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Op amps for everyone PDF

284 Pages·2013·18.79 MB·English
by  Carter
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Op Amps for Everyone Op Amps for Everyone Fourth Edition Bruce Carter AMSTERDAM(cid:129)BOSTON(cid:129)HEIDELBERG(cid:129)LONDON NEWYORK(cid:129)OXFORD(cid:129)PARIS(cid:129)SANDIEGO SANFRANCISCO(cid:129)SINGAPORE(cid:129)SYDNEY(cid:129)TOKYO NewnesisanimprintofElsevier NewnesisanimprintofElsevier TheBoulevard,LangfordLane,Kidlington,Oxford,OX51GB,UK 225WymanStreet,Waltham,MA02451,USA Secondedition2003 Thirdedition2009 Fourthedition2013 Copyrightr2013ElsevierInc.Allrightsreserved. Nopartofthispublicationmaybereproducedortransmittedinanyformorbyanymeans,electronicor mechanical,includingphotocopying,recording,oranyinformationstorageandretrievalsystem,without permissioninwritingfromthepublisher.Detailsonhowtoseekpermission,furtherinformationaboutthe Publisher’spermissionspoliciesandourarrangementwithorganizationssuchastheCopyrightClearanceCenter andtheCopyrightLicensingAgency,canbefoundatourwebsite:www.elsevier.com/permissions ThisbookandtheindividualcontributionscontainedinitareprotectedundercopyrightbythePublisher (otherthanasmaybenotedherein). Notices Knowledgeandbestpracticeinthisfieldareconstantlychanging.Asnewresearchandexperiencebroadenour understanding,changesinresearchmethods,professionalpractices,ormedicaltreatmentmaybecomenecessary. Practitionersandresearchersmustalwaysrelyontheirownexperienceandknowledgeinevaluatingandusing anyinformation,methods,compounds,orexperimentsdescribedherein.Inusingsuchinformationormethods theyshouldbemindfuloftheirownsafetyandthesafetyofothers,includingpartiesforwhomtheyhavea professionalresponsibility. Tothefullestextentofthelaw,neitherthePublishernortheauthors,contributors,oreditors,assumeanyliability foranyinjuryand/ordamagetopersonsorpropertyasamatterofproductsliability,negligenceorotherwise,or fromanyuseoroperationofanymethods,products,instructions,orideascontainedinthematerialherein. BritishLibraryCataloguing-in-PublicationData AcataloguerecordforthisbookisavailablefromtheBritishLibrary LibraryofCongressCataloging-in-PublicationData AcatalogrecordforthisbookisavailablefromtheLibraryofCongress ISBN:978-0-12-391495-8 ForinformationonallNewnespublications visitourwebsiteatwww.newnespress.com PrintedandboundintheUnitedStates 13 14 15 16 10 9 8 7 6 5 4 3 2 1 Index Note:Page numbers followed by “f” refer to figures. A bandpassfilters, 86(cid:1)88 power supply information, high-pass filters, 86 65(cid:1)66 Absolute valuecircuit,264 low-passfilters, 86 system information, AC and DCgain,19 notchfilters, 88 64(cid:1)65 complication, 19 narrow vs. wide bandpass Adder circuit, 13 design procedure for single- filter, 83 Adhesives, 133 supply opamp design, 36(cid:1)40 single op amp, 89(cid:1)97 Analog computers,2 simultaneous equations, combination bandpass Analog ground,241(cid:1)242 22(cid:1)34 andnotch filters, Antennas,247(cid:1)249 97 Applicationerrors,commonwith single supply versus dual supply, 19(cid:1)22 single-amplifier notch and current feedback amplifier multiple-notch filters, capacitorin feedback ACtoDCconvertercircuit,265 95(cid:1)96,95f loop, 187 Activefilter design stagger-tuned and shortedfeedback resistor, techniques, 73 biquad filters, 98 multiple-peak bandpass 185(cid:1)187 design aids, 98(cid:1)103 filters, 91(cid:1)95, 94f DCgain, 185 three-pole high-pass decouplingcapacitors, 193 low-pass, high-pass, and filters, 90(cid:1)91 fully differential amplifier bandpass filter design