Mi 7529237 0023060 6 my 1-74-0% SGS-THOMSON __LM124,A-LM224,A ky MICROELECTRONICS LM324,A-LM2902 S$ G S=THOMSON JOE D LOW POWER QUAD OPERATIONAL AMPLIFIERS a LARGE VOLTAGE GAIN : 100 dB VERY LOW SUPPLY CURRENT/AMPLI 375 a LOW INPUT BIAS CURRENT : 20 nA 1 a LOW INPUT OFFSET VOLTAGE : 2 mV fh a LOW INPUT OFFSET CURRENT : 2 nA D WIDE POWER SUPPLY RANGE : pidaa sot - SINGLE SUPPLY :+3VTO+30V ; ic Mh : (Plastic Package) (Plastic Micropackage) - DUAL SUPPLIES :41.5VTO+15V J CERDIP14 Oo (Cerdip Package) "ing ac LCC20 (Tricecop (LCC)) DESCRIPTION ORDER CODES These circuits consist of four independent, high Part Temperature Package gain, internally frequency compensated operational Number Range n|1ulaclop amplifiers which were designed specifically for auto- L124 BC ischelelele motive and industrial control systems. They operate CMD an ~ * C e * toe clele . from a single power supply over a wide range of vol- LM324.A ~ 0c o. C0 C ele . tages. Operation from split power supplies is also LM2902 ~ 40C oe 405C} | e possible and the low power supply current drain is independent of the magnitude of the power supply Note : Hi-Rel Versions Available voltage. Examples : LMi24J, LM124GC, LM224N PIN CONNECTIONS (top views) DIP14/CERDIP14 LCc20 $o14 ig er 14 aS ighs 3 iB i 12 4 q i 11 5 og ry 10 6 rt Lh Mos CRD Ng 3- Inverting input 1 13 - Inverting input 3 1 - Output 1 8- Output 3 4 - Non-inverting input 4 14- Non-inverting input 3 2- Inverting input 1 9 - Inverting input 3 5-NC 15- NC 3- Non-inverting input? 10 - Non-inverting input 3 6 - Vic 16 - Vee 4- Vee 11- Veco 7-NC 17-NC - Non-inverting input 2 12 - Non inverting input 4 8 - Non-inverting input 2 18 - Non-inverting input 4 6 - Inverting input 2 13 - Inverting input 4 9 - Inverting input 2 19 - Inverting input 4 7- Output 2 14 - Output 4 10- Output 2 20 - Output 4 December 1988 14 467LM124,A-LM224,A-LM324,A-LM2902. gm 7929237 0023061 T - mr To sae mentee eer RY ABSOLUTE MAXIMUM RATINGS SG S-THOMSON T~79-~08 Oe D Symbol Parameter LM124,A eee LM324,A_ | Unit Veo Supply Voltage + 16 or 32 Vv Vi Input Voltage 0.3 to + 32 V Via Differential input Voltage +32 + 32 + 32 Vv ; Ptot | Power Dissipation N, J Suffix 500 500 500 mw GC Suffix 665 D Suffix 400 400 Output Short-circuit Duration Indefinite lia Input Current (note 6) 50 50 : 50 mA Toper | Operating Free Air Temperature Range -55to+125/-40to+105| Oto+70 C Tstg Storage Temperature Range 650 150 | -65to 150 | 65 to 150 C SCHEMATIC DIAGRAM (1/4 LM124) Inverting input Non-inverting input +] ve ie] a6 2 kN a? Ag Ra . C] Output 17] fers {] Yee EesLM124-01 inverting |Non-inverting - Case inputs inputs Voc Vdeo Outputs N.C. DIP14 