 3.27 Trimming: errors, 6.121 voltage reference, 7.13 Trimming potentiometer, 10.22 Trimpot, 10.22 True Power circuit, 4.2 True Power detector, RF/IF circuit, 4.29-31 True log, architecture, 4.21 True log amp, 2.56 structure and performance, diagram, 4.23 Tschebychev, see: Chebyshev Tschebyscheff, see: Chebyshev TTE, Inc., 5.32 Tuned circuit, ringing, 12.80 Turney, William J., 6.114 Twin-T notch filter: design equations, 8.101 diagram, 8.81 Two op amp in-amp: circuit, 2.18 CMR, 2.19 Two amp ion amp (cont) input impedance, 2.18 single-supply restrictions, circuits, 2.19-20 Two-terminal voltage reference, 7.2 Two-tone IMD, 6.141 Twos complement code, 4-bit converter, 5.6, 5.8 TxDAC, 6.34 oversampling interpolating, block diagram, 6.35 INDEX TxDAC series, high-speed CMOS DACs, 12.94 Type 5MC Metallized Polycarbonate Capacitor, 9.78, 10.27 Type 5250 and 6000-101K chokes, 10.27 Type EXCEL leaded ferrite bead EMI Filter, and type EXC L leadless ferrite bead, 10.27 Type HFQ Aluminum Electrolytic Capacitor and Type V Stacked Polyester Film Capacitor, 9.78, 10.27 Type-2 servo loop, 6.79 U Undersampling, 5.28-29 antialiasing filters, 5.29-31 within Nyquist zone, 5.31 Unipolar 3-bit ADC, transfer function, 5.5, 5.12 Unipolar 3-bit DAC, transfer function, 5.5, 5.12 Unipolar code, 5.4-6 binary, 4-bit converter, 5.4 quantization uncertainty, 5.6 Unipolar converter, 5.12-13 Unipolar power supply, 9.1 Unlooped ground, 12.9 V Valkenburg, M.E. Van, 8.143 Valley control, 9.51 Van de Plassche, R.J., 6.112 Van de Plassche, Rudy J., 6.83 Van de Weg, H., 6.112 Van der Grift, Rob E.J., 6.83 Van der Veen, Martien, 6.83 Van Mierlo, S., 6.112 Van Valkenburg, M.E., 8.143 Variable gain amplifier, see: VGA Variable Gain Amplifiers Enable Cost Effective IF Sampling Receiver Designs, 4.40 Variable integrator, digital, improved, circuit, 8.140 VCA: audio application, 2.98-100 liner-in-dB gain, 4.35 RF/IF circuit, 4.33-34 translinear, 4.33 VCO, 3.12 phase noise vs. frequency offset, 4.63 in PLL, 4.52 in resolver, 6.78 transfer function, graph, 4.53 VCO Designers’ Handbook, 4.73 VDE 0871 compliance, 11.23 Vector Electronic Company, 13.91, 13.92 Vectorscope, signal displays, 1.74 Veen, Martien van der, 6.83 Verster, T.C., 6.82 VFB, advantages, 1.19 VFB op amp: basic operation, 1.4-5 Bode plot, 1.16, 1.31 Closed-loop gain, 1.13 common-mode input impedance, specification, 1.42 current noise, 1.49 gain-bandwidth product, 1.11, 1.67 inverting and noninverting configurations, 1.5-9 loop gain, 1.15 noise gain, 1.14-15 open-loop gain, 1.9-10 phase margin, 1.13 signal gain, 1.14 stability criteria, 1.11-12 VFC: architecture: charge-balance, 6.68 current-steering multivibrator, 6.68 definition, 6.68-72 waveforms, 6.71 