aids,98(cid:1)101 three-pole low-passfilters, incorrect common mode 89(cid:1)90 range,189(cid:1)190 notch filter design aids, transfer equationmethod, incorrect DC operating 101 74(cid:1)77 point, 188(cid:1)189 Twin-T design aids, 102 Active load, 146f,147 incorrect single-ended fast, practical filter design, ADC (analog todigital termination, 190(cid:1)191 77(cid:1)85 converter), 3 improper decoupling, high-passfilter, 80(cid:1)81 ADC converter 192(cid:1)194 characteristics, 67(cid:1)68 improper termination of low-pass filter, 80 architecturaldecisions, unused sections, narrow (single-frequency) bandpass filter, 81(cid:1)82 70(cid:1)71 183(cid:1)185 comparator,182 op amps notch (single-frequency rejection) filter, 83(cid:1)85 input signal characteristics, operated at less than unity widebandpassfilter,82(cid:1)83 66(cid:1)67 gain,179(cid:1)180 interface characteristics, used asa comparator, high-speed filter design, 85(cid:1)88 68(cid:1)70 180(cid:1)183 273 274 Index B CMRR (common-mode bandwidth Bandpass filter, 86(cid:1)88 rejection ratio), 206 for 0.1dB flatness, 223 design aids,98(cid:1)101 Colors, noise,229(cid:1)230 BW, 203 Common mode error,189(cid:1)190 maximum-output- narrow vs.wide, 83 Common-mode input voltage swing, 203 and notch filters,97 condition,218 unitygain, 202(cid:1)203 Bandwidth, 203 Common-mode input voltage capacitance Bandwidth parameters range parameter, 218 common-mode input for 0.1dB flatness, 223 Common-modeinput,204(cid:1)205 capacitance,204(cid:1)205 maximum-output-swing, 203 unity gain, 202(cid:1)203 differential,205 differentialinput Common-mode rejectionratio capacitance,205 Biquad filters,98 Bishop, John, 39(cid:1)40, 162, 164 (CMRR),206 inputcapacitance, Companion circuits, 144(cid:1)148 203(cid:1)204 Black, Harry, 1 Comparator, op amp used as, load capacitance, 205 Bode,H. W.,2 Broadbandamplifiers,113(cid:1)116 180(cid:1)183 common-mode rejection Compositeop amp,156, 156f ratio (CMRR), 206 Brown noise, 230 Buffer amplifiers,59(cid:1)61 Computers, analog, 2 crosstalk,222 Conductednoise,239, 255 current BurrBrown,164 Constantcurrent generator inputbiascurrent, 208 C circuit, 263 inputcurrent range, 207 Capacitance Continuous total dissipation inputnoise current, 209 common-modeinput parameter, 224 inputoffset current, parameter,204(cid:1)205 Copper cladding, 238(cid:1)239 200, 208 differential input Coupling capacitors, 108 output current, 209 parameter,205 Crosstalkparameter, 222 short-circuitcurrent input parameter, 203(cid:1)204 Currentfeedback opamps, duration, 224 load parameter, 205 48(cid:1)49,105(cid:1)106, 113 supply current,207 Capacitors, 187, 245(cid:1)246, Currentparameters dissipation,224 250(cid:1)251 inputbias current, 208 error Cartesian coordinates, 22, 23f inputcurrent range, 207 differentialgain error,200 Casetemperature for 60 inputnoisecurrent, 209 differentialphase seconds, 223(cid:1)224 inputoffset current, 200, 208 error,223 Ceramic packaging, 131 outputcurrent, 209 frequency condition, 206 CFA (currentfeedback low level condition, 209 gain amplifier) short-circuit, 209(cid:1)210 large-signal voltage applicationmistakes,185(cid:1)187 short-circuitcurrent amplification gain capacitorinfeedbackloop,187 duration,224 condition, 202 shorted feedback resistor, supply current, 207 open-loop voltage gain, 185(cid:1)187 shutdown, 207 200(cid:1)202 Circuit design, 7 Current-limiting resistor, 142 gain bandwidth,202(cid:1)203, Circuit theory, 7 Curve-fitting filters,268(cid:1)271 207 Circuits See also gain error, 200 D specific circuits gain