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Thank You 400 Amherst Street, Suite 301 Nashua, NH 03063If SGS-THOMSON MICROELECTRONICS LM158/A - LM258/A LM358/A - LM2904 | LOW POWER DUAL OPERATIONAL AMPLIFIERS a INTERNALLY FREQUENCY COMPENSATED ia LARGE DC VOLTAGE GAIN : 100dB ja WIDE BANDWIDTH (unity gain) : 1.1MHz (temperature compensated) " VERY LOW SUPPLY CURRENT/AMPLI | (500A) - ESSENTIALLY INDEPENDENT OF | SUPPLY VOLTAGE = LOW INPUT BIAS CURRENT : 20nA | (temperature compensated) ls LOW INPUT OFFSET VOLTAGE : 2mV ia LOW INPUT OFFSET CURRENT : 2nA ja INPUT COMMON-MODE VOLTAGE RANGE | INCLUDES GROUND ia DIFFERENTIAL INPUT VOLTAGE RANGE | EQUAL TO THE POWER SUPPLY VOLTAGE is LARGE OUTPUT VOLTAGE SWING OV TO (Voc 1.5V) i i 1 ] DESCRIPTION These Circuits consist of two independent, high gain, internally frequency compensated which were lesigned specifically to operate from a single power Nooy over a wide range of voltages. The low power upply drain is independent of the magnitude of the ower supply voltage. lication areas include transducer amplifiers, dc pain blocks and ail the conventional op-amp circuits hich now can be more easily implemented in single bower supply systems. For example, these circuits tan be directly operated off the standard + 5V power bupply voltage which is used in logic systems and Will easily provide the required interface electronics without requiring any additional power supply. In the linear mode the input common-mode voltage jange includes ground and the output voltage can also swing to ground, even though operated from N Oo DIPS sos (Plastic Package) (Plastic Micropackage) J CERDIPS (Cerdip Package) a TOS9 (Metal Can) ORDER CODES Part Temperature Package Number Range HINI|I JID LM158/A 88C, +125C . . LM258/A 40C, +105C e/ ee] e]e LM358/A 0C, +70C |e) ee] e LM2904 40C, +105C o| oe] el] e Examples : LM158H, LM258N, LM2904D PIN CONNECTIONS (top views) Toss DIPS/CERDIPS soe 1 q 7 He 2 dp 7 3 kp 6 4d Js 158-01.EPS 158-02.EPS 1 - Output 1 5 - Non-inverting input 2 nly a single power supply voltage. 2 - inverting input 1 6 - Inverting input 2 e gain-bandwidth product is temperature 3 - Non-inverting input 1 7 - Ouput 2 bompensated. 4- Voc" 8 - Voc" November 1992 M2 | 395 158-01.TBLLM158,A - LM258,A - LM358,A - LM2904 SCHEMATIC DIAGRAM (1/2 LM158) Inverting input a1 Cc ait S Output Non-inverting input O} tor 2 as as 50 pA g RT ENT ARN GND 159-03.EPS ABSOLUTE MAXIMUM RATINGS Symbol Parameter LM158,A nary LM356,A | Unit Vee Supply Voltage +32 +32 +32 Vv Vi Input Voltage : 0.3 to +32 0.3 to +32 0.3 to +32 v Via Differential Input Voltage +32 +32 +32 Vv Output Short-circuit Duration - (note 2) Infinite Prot Power Dissipation 500 500 500 mw lin Input Current - (note 1) 50 50 50 mA Toper | Operating Free-air Temperature Range -5 10 +125 | 40 to +105 0 to +70 C Tsig | Storage Temperature Range -65 to +150 | -6510+150 | -65 to +150 C ane &y7 SSS:THOMSON Y, MICROELECTROMICS 396LM158,A - LM258,A - LM358,A - LM2904 pect RICAL CHARACTERISTICS co = +5V, Voc = Ground, Vo = 1.4V, Tamb = 25C (unless otherwise specified) Symbol Parameter LM158A LM258A LM358A LM156 - LM258 LM358 - LM2904 TyP-| Max. Typ. Unit Vio Input Offset Notage - (note 3) Tamb = LM158, LM258 LM158A LM158, LM258 Tmin. S Tamb < Tmax. mV Input Offset Current