VFO, architecture, 6.68 VGA: digitally controlled, 4.38-39 RF/IF circuit, 4.33-40 voltage controlled amplifier, 4.33-34 VHDL.org, 13.31 Vibration, immunity, 3.25-26 Video: applications, differential gain, 1.73 crosspoint switch, 7.45 flat bandwidth, 1.66 multiplexer, 7.42-44 switch, 7.42-44 crosspoint, 7.45 Video DAC, 6.23 Video Op Amp, 1.79 Virtual ground, op amp, 1.7 Viswanathan, T.R., 6.82 Vito, Tom, 6.175 Vizmuller, P., 4.73 Vladimirescu, A., 13.31, 13.91 Vladimirescu, Andrei, 13.31, 13.91 Voltage controlled amplifier, see: VCA Voltage controlled oscillator, see: VCO Voltage doubler: circuit, 9.81 operation, 9.88-89 power losses, circuit, 9.91 waveforms, 9.89 Voltage drop: coupled circuit, 12.8 and grounding, 12.8 Voltage feedback, see: VFB Voltage feedforward, 9.49 Voltage inverter: circuit, 9.81 operation, 9.88-89 Index 43 BASIC LINEAR DESIGN voltage inverter (cont) power losses, circuit, 9.90 use, 9.83 waveforms, 9.88 Voltage noise, op amp, 1.47 Voltage output sensor: packaging, thermal response, 3.35 ratiometric, diagram, 3.34 Voltage plane, advantages, 12.56-57 Voltage reference: architectures, characteristics, table, 7.11 diode, circuits, 7.2 diode-based, circuits, 7.2 noise, 7.1 precision, 7.1-2 pulse current response, 7.17-19 shunt, 7.2 specifications, 7.13-16 three-terminal, 7.2 three-terminal hookup, schematic diagram, 7.11-12 two-terminal, 7.2 types, 7.2-3 Voltage sensitivity, resistor, 10.20 Voltage standing wave ratio, filters, 8.26 Voltage-mode R-2R ladder network DAC, diagram, 6.18 Voltage-output DAC, diagram, 6.5 Voltage-to-frequency converter, as transmitter, 2.42 Voluntary Control Council for Interference, 11.23 V rms/dBm/dBu/dBv calculator: screen, 13.33 use, 13.33 W Wagner, Richard, 1.80 Wainwright Instruments, 13.84 Wainwright Instruments GmbH, 13.91, 13.92 Wainwright Instruments Inc., 13.91, 13.92 Waldhauer, F.D., 6.82 Waltman, Ron, 6.175 Watkins, Tim, 13.92 Waveform: bipolar, 1.23 Waveform, (cont) effects on intercept point, chart, 4.26 nonlinear, equation, 8.16-17 Weaver, Lindsay A., 4.73 Webster, John G., 3.27, 3.64 Weg, H. Van de, 6.112 Welland, D.R., 6.113 Wenzel Associates, Inc., 12.65 West, Julian M., 1.79 Wheable, Desmond, 6.84 Wheatstone bridge, 3.70-71 Index 44 White noise, 1.54 source, 1.48 White noise signal, input bandwidth limit, 13.52 Wide codes, in ADC, 5.18 Wideband amplifier, 2.123 Wideband CDMA: adjacent channel leakage ratio, 6.145-146 graph, 6.145 adjacent channel power ratio, 6.145-146 Widlar, Bob, 7.21, 9.26 Williams, A.B., 8.143 Williamsen, M., 8.144 Williams, Jim, 13.91, 13.92 Window comparator, 2.69 Wire microstrip, 12.36 transmission line, 12.36 impedance, calculation, 12.37 Wirewound resistor: comparison chart, 8.112 parasitics, 10.17-18 