margin, 200 components of,1 Data sheet parameters, harmonicdistortion defined, 7 197(cid:1)199Seealso total, 215 Cladding, 238(cid:1)239 specific parameters total plus noise, 216 Index 275 impedance, 222 maximum junction low-level output input bias current,208 temperature, 216 voltage, 221 input offset voltage, operatingfree-air open-loop voltage gain, 219(cid:1)220 temperature condition, 200(cid:1)202 noise 214 outputvoltage swing, equivalent input noise storage temperature, 217 maximum peak-to-peak, voltage, 220 thermal resistance 221 harmonic distortion, junctionto ambient,211 outputvoltage swing, total, 215 junctionto case, 211 peak-to-peak, 221(cid:1)222 input noise current, 209 time stepvoltage peak-to-peak total harmonicdistortion fall time, 215 condition, 222 plus noise, 216 rise time, 216 supply voltage condition, null resistancecondition, 213 settling time, 216(cid:1)217 217 open-loop turn-off/turn-on, 215 supply voltage sensitivity, transimpedance, 222 voltage 205(cid:1)206 transresistance, 213 amplificationgain turn-off/turn-on, 219 voltage gain,200(cid:1)202 condition, 202 DC gain, 185 phase margin,223 common-mode input DC operating point, 189 power dissipation,210 voltage condition, 218 Decouplingcapacitors, 193 power supply rejection common-mode input DecouplingPCB, 252(cid:1)255 ratio,210 voltage range, 218 at board level, 255 resistance differential input at integratedcircuitlevel, input resistance,211(cid:1)212 voltage,218 254(cid:1)255 input resistance differential inputvoltage choosing right capacitor, differential, 212 range, 219 253(cid:1)254 load resistance condition, differential large-signal digital circuitry, 252(cid:1)253 212(cid:1)213 voltage amplification, Deliyannis filter, 82 output resistance,213 202 Design aids, 98(cid:1)103 shutdown equivalent input noise low-pass, high-pass, and turn-off time, 215 voltage,220 bandpassfilter design turn-off voltage high-level outputvoltage, aids, 98(cid:1)101 parameter, 219 221 notch filter design turn-on time, 215 input offset voltage, aids, 101 turn-on voltage, 219 219(cid:1)220 Twin-T design aids, signal source condition, 213 input offset voltage long- 102 slew rate,213(cid:1)214 term drift,224 Difference amplifier, 55(cid:1)59 supply rejectionratio, 210 input voltage condition, Differential amplifier, 3, temperature 219 13(cid:1)14 case temperature for 60 input voltage condition, Differential input resistance seconds, 223(cid:1)224 common-mode, 218 parameter, 212 coefficientofinput offset input voltage range Differential input voltage, current, 200 condition or parameter, 218 coefficientofinput offset 217(cid:1)218 Differential input voltage voltage, 200 large-signal voltage range,219 lead temperature for 10 or amplification gain Differential phase error 60 seconds, 225 condition, 202 parameter, 223 276 Index Differential-large signal Extremereliability, 127, Frequency condition, 206 voltage amplification 136(cid:1)137 Frequency response peaking, parameter,202 Extremeshock, 132 109 Digital circuitry, 252(cid:1)253 Extremetemperature Full waverectifier circuit, Digital control system, 152f range, 127 265 Digital ground,241(cid:1)242 Extremevibration, 131(cid:1)132 Fully differential amplifier, Digital subscriber line (DSL), 49(cid:1)53, 187(cid:1)191 F 3,59 applicationmistakes, Digital-to-analog converters Fairchild,µA709, 4 187(cid:1)191 (DACs), Fall time parameter,215 differentialgain stages, 126,151(cid:1)153 Faraday cage, 255 50(cid:1)52 design example, 151(cid:1)153 Fast, practical filter design, incorrect common mode