Tamb = 25 Cc Tmin. S Tamb Tmax. nA lin Input Bias Current - (note 4) Tamb = 25C Tin. S Tamb S Tmax. 20 50 20 Large Signa! Voltage Gain (Veco = +15V, f= 2kQ, Vo = 1.4V to 11.4V) Tamb = 25C Tmin. S Tamb < Tmax. 100 RS 100 VimvV SVR Supply Volta 10 $0) Rejection Ratio (Rs = 10k) (Vec* =5to Tamp = 25 o Tin. < Tamb S Tmax. 100 RE 100 dB Iec Supply Current, all Amp, no Load Voc = +5V, Tmin. S Tamb S Tmax. Voc = +30V, Tmin. S Tamb S Tmax. 0.7 1.2 0.7 1.2 Viem 0 ut Common Mode Voltage Range oc= +30V) - (note 6) Tam = 25C Tin. < Tamb < Tmax. Veo*-1.5 Vec*-2 Vec*-1.5 Voc*-2 CMR Common-mode Rejection Ratio (Rs = 10kQ) Tamb = 25C Tin. S$ Tamb < Tmax. 70 85 70 85 dB Output Short Circuit Current (Voc = +15V, Vo = 2V, Vig = +1V) 20 20 40 60 Isink Output Current Sink (Vig = -1V) Voc = +15V, Vo = 2V Voc = +15V, Vo = +0.2V 10 12 20 50 10 12 Vopp Output Voltage Swing (Ri = 2kQ) Tamb = 25C Tin. S Tamb S Tmax. Veco*-1.5 Vec*-2 Vec*-1.5 Vec*-2 </53 Vou High ten Level =e. Voltage (Vec* = 30V) Ri = 2kQ ia < S Tmax. Tamb = pees Ru = 10kQ Tin. < Tamb $ Tmax. 27 28 27 +28 Vor Low Level Quiput Voltage (RL = 10kQ) Tamb = 25 Tmin. & Fone S Tmax. mV SR Slew Rate (Vcc = 15V, Vl = 0.5 to 3V, RAL = 2kQ, Ci = 100pF, Tamp = 25C, unity gain) 0.3 0.6 0.3 0.6 Vips 12 397 158-03. TBLLM158,A - LM258,A - LM358,A - LM2904 ELECTRICAL CHARACTERISTICS (continued) LM158A LM158 - LM258 LM258A LM358 - LM2904 Symbol Parameter LM358A Unit Min. | Typ. | Max. | Min. | Typ. | Max- GBP Gain Bandwidth Product MHz (Vcc = 30V, f = 100KHz, Tam = 25C, Vin = 10MV, RL = 2kQ, Cr = 100pF) 0.7 11 0.7 14 THD | Total Harmonic Distortion % (f= 1kHz, Ay = 200B, RL = 2kQ, Vcc = 30V, 0.02 0.02 = 100pF, Tam = 25C, Vo = 2 pp) en Equivalent Input Noise voltage 7 AV (f = 1kHz, Rs = 100Q, Vec = 30V) 55 55 VHz DVio | Input Offset Voltage Drift 7 15 7 30 | pVfC Dlio Input Offset Current Drift 10 | 200 10 | 300 | pAfc Vo1/Vo2 | Channel Separation (note 5) dB 1kHz < f< 20kHz 120 120 Notes: 1. This input current only exist when the voltage at any of the input leads is driven negative. It is due to the colle: tor-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 caus the output voltages of the Op-amps to go to the Vcc voltage level! (or to ground for a large overdrive) for the tir duration that an input is driven negative. This is not destructive and normal output will set up again for input voltage higher than -0.3V. 2. Short-circuits from the output to Vcc can cause excessive heating if Vcc* > 15V. The maximum output current approximatively 40mA independent of the magnitude of Vcc. Destructive dissipation can result from simultaneot short-circuits on all amplifiers. 3. Vo = 1.4V, Rs = 09, 5V < Vec* < 30V, 0 < Vie < Voc 1.5V. 4. The direction of the input current is out of the IC. This current is essentially constant, independent of the state the output so no loading change exists on the input lines. 5. Due to the proximity of extemal components insure that coupling is not originating via stray capacitance betwee these external parts. This typically can be detected as this type of capacitance increases at higher frequences. 6. The input common-mode voltage of either input signal voltage should not be allowed to go negative by more tha 0.3V. The upper end of the common-mode voltage range is Vcc 1.5V. But either or both inputs can go to +32V without damage. 