table, 10.21 Witte, Robert A., 6.175 Wold, Ivar, 6.84 Wong, James, 3.64 Woodward, Charles E., 6.80, 6.175 Woofer-midrange-tweeter analogy, for RFI low-pass filter design, 11.32 Wooley, B.A., 6.113 Wooley, Bruce, 6.113 Word: parallel, 5.2 serial, 5.2 Worst harmonic, definition, 6.135-136 Wynne, J., 11.50 X X-AMP, 4.35-38 block diagram, 4.35 RF/IF circuit, 4.35-38 schematic, 4.36 total input-referred noise, 4.37 transfer function, 4.36 X-AMP, A New 45 dB, 500 MHz Variable-Gain Amplifier (VGA) Simplifies Adaptive Receiver Designs, 4.40 XFET reference, 7.9-12 architecture, 7.10 table, 7.11 basic topology, circuit, 7.10 drift, 7.13 pinchoff voltages, 7.9 thermal hysteresis, 7.10 Y Yasuda, Y., 6.112 Yester, Francis R., Jr., 6.114 Young, Joe, 6.83, 7.63 INDEX Z Zang, Lingli, 2.127 Zener, buried, drift, 7.13 Zener diode, 1.34, 11.35 break-down, 7.3 circuit, 7.2-3 EMI protection, 11.35 monolithic, 7.3 temperature-compensated, 7.3 Zener reference: buried, 7.8-9 surface, 7.8 Zener zapping, 1.34-35 Zeoli, G.W., 6.175 Zero TC (unipolar converter), definition, 6.124 Zeta converter, 9.44 Zhang, K., 13.31, 13.91 Zkazawa, Yukio, 6.175 Zoned load capacitor ESR, graph, 9.12 Zumbahlen, H., 8.144 Zverev, A.I., 8.143 Index 45 BASIC LINEAR DESIGN ANALOG DEVICES PARTS INDEX AD2S90, 6.79 AD210, 2.34-36 AD215, 2.36-37 AD260, 2.40-42 AD260/AD261, 2.40-42 AD38X, 7.12 AD39X, 7.12 AD482, 13.65 AD524, 2.29, 13.43 AD526, 2.89-90 AD534, 4.16-17 AD536A, 2.85-86 AD538, 2.57 AD539, 2.77-78, 4.13-14 AD548, 13.65 AD549, 1.51, 13.65 AD550, 6.3, 6.12 AD574, 5.22, 6.42, 7.20 AD580, 7.4 AD584, 7.5 AD586, 7.8-9, 7.13 AD587, 7.15 AD588, 3.95, 3.97, 7.8, 7.13-14 AD589, 3.95, 7.5, 7.16, 7.17 AD590, 3.33 AD594, 3.42-43 AD594/AD595, 3.42-43 AD595, 3.42-43 AD598, 3.3 AD600, 4.35-36 AD602, 4.35-36 AD620, 2.13-16, 2.22, 2.24-25, 2.28, 2.35-36,3.95 AD620B, 2.28, 3.96, 13.42 AD621, 2.22 AD621B, 3.96, 3.97 AD623, 12.13 AD624C, 2.22 AD627, 2.14 AD629, 2.9-10, 12.12-13 AD629B, 2.10 AD636, 2.85 AD641, 4.24-27 AD645, 1.47, 1.51 AD648, 13.65 AD680, 7.4, 7.14 AD684, 7.51 AD688, 7.14 AD698, 3.3-5 AD704, 13.65 AD711, 13.65 AD711/12/13, 2.95 AD712, 1.44, 13.65, 13.67 AD713, 13.65 AD737, 2.85 Index 46 AD743, 13.65 AD743/AD745, 1.47 AD768, 6.27 AD775, 6.210 AD780, 2.63, 7.4, 7.12, 7.13, 7.14, 7.19 AD781, 7.51 AD783, 7.51 AD790, 2.68-69 AD795, 13.65 AD797, 2.90-91, 2.95 AD811, 13.12 AD817, 12.89, 13.8 AD820, 1.98-99, 13.65 AD822, 1.98-99, 2.15-16, 13.65 AD823, 1.99, 13.65 AD824, 1.98-99, 13.65 AD825, 8.137-138, 8.141 AD829, 1.74 AD830, 2.49 AD834, 2.83-84, 4.17-19 AD847, 1.12, 1.83, 1.85, 8.118-120, 13.14-16 AD848, 1.12 AD849, 1.12 AD850, 6.3 AD8152, 7.46 AD1170, 6.72 AD1580, 7.5-6, 7.16, 7.17 AD1582 to AD1585 series, 7.4, 7.8, 7.12 AD1582 to AD1585 