Dualsupplyamplifier 77(cid:1)85 range, 189(cid:1)190 packages, 256(cid:1)257 high-passfilter, 80(cid:1)81 incorrect DCoperating point, single supply amplifier vs., low-pass filter, 80 188(cid:1)189 19(cid:1)22 designprocedure, 80 incorrect single-ended Dynamic range, 121 digging deeper,80 termination, 190(cid:1)191 narrow (single-frequency) meaning of“fully E bandpassfilter, 81(cid:1)82 differential” 49(cid:1)50 ElectronicsWorkbench, 171 digging deeper,82 new function, 53 Electrostatic discharge(ESD) notch (single-frequency secondoutput,usage structure,11(cid:1)12 rejection)filter, 83(cid:1)85 of, 50 Equivalentinput noise voltage designprocedure, 83(cid:1)84 single-ended todifferential parameter,220 digging deeper,84(cid:1)85 conversion, 52(cid:1)53 Error correction, 236 wide bandpass filter, G Extreme applications,127 82(cid:1)83 failure, probability of, designprocedure, 82 Gain, 10 134(cid:1)135 digging deeper,83 Gain margin,200 packaging, 130(cid:1)133 narrow vs.widebandpass Gain parameters integrated circuit, filter, 83 gain bandwidthproduct connecting, 132(cid:1)133 Feedback,10 parameter, 207 integrated circuit itself, Feedback,negative, 1 gain marginparameter, 200 130(cid:1)131 Feedbackresistor,10 large-signal voltage integrated circuit Feedbackresistorshorted, amplification gain package, 131 185(cid:1)187 condition, 202 temperature, 127(cid:1)130 Feedbacksystem analysis open-loop voltage gain, final parameter comments, historically,2(cid:1)5 200(cid:1)202 129(cid:1)130 stability “Gain” resistor, 10 high temperature, calculating historically,2 George A.Philbrick degradationat, 129 Feedbacksystems Research, 3 noise, 128 design, historically,2 Global System for Mobile outputdrive andstage, Filter, definitionof, 73 Communications (GSM) 129 Filter circuits,73 Cellular BaseStation speed,128(cid:1)129 Filter Pro, 164(cid:1)167 Receiver, 113f time,extremeduration in, Fliege filter topology, 84 Grounding consideration in 135(cid:1)136 Fluxresidue, 252 PCB design, 241(cid:1)244 Index 277 H Input voltage range condition Low-powerconsumption, orparameter, 217(cid:1)218 127 Harmonic distortion parameters, 215(cid:1)216 Instabilityeffect, 2 LT Spice,174(cid:1)176, 176f Instrumentation amplifier, Heatsinking, 133 53(cid:1)55 M High meltingpoint (HMP) solders, 132(cid:1)133 Integratedcircuit(IC),4(cid:1)5, Manufacturer design aids, 161 119, 130(cid:1)131 High-pass filter design aids, Analog Devices OpAmp 98(cid:1)101 at high temperature, 129 Error Budget, packaging, 130(cid:1)133 High-speed analog inputdrive 173(cid:1)174 circuits, 117(cid:1)118 Integratedvoltage regulators, Linear Technology LT 140(cid:1)141 High-speed bridgedhybrid Spice,174(cid:1)176 amplifier, 159f Intermediate-frequency (IF) National Semiconductor/ amplifiers, 116 High-speed filter design, Texas Instruments 85(cid:1)88 Inverted voltage reference Webench, 167(cid:1)170 bandpassfilters, 86(cid:1)88 circuit, 263 NI Multisim,analog devices Inverting op amp, 12 high-pass filters, 86 versionof,171(cid:1)173 low-passfilters, 86 K Printed Circuit Board notch filters, 88 Layout, 176 Kirchoff’svoltage law, 12 Hybridamplifiers andpower Texas Instruments Filter Pro, boosters, 156(cid:1)160 L 164(cid:1)167 I Texas Instruments Tina-TI, Lead temperature for 10or 60 IC op amp, 4, 254(cid:1)255 seconds,225 162(cid:1)164 Mars Rover, 135(cid:1)136 Image plane effect,240 Least significantbits(LSBs), Improper decoupling,192(cid:1)194 125 µA709, 4 Inductors, 246(cid:1)247,250(cid:1)251 Linear Technology LT Spice, µA741, 4 Input bias current parameter, 174(cid:1)176,176f