CERDIP14 2,6, 9, 13 3,5, 10, 12 11 4 1,7, 8, 14 $014 Lcc20 3,9,18,19 | 4,8, 14, 18 16 6 1, 2, 12, 20 , * LCC20 : Other pins are not connected. arta f scs- ON yf SGS-THOMSON 468ME 7929237 O0230b2 1 LM124, A-LM224,A-LM324,A-LM2902 ELECTRICAL CHARACTERISTICS *S & S=THOMSON 30E D Vdc =+ 5 V, Vac = Ground, Vo = 1.4 V LM324, A 290 : 0< Tam $+ 70C __ 7 LM224, LM2902 : ~ 40 <Tamp < + 105 C . LM124, A = 55 <Tamp < +125 C T~79-08 (unless otherwise specified) LM124A, 224A LM124, 224 Symbol Parameter 324A 324, 2902 Unit Min. | Typ. | Max. | Min. | Typ. | Max. Vio Input Offset Voltage (note 3) mV Tamb = + 25 C 2 3 2 5 Tmin S Tamb S Tmax 5 7 lio Input Offset Current nA Tamb = + 25 C 2 20 2 20 Tmin S$ Tamb <= Tmax 40 40 lip Input Bias Current (note 2) nA Tamb = + 25 C 20 400 20 100 Tmin S$ Tamb S Tmax 200 200 Avo Large Signal Voltage Gain VimV (Vdco=+15V, RL =2 kQ) (Vo = 1.4 V to 11.4 V) Tamb = + 25 C 50 100 50 100 Tmin S Tamb S Tmax 25 25 Sva Supply Voltage Rejection Ratio (Rs < 10 kQ) dB Tamb = + 25 C 65 110 65 110 Tmin $ Tamb < Tmax 65 65 * lec Supply Current, all Amp, no Load mA Tamb = + 25 C Voc=+ 5V 0.7 1.2 0.7 1.2 Voc =+ 30 V 1.5 3 1.5 3 Tmin S Tamb S$ Tmax Veco=+ 5V 0.8 1.2 0.8 1.2 Voc =+30V 1.5 3 1.5 3 Vi Input Voltage Range (note 4) Vec Voc Vv Tamb = + 25 C Veco =+30V 0 -15 0 -15 Tmin $ Tamb S Tmax 0 Yee 0 Yee CMR | Common-mode Rejection Ratio (Rg < 10 kQ) dB Tamb = + 25 C 70 80 70 80 Tmin $ Tamb Tmax 60 60 lo Output Short-circuit Current mA (Vi =+1V, Vi =0V, Veco =+ 15 V) Tamb = + 25 C 20 40 60 20 40 60 Tmin < Tamb S Tmax 10 10 Isink Output Current Sink (Vi =-1 V, Vr =0 V) Veo =+15V Tamb = + 25 C 10 20 10 20 mA Tmin S Tamb S Tmax | 10 10 Vo =+0.2V Tamb = + 25 C 12 50 12 50 pA Tmin S$ Tamb < Tmax 12 12 Vopp | Output Voltage Swing : Voc Voc V Tamb = + 25 C Ri 2 2 kQ 0 -~415 0 -15 Tmin S$ Tamb S Tmax Rp 2>2kQ 0 Veo 0 Vee (7 SGs-THoMson a4 Y/ iencmzcracn:cs | 469LM124,A-LM224,A-LM324,A-LM2902_ MM 7427237 0023063 3 We 470 SG S-THOMSON~--------- 90E D ELECTRICAL CHARACTERISTICS (continued) T-79-~08 LM124A, 224A LM124, 224 Symbol Parameter 324A 324, 2902 Unit ; Min. | Typ. | Max. | Min. | Typ. | Max. Vou High Level Output Voltage Vv (Voc = +30 Vv) Tamb = + 25 C RL =2kQ 26 27 26 27 Tmin S$ Tamb S Tmax 26 26 Tamb = + 25 C Re = 10 kQ 27 28 27 28 7 Tmin S Tamb S Tmax 27 27 - VoL Low Level Output Voltage Vv (RL s 10 kQ) 7 Tamp = + 25 C 5 20 5 20 Tmin S$ Tamb S Tmax 20 20 Svo Slew-rate (V; = 0.5 to 3 V, Rp = 2 kQ Vis CL < 100 pF, Tamp = +-25 C, unity gain Veco = 15 V) 0.2 0.4 0.2 0.4 GBP | Gain Bandwidth Product, Voo = 30 V MHz (f = 100 KHz, Tamp = + 26 C, Vin = 10 mV Ri =2 kQ, CL = 100 pF) 0.7 1.3 1.8 0,7 1.8 18 - THD | Total