series, 7.13-14 AD185X series, 6.109-110 AD1853, 6.110 AD1871, 6.99-101 AD1879, 6.98 AD1955, 6.110 AD1990/ AD1902/ AD1904/AD1906, 2.107-117 AD5535, 13.73 AD5570, 6.181, 6.190, 6.197 AD6600, 6.210 AD6644, 6.210 AD6645, 6.139-140, 6.142, 6.145, 6.152- 154, 6.160, 6.178-179, 6.181-185, 6.188, 6.193-194, 6.202, 7.61-62, 12.94 AD7111 LOGDAC, 6.38-39 AD7450, 13.74-75 AD7524, 6.14 AD7528, 8.137-138, 8.141 AD7677, 6.48-49 AD7678, 6.181, 6.196, 6.199 AD7684, 6.190 AD77XX series, 6.101 AD77XX family, 3.44, 3.49-50 AD7710, 2.93-94 AD7710-series, 7.19 AD7711, 2.93 AD7712, 2.93 INDEX AD7713, 2.93 AD7730, 3.85, 3.86, 3.98 6.101, 6.103-107, 6.115, 6.181, 6.198, 6.201-202, 13.46-48, 13.72-73 AD7846, 2.91-92 AD789X, 6.40 AD7943/ AD7945/ AD7948, 6.19 AD8001, 1.18, 1.68, 1.76-77, 1.83, 12.31, 13.70-71, 13.89 AD8016, 12.87-89 AD8017AR, 12.83-86 AD8021, 13.40-41 AD8029, 12.77 AD8033, 1.98-99, 13.59 AD8034, 1.98-99, 13.59 AD8036, 2.59-63 AD8036/AD8037, 2.59-63 AD8037, 2.59-63 AD8051, 1.13 AD8051/ AD8052/ AD8054, 1.83, 1.86-88 AD8054, 1.70-71 AD8055, 6.26-27 AD8057, 12.90 AD8058, 12.90 AD8065, 1.98-99, 13.56-57, 13.59 AD8066, 1.98-99, 13.59 AD8067, 13.59-60 AD8074, 2.4 AD8074/AD8075, 2.3 AD8075, 1.66, 2.4 AD8079A/AD8079B, 2.4 AD8079A/ AD8079B, 2.4 AD8108/AD9109, 7.45 AD8110/AD8111, 7.45 AD8113, 7.45 AD8114/AD8115, 7.45 AD8116, 7.45 AD8129, 2.50-51, 13.45 AD8129/AD8130, 2.5, 2.49-51 AD813X, 6.27-28, 2.31-32 AD8130, 2.50-51, 13.45 AD8138, 13.44 AD8170, 7.42-43 AD8174, 7.42-44 AD8180, 7.42-43 AD8182, 7.42-43 AD8183/AD8185, 7.42-44 AD8184, 7.44 AD8186, 7.43 AD8187, 7.43 AD8230, 3.45-46 AD8330, 4.33-34 AD8345, 4.11 AD8350, 2.6 AD8354, 2.5 AD8362, 4.29-31 AD8367, 4.37-38 AD8370, 4.38-39 AD8510, 13.65 AD8512, 13.65 AD8517, 1.98 AD8519, 1.98-99 AD8527, 1.98 AD8529, 1.98-99 AD8531/ AD8532/ AD8534, 1.83, 1.94 AD8534, 1.46, 1.90-91 AD8541, 1.98 AD8542, 1.98 AD8544, 1.98 AD855X, 2.121, 2.123, 2.125 AD8551, 1.98, 12.11-12, 12.19 AD8551/ AD8552/ AD8554, 2.122 AD8552, 1.98 AD8554, 1.98 AD8565, 1.98-99 AD8566, 1.98-99 AD8567, 1.98-99 AD857X, 2.121, 2.123 AD8571, 1.98 AD8571/72/74, 2.122 AD8572, 1.98 AD8574, 1.98 AD8603, 1.98 AD8614, 1.98 AD8620, 13.65 AD8621, 1.98 AD8622, 1.98 AD8624, 1.98 AD8625, 1.99 AD8626, 1.98-99 AD8627, 1.98-99, 13.65 AD8631, 1.98 AD8632, 1.98 AD8644, 1.98 AD9002, 2.62-63 AD9042, 6.210, 7.60-61 AD9051, 6.210 AD9054A, 6.63 AD9057, 6.210 AD9200, 6.210 AD9203, 6.210 AD9216, 6.208 AD9220, 6.210 AD9224, 6.210 AD9225, 6.210 AD9226, 6.136-137 AD9235, 6.55 AD9238, 6.208 AD9240, 6.210 AD9245, 12.91-92 AD9248, 6.208 AD9280, 6.210 AD9283, 6.210 AD9410, 6.51 AD9430, 6.55, 6.148, 12.49, 12.92-93 AD9432, 6.210 AD9510, 7.73-83 AD9514, 7.67-72 Index 47 BASIC LINEAR DESIGN AD9620, 2.3 AD9630, 2.3 AD9631, 12.79-80 