Multiple-notch andsingle- amplifier notchfilters, 208 Linear voltage regulator, Input capacitance parameters, 141(cid:1)143 95(cid:1)96, 95f 203(cid:1)204 Loadcapacitance condition, Multiple-peak and stagger- tunedbandpass filters, Input common-modevoltage, 205 121(cid:1)124 Loadresistance condition, 91(cid:1)95, 94f Input current range parameter, 212(cid:1)213 Multisim,171(cid:1)173 207 Loop antenna, 248(cid:1)249 N Input noisecurrent parameter, Loop gain, 46 209 Low voltage amplifier circuit Narrow vs. wide bandpass Input offset current parameter, design filter, 83 208 dynamic range, 121 National Electrical Input offset voltage long-term input common-moderange, Manufacturers drift parameter,224 121(cid:1)124 Association (NEMA), Input offset voltage parameter, outputvoltage swing, 237 219(cid:1)220 120(cid:1)121 National Semiconductor, Input resistance parameter, signal-to-noiseratio, 167(cid:1)170 211(cid:1)212 124(cid:1)125 Negative feedback, 1 differential, 212 Low-pass filter design aids, NI Multisim,analog devices Input voltage condition, 219 98(cid:1)101 versionof,171(cid:1)173 278 Index Noise.See also specific types unused sections,183(cid:1)185 integrated circuit itself, colors,229(cid:1)230 Op amp oscillators, 153(cid:1)156 130(cid:1)131 isolation, 255 OPA277, 156(cid:1)157 integrated circuit package, op amp, 230(cid:1)231 OPA512, 156 131 root mean squarevs. peak- Open-loopgain, 10 Pass transistor,142(cid:1)143, to-peak noise,226 Open-loopparameter 145(cid:1)146 sources,227(cid:1)228 transimpedance, 222 PCB (printed circuit board) sources,236(cid:1)237 transresistance, 213 design,132,172(cid:1)173, spreadsheet, 233 voltage gain,200(cid:1)202 176 units, 228 Operating free-air temperature basics, 235(cid:1)237 Noisebudget,225(cid:1)226 condition,214 decoupling, 252(cid:1)255 Noisecorner frequency, 230 Oscillator error correction,236 Noiseenergy,227f comparator oscillator example,243(cid:1)244 Noisefigure, 111 analysis,155f grounding, 241(cid:1)244 Noisefloor, 226 outputs, 154f input andoutputisolation, Noiseparameters schematics,154f 255(cid:1)256 equivalent input noise Output current condition, low mechanical characteristics, voltage,220 level, 209 237(cid:1)240 input noise current,209 Output current parameters, 209 packages, 256(cid:1)258 total harmonic distortion short-circuit,209(cid:1)210 passive component selection, plus noise (THD1N), Output drive and high 244(cid:1)252 216 temperature, 129 summary,258(cid:1)259 Noisetheory Output impedance parameter, Peak-to-peak noise vs.root application example, 222 meansquare,226 231(cid:1)233 Output resistance parameter, Peak-to-peak outputvoltage characterization, 226(cid:1)228 213 swing conditionor Non-inverting op amp, Output voltage parameters parameter, 221(cid:1)222 11(cid:1)12 high-level,221 Phase linearity, toRF design, Notchfilter design aids, 101 low-level,221 109 Notchfilter response, 88,89f Output voltage swing Phase margin parameter, Notchfilters, 84(cid:1)85, 85f parameters 223 and bandpass,combination maximum peak-to-peak, Pink noise, 230 of,97 221 Powerboosters, hybrid Nullresistancecondition, peak-to-peak, 221(cid:1)222 amplifiers and, 213 Output voltage swing, 156(cid:1)160 O 120(cid:1)121 Powerdissipation parameter, Overvoltage protection, 210 Ohm’slaw, 7 144(cid:1)145,145f Powersupplyinformation, Op amps. See also specific P 65(cid:1)66 types Powersupplyrejection ratio differential vs.single Packaging, 130(cid:1)133 parameter, 210 ended, 3 integrated circuit, Precisionrectifier circuit, functionsof,5 connecting, 