Harmonic Distortion % (f= 1 kHz, Ay =20 dB, RL =2kQ, Vo =2 Vpp OL < 100 pF, Tamb = + 25 C, Veco = 30 V) 0,015 0.015 Vn Equivalent Input Noise Voltage nVAHz (f = 1 kHz, Rg = 100 Q, Voc = 30 V) 40 40 DVio | Average Temperature Coefficient Wve of Input Offset Voltage Tmin S Tamb S Tmax 7 30 7 30 Dlio | Average Temperature Coeff. parc of Input Offset Current . Tmin S$ Tamb S Tmax 10 300 10 300 Vot/Vo2| Channel Separation (note 5) dB 1 kHz <f < 20 kHz 120 120 . Notes: 1. Short-circuits from the output to Vee can cause excessive heating If Vec > 15 V. The maximum output current is approximatively 40 mA independent of the magnitude of Voc. Destructive dissipation can result from simul- taneous short-circuits on all amplifiers. 2. The direction of the input current is out of the IC. This current is essentialy constant, Independent of the state of the output so no loading change exists on the input lines. 3. Vo=1.4V,Rs=0,5V < Veo <30V,0<Vi< Veo-1.5V. 4. The input common-mode voltage of elther input signal voltage should not be allowed to go negative by more than 0.3 V. The upper end of the common-mode voltage range is Vcc - 1.5 V, but either or both inputs can go to + 32 V without damage. 5. Due to the proximity of external components insure that coupling Is not originating via stray capacitance be- tween these external parts. This typically can be detected as this type of capacitance increases at higher fre- quences. 6. This input only exist when the voltage at any of the input leads Is driven negative. It Is due to the collector- base junction of the input PNP transistor becoming forward biased and thereby acting as input diode clamps. In addition to this diode action, there is also NPN parasitic action on the IC chip. This transistor action can cause the output voltages of the Op-amps to go to the Vcc voltage level (or to ground for a large overdrive) for the time duration than an input is driven negative. This is not destructive and normal output will set up again for input voltage higher than ~ 0.3 V. 44 [7 SGSTHOMSON Vf wicronecteeaesMe 7929237 0023064 5 LM124,A-LM224,A-LM324,A-LM2902 S G S-THOMSON 30E D INPUT BIAS CURRENT CURRENT LIMITING (Note 8) vs AMBIENT TEMPERATURE MITING (Note IIB (nA) 24 0 T-79-08 21 80 18 70 wT -_ 8 15 q 60 wv = N 12 5 a z= 40 = 9 = = > 30 wd 6 oO 5 2 3 a 2 10 0 55-35-15 5 25 45 65 85 105125 4 -65 -35-15 5 25 45 65 85 105 125 AMBIENT TEMPERATURE (C) EBaLMi24-02 TEMPERATURE (C) E88LM124-03 INPUT VOLTAGE RANGE . SUPPLY CURRENT 15 4 Vc : mA ,'D _ z3 = 40 ~ 4 E y . J 5 5 Negative 2 g Positive 2 55 TP > = 2 / a Tamb 20C to +125C 2 a. 2 oY Tomb = 85C a 5 10 15 0 10 20 30 POWER SUPPLY VOLTAGE (V) POWER SUPPLY VOLTAGE (V) E88LM124-04 E88LM124-05 GAIN BANDWIDTH PRODUCT a COMMON-MODE REJECTION RATIO $y GBP (MHz) =S 120 = = 1.35 z 5 1.30 eq 10 R125 3 2 12 5 * o , 2 x 1.15 a 60 Ee Q Ww wi a = 1.05 qo ae 3 3S 5 2 z 95 = = = 3 o 0 9 55 -35 -15 5 25 45 65 85 105 125 AMBIENT TEMPERATURE (C) . FREQUENCY {Hz} E68LMi24-06 E88EM124-07 -THOMSO 5/14 ki SGS THOMSON 4713? G02e30b5 7 a ~~ LM124,A-LM224,A-LM324,A-LM2902. Ml 7929 SG S=THOMSON. 30E D OPEN LOOP FREQUENCY RESPONSE --.-. . --. -..-------- LARGE SIGNAL FREQUENCY RESPONSE 140 10M , 0.1 uF 120 9 Veco a a \ e o om AS & 10 fN \ _ z 5 + . 2 =z N Ved2--"e o \ vdo=+30V & z= 10 @ 60 AK 55C <Tamb< + 125C = NY a 40 | 4-4 5 > AA 5 5 2 Nc= +10 to +16V & 3 -56C<Tamb< + 125C N a Q poi b a 10 10 100 10h 10k 100k 1.0 10M 1k 10k 100k 1M FREQUENCY (Hz) FREQUENCY (Hz) . E@6LM124-08 . E88L.M124-09 a VOLTAGE FOLLOWER PULSE RESPONSE OUTPUT CHARACTERISTICS 7 S (CURRENT SINKING} a 10 " g RL 22 ka Vc+ +8V 5 Vc= +18 V Vee= +15 ; 9 s Vde=t+HV 5 wf 3 a +/2 : g vd 2 5 oa g & . < 2 Jo 5 9 r fa > > T 7 oot z 10 20 30 ag 0001 oof D1 61) 610 100 ~ TIME (ys) OUTPUT SINK CURRENT (mA! : E@8LM124-10 EseLM124-11 a VOLTAGE FOLLOWER PULSE RESPONSE OUTPUT CHARACTERISTICS Lot (SMALL SIGNAL} (CURRENT SOURCING) Ss 8 > 7 7 = 450 tle oO E 1 F 6 Yc? wD SO pF & ag al Ty Qo , < q =] z E L i 3 * input c 4 > : L 350 ti 2 \ Output uw 3 a E y g 2 o 30 Tomb = + 25C a 2 Vcg= +30V > 250 & 1 8123 4 5 6 728 @ ooo oot O11 10 100 - ~ TIME (us) _ QUTPUT SOURCE CUARENT (mA) E88LM124-12 E88LM124-13 6/14 Gy SGS-THOMSON If ticrosectmoatcs 472Mm 7929237 0023066 7 LM124,A-LM224,A-LM324,A-LM2902 SG S=THOMSON 30E D T~79-08- INPUT CURRENT VOLTAGE GAIN 100 R, =20k2 zs 120 a 5 = =2kn Ww = = 50 g 80 g kK 2 ke 25 = 2 9 0 10 20 0 0 10 20 0 POWER SUPPLY VOLTAGE (V) POWER SUPPLY VOLTAGE (V) ESSLM124-14 E@eLMi24-15 POWER SUPPLY & COMMON MODE LARGE SIGN LTAGE REJECTION RATIO wv Po ana a w (4B) 120 8 115 z oa 110 6 za S~ tos g " LL =o 5 | OE 100 a LL Ce > 410 ba} a 95 4 Ll >5 90 3 L| 8 as 2 c a5 Go LL Su 85 @ 105 Gy 80 o ro fz z = 7 4 9 70 100 a. -55-95-15 5 25 45 65 85 105 125 -55 -35-15 5 25 45 65 80 105125 AMBIENT TEMPERATURE (C) AMBIENT TEMPERATURE (C) EeslMi24-16 88LM124-17 (7 8GS-THOMSON wN4 YF insromestzomes 473LM124,A-LM224,A-LM324.A-LM2902 Ml, 7929237 00230670 om "3S G S~THOMSON JOE D TYPICAL SINGLE - SUPPLY APPLICATIONS nr rar, AC COUPLED INVERTING AMPLIFIER T-79-08 8 +I Aya (As shown Ay = 10) Ri Ri 100 k2 c R 1 40ko }-c+ ro -o| 9 Re RL 6.2k2 10 ks. vit, R2 R3 CC 100 ka 100 ka OoC_+- ci 10 pF oe Ww E8s8LMi24-18 AC COUPLED NON-INVERTING AMPLIFIER 9 RL 10 ks2 A =? Vpp FF ESLM124-19 8/14 474 ii SGS-THOMSON MICROELECTRONICSME 7929237 