AD976X, 6.24 AD977X, 6.24 AD977x-family, 6.21 AD9772, 13.50 AD9773, 6.34 AD9775, 6.21-22, 6.34 AD9777, 6.34, 6.171, 6.181, 6.186-187, 6.191-192, 6.195, 6.198, 12.94 AD985X series, 12.94 AD985x-family, 6.21 AD9850, 4.46-47, 13.48 AD9870, 6.109 AD10677, 6.210 AD12400, 6.210 AD22100, 3.34 AD22105, 3.58-59 AD22151, 3.7-8 ADF439F, 7.50 ADF4111, 4.58 ADF4112, 4.67 ADF41167/ ADF41168, 13.29 ADG200-series, 7.23 ADG201-series, 7.23 ADG412, 2.90-91, 7.32 ADG438F, 7.50 ADG508F, 7.50 ADG509F, 7.50 ADG511, 2.92-93 ADG528F, 7.50 ADG708, 7.30 ADG8XX-series, 7.26 ADG801/ADG802, 7.26 ADG918, 7.40-41 ADG919, 7.40-41 ADLH0033, 2.1 ADM1201, 3.61-63 ADP1073, 9.52, 9.54 ADP1108, 9.54 ADP1109, 9.54 ADP1110, 9.54 ADP1111, 9.54 ADP1147, 9.47 ADP1148, 9.62 ADP1173, 9.54 ADP3000, 9.48, 9.52, 9.54-55, 9.58-59 ADP330X, 9.13-15 ADP3300, 9.15-16 ADP3300-series, 7.15 ADP3310, 9.20-25 ADP3603, 9.82, 9.91-93 ADP3604, 9.82, 9.91-93 ADP3605, 9.82, 9.91-93 ADP3607, 9.82, 9.91-93 ADP3607-5, 9.94 ADR01, 7.4, 7.12 ADR02, 7.4, 7.12 Index 48 ADR03, 7.4, 7.12 ADR29X series, 7.12, 7.14 ADR38X series, 7.4, 7.13-14 ADR39X series, 7.4, 7.13-15 ADR43X, 7.12 ADR43X series, 7.13, 7.14-15 ADR510, 7.17 ADR512, 7.16, 7.17 ADSP-2106X, 12.48 ADSP-2189M, 13.79-80 ADSP-21060L SHARC, 12.43 ADSP-21160 SHARC, 12.69-70 ADT45/ADT50, 3.34 ADT70, 3.49-51 ADT71, 3.51 ADuM130X/ADuM140X, 2.46-48 ADuM1100, 2.42-46 ADuM140X, 2.46-47 ADuM1400, 2.48 ADuM1401, 2.48 ADuM1402, 2.48 ADXL202, 3.17-18 ADXRS150, 3.19-20 ADXRS300, 3.19-20 AMP02, 2.29 AMP03, 12.12-13 AMP04, 2.92-93 BUF03, 2.2 BUF04, 2.3 DAC-08, 6.16, 6.18 HOS-100, 2.1 OP07, 2.75 OP27, 1.49-51, 1.77, 13.8 OP42, 13.65 OP90, 1.98, 8.118-120, 12.31 OP113, 1.98-99 OP162, 1.98-99 OP176, 8.116 OP177, 1.71, 2.123, 3.95, 3.96, 3.97, 10.19 OP177F, 1.33 OP179, 1.98 OP183, 1.98-99 OP184, 1.98 OP191, 1.98, 11.5 OP193, 1.98, 3.42 OP196, 1.98 OP213, 1.52, 1.98-99, 2.91, 3.97, 3.98, 7.32 OP249, 13.9, 13.65 OP262, 1.98-99 OP275, 13.65 OP279, 1.98 OP281, 1.98 OP282, 13.65 OP284, 1.98, 2.18 OP290, 1.45 OP291, 1.98, 11.5, 11.7 OP292, 1.98-99 OP293, 1.98 OP295, 1.98-99, 2.95 INDEX OP296, 1.98 OP297, 2.18 OP413, 1.98 OP418, 1.99 OP462, 1.98-99 OP481, 1.98 OP484, 1.98 OP490, 1.98 OP491, 1.98, 11.5 OP492, 1.98-99 OP493, 1.98 OP495, 1.98-99 OP496, 1.98 OP727, 1.98 OP747, 1.98 OP777, 1.98 OPX91 family, 11.5-7 OP1177/OP2177/OP4177, 1.83-84 REF01, 7.4 REF02, 7.4 REF03, 7.4 REF43, 7.12, 7.14 REF19X, 7.4, 7.12, 7.13-14 REF195, 3.97, 7.13, 7.14 SSM-2018, 2.98 SSM-2019, 2.95 SSM-2135, 1.98-99 SSM-2141, 2.103 SSM-2141/ SSM-2143, 2.101, 2.104 SSM-2142, 2.101, 2.103-104 SSM-2143, 2.102-103 SSM-2160, 2.99 SSM-2165/ SSM-2166/ SSM-2167, 2.95-96 SSM-2211, 2.97 TMP01, 3.59-60 TMP03/TMP04, 3.56-58 TMP04, 3.58 TMP35, 3.41-42, 3.44 Index 49