130(cid:1)133 264(cid:1)265 operated at less than unity, component retention, 133 Q 179(cid:1)180 printed circuit board packages, 256(cid:1)258 design, 132 Quadsupply opamp packages, stability,4 solders, 132(cid:1)133 256(cid:1)257 Index 279 R Semiconductor companies, Single-ended termination, 47 190(cid:1)191 Radiated noise,237, 255 Settling time parameter, Single-supply design, 126 Radiofrequency (RF) design, 216(cid:1)217 Single-supply inverting op amp 105 21dB compression point, Short-circuit current duration, circuit,20(cid:1)21,20f 109(cid:1)111 224 Single-supply non-inverting op Short-circuit outputcurrent amp gain circuit, 21, amplifier topology, 106(cid:1)108 parameter,209(cid:1)210 21f Shotnoise,226 Slew rate parameter, 213(cid:1)214 frequency response peaking, Shutdown parameters Sn60Pb40solder, 132 109 turn-offtime, 215 Sn96Ag04 solder, 132(cid:1)133 high-speed analog input drivecircuits, 117(cid:1)118 turn-offvoltage, 219 SNR (signal-to-noise ratio), turn-ontime,215 124(cid:1)125, 227 noise figure, 111 turn-onvoltage, 219 Solders,132(cid:1)133 phase linearity, 109 stage gain, 108(cid:1)109 Signal source condition, 213 Spice models, 161 Signal-to-noise ratio (SNR), Spice simulation programs, voltage feedback/current feedback, 105(cid:1)106 124(cid:1)125 172(cid:1)173 wirelesssystems, 111(cid:1)116 Simulatedinductor, 261(cid:1)263 Split-supply opamp circuit, 19, Single supply amplifier 20f broadband amplifiers, 113(cid:1)116 dual supply vs.,19(cid:1)22 Stage gain,108(cid:1)109 Single supply amplifier design Stagger-tuned and multiple- intermediate-frequency application mistakes, peak bandpassfilters, amplifiers,116 190(cid:1)191 91(cid:1)95, 94f Rail-to-rail input (RRI), 122, designprocedure for, Step voltage peak-to-peak 126 36(cid:1)40 condition, 222 Rail-to-rail input/output incorrect single-ended Storage temperature parameter, (RRIO), 124 termination, 190(cid:1)191 217 Rail-to-rail op amps, 129 simultaneous equationcase Superposition, 9(cid:1)10, 13 Rail-to-rail output (RRO), 120(cid:1)121, 120f, forms, 22(cid:1)34 Supply current parameter, 123(cid:1)124, 126 summary, 40(cid:1)41 207 Single supply amplifier shutdown, 207 Red/brown noise,230 packages,256 Supply rejection ratio Redundancy, 135 Reflections, 249(cid:1)250 Single supply circuits parameter, 210 Resistors, 244(cid:1)245 AC toDC converter,265 Supply voltage condition,217 RF design see Radiofrequency constant current generator, Supply voltage sensitivity, 263 205(cid:1)206 (RF)design curve fitting filters, 268(cid:1)271 Surface acousticwave(SAW) Rise time parameter,216 fullwave rectifier, 265 filters, 116 Rootmean square vs. peak- inverted voltage reference, Switching power supplies, to-peak noise,226 263 143(cid:1)144 RRO (railto rail output), 120(cid:1)121, 120f, precisionrectifier, 264(cid:1)265 T 123(cid:1)124, 126 stoimneulcaotendtroinl,d2u6c5to(cid:1)r,226681(cid:1)263 Teardropping, 238(cid:1)239 S Single-amplifier notch and Temperature extremes, Sallen(cid:1)Key low-passfilter, 74, multiple-notch filters, 127(cid:1)130 74f, 90, 166 95(cid:1)96,95f degradationat, 129

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Op Amps for Everyone is an indispensable guide and reference for designing circuits that are reliable, have low power consumption, and are as small and low-cost as possible. Operational amplifiers are essential in modern electronics design, and are used in medical devices, communications technology,
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Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.