0023068 2 MM _LM124,A-LM224,A-LM324,A-LM2902 a, TYPICAL SINGLE - SUPPLY APPLICATIONS (continued) 1-79-08 NON-INVERTING DC GAIN S G S=-THOMSON 3J0E D = Ra Ay=it a (As shown Ay = 101) 10 kx e . oO a 4 R2 TMQ = 8 | Ri 10 kX mr ; ej (mv) 88LM124-20 DC SUMMING AMPLIFIER A 100 kx oT , p>O 0 eg 100k2 Oo1 + 100 k2 1 & 100 kz 100 kQ. 4 [_) ego=e, + 2 - e3 - &4 100k: where (e, + e7)>(e3 + e4) to keep eg 20 V E98LM124-21 9/14 Ky7 S&STHOMSON 475LM124,A-LM224,A-LM324,A-LM2902 MM 7929237 0023069 4 TYPICAL SINGLE SUPPLY APPLICATIONS (continued) T~79~08 HIGH INPUT Z ADJUSTABLE GAIN DC INSTRUMENTATION AMPLIFIER if Ri = Rs and Rs = Ra = Re = R 8S G S=-THOMSON J0E D 2Ri eo= (15 7) (e2 - 1) at As shown @o = 101 (e2- e1) ton ke R3 R4 100 kn 100 kn E88LM124.22 LOW DRIFT PEAK DETECTOR +810 4 Hr wr <~_. . ANN Ty input current * Polycarbonate or polyethylene compensation E88LMi24-23 1on4 [7 SGS-THOMSON VF tcroauscizox:33 476We 7929237 0023070 0 LM124,A-LM224,A-LM324,A-LM2902 TYPICAL SINGLE SUPPLY APPLICATIONS (continued) ACTIVE BANDPASS FILTER R1 100 kQ SG S-THOMSON JOE D T-79-08 Q=50 Av = 100 (40 dB) ova On oe N MS E88LM124-24 TH 1414 hy SSeces 477LM124,A-LM224,A-LM324,A-LM2902 MM 7929237 o023071 c TYPICAL SINGLE SUPPLY APPLICATIONS (continued) T~79-08 HIGH INPUT Z, DC DIFFERENTIAL AMPLIFIER Ri = For Re i (CMRR depends on this resistor ratio match) Ra R2 R4 eo= (1+ Bop (e2-e1) 100 ka 100 ks Ri As shown o = 2 (62-1) 100 ka 1/4 LM124 3 {00 k2 V4 rer O14 LM124 *0 +82 O- $$$ _______/+ SG S-THOMSON JOE D EeBLM124-25 USING SYMMETRICAL AMPLIFIERS TO REDUCE INPUT CURRENT (GENERAL CONCEPT) ip Aux. amplifier for Input current compensation . E@8LM124-26 ter4 (57 SGS-THOMSON Y/ iasnouzcrones 478Mme 7929237 O0es072 4 LM124,A-LM224,A-LM324,A-LM2902 PACKAGE MECHANICAL DATA SG S-THOMSON JOE D 14 PINS N SUFFIX PLASTIC PACKAGE J SUFFIX CERDIP PACKAGE T-79~08 mm ni & e e e e e one e__ 8.5 max. Fl t = t ; 0,51 min. 5.08 max} if] [7] [2 fT) yer F 7aUeUalla lation Pattie He n Ye | / \ , : ; i ! : 02 i 31 0,38 177 mox. 03 | 7.62 39 0.508 _ (2) . mrs: 14 8 O64 6 rd od) Datum (1) Nominal dimension a a ~~ ~ {2) True geometrical position , A LIC UI OY Ly 3" 19.9 max. 6.3> 0) 1 4 PINS 14 PINSD SUFFIX PLASTIC MICROPACKAGE. mm e= 1.27 egeyeezpegqe 0.185 | 0.265 1 1 I t 1 1 ' 0:63 | | | max. 0.4 i j ' | : : : min. 14 8 | 59. 39 0.1 6.2 4,0 0.2 P} Z | patum/ 0.35 0.4 0,45 min. 8.55 1.75 max. 8,75 14 PINS S- so 13/14 ky Scs THOMSON 479S G S-THOMSON JOE D PACKAGE MECHANICAL DATA (continued) 20 PINS - GC SUFFIX TRICECOP (LCC) en J-79-08 _ mm 8,74 "1,86 max, 1,27 9.04 14 18 13 9 | Output n?1 -|- a | 2.16 0.64 9 3 8 4 e2127 lelolele Datum 8.74 9.04 20 PINS 44/14 . 480