42OPEN LOOP FREQUENCY RESPONSE (Note 3) LM158,A - LM258,A - LM358,A - LM2904 LARGE SIGNAL FREQUENCY RESPONSE saad Toma | ca 0.1 uF 170 Voc 100 . yy 6 Yo 5 a Vec/2 2 3 N = *cc > ae > 3 vc Saye ey tose 8 56 + z Oo eCKT <+12 5 wi a o < NY 5 5s 2s 9 Vcc : +10 to +15v NN 5 2% 56C < Tamb< + 125C o } Urriit 3 10 18 106 1.0k 10k 108k 1.64 10m Vk 10% 180k FREQUENCY (Hz) FREQUENCY (Hz) VOLTAGE FOLLOWER PULSE RESPONSE OUTPUT CHARACTERISTICS > 18 ui 22k Vec=+5V 52 Vec=+15V Voc=+15V or s Voc =+30V 320 ~ : o> o 1 < 5 9 > = bE = = 0.1 < 3 e 25 0 25 ae 1 e 19 20 30 ac , 6.00) 601 01 1 19 TIME (us) OUTPUT SINK CURRENT (mA) COMMON-MODE REJECTION RATIO 120 or y COMMON-MODE REJECTION RATIO (dB) FREQUENCY iHz2} 158-05.EPS 158-04.EPS S12 a ky S68 Homs SON "LM158,A - LM258,A - LM358,A - LM2904 VOLTAGE FOLLOWER PULSE RESPONSE (SMALL SIGNAL) Ss OUTPUT CHARACTERISTICS soe 2 an Vv 2 aly Hh Yee TY . o ? at | il ; > 50 eo 4 r mes . E Bg bMcc/2 Vo | Ut w @ 50 pF 9 oO ey TIT z | . 2 a0 +4 iy [: FE z { & 5 WH. 7, 5 i wi | li : a ia: : Oo Input ky : ; > a 4nRy > r - + - 350 - on w 3 oO Independent of Vcc B Oretgaut 3k wi _.- ; Hy 5 00 N tI 4 & \ Tomb ~ *25C o Tamb = + 25C gS 2 ttt fob | Vec = +30V 5 Ye 258 a 1 tT ttt o 12 3 4 5 6 7 8 5 oo oo 01 1 12100 3 TIME (us) OUTPUT SOURCE CURRENT (mA) INPUT CURRENT (Note 1) CURRENT LIMITING [Note 1} t vj=0V a - z 70 q Vec=+30V 5 60 5 tf. ws x Voc = +15V x * i x cc a 4 3 e E . a 3 i > = ! : a Vec= +5V 2 2 + i ee : wEPa fa, |. ed Q l Ld ' S5 -35 -15 S 25 45 65 85 195 125 -55 -35-15 5 25 45 65 95 106 125 TEMPERATURE (C) TEMPERATURE (C) INPUT VOLTAGE RANGE SUPPLY CURRENT 15 a Vec | ! z mA |' | = | 3 w 10 - g I Yo - Negative 3 | - > | Positive 3 5 5 } > = 2; 5 Yo | z ' Tomb = O 10 +125C wa amy = 85C G 5 10 5 a 10 20 0 POWER SUPPLY VOLTAGE (+ V) POSITIVE SUPPLY VOLTAGE [V) 158-06.EPS | ! si2 G57 S6S:THOMSON MICROELECTRONICSLM158,A - LM258,A - LM358,A - LM2904 | VOLTAGE | GAIN INPUT CURRENT VOLTAGE GAIN (d8) INPUT CURRENT (nA) 6 10 2 3 a POSITIVE SUPPLY VOLTAGE (V) 0 10 2 w POSITIVE SUPPLY VOLTAGE (V} 158-07.EPS 158-08.EPS VOLTAGE GAIN GAIN BANDWIDTH PRODUCT 1.5 1.35 1.2 1.05 9 75 6 45 3 15 VOLTAGE GAIN (dB) GAIN BANDWIDTH PRODUCT (MHz) Q 0 0 2 30 55 -35 -15 5 25 45 65 85 105125 POSITIVE SUPPLY VOLTAGE [V) TEMPERATURE (C) 158-09.EPS 158-10.EPS POWER SUPPLY REJECTION RATIO COMMON MODE REJECTION RATIO 115 110 105 100 118 110 105 100 | i | i \ i \ ' j 95 90 85 95 90 85 80 80 75 70 65 75 70 65 690 POWER SUPPLY REJECTION RATIO (aB) COMMON MODE REJECTION RATIO (dB) -55 -35 -15 5 25 45 65 85 105 125 55-35-15 5 25 45 65 85 105 125 TEMPERATURE (C) TEMPERATURE (C) 158-11.EPS 158-12.EPS 72 f SGS-THOMSON Y2 iencevecrsemics 401LM158,A - LM258,A - LM358,A - LM2904 TYPICAL APPLICATIONS (single supply voltage) Vcc = +5Vpc AC COUPLED INVERTING AMPLIFIER Ay = = (As shown Ay =~ 10) R2 Veco 100k | 100Kn oL_14 __}_| Ri 100 kn c, 10 ka c Kg HR 6.2k2 10 KS? co ob 10 uF wr 158-13.EPS AC COUPLED NON INVERTING AMPLIFIER Gain = 1 + 2 tas shown, Gain = 11) Yo Ry 10 ks2 ~-=-. 2 Vpp + 158-14.EPS ai2 LT SES; THOMSONLM158,A - LM258,A - LM358,A - LM2904 TYPICAL APPLICATIONS (single supply voltage) Vec = +5Vpc (continued) NON INVERTING DC AMPLIFIER , R2 Ay = 14+ Rr Ay = 101 (As shown) 10 kQ Vv o-t 7+ Oo v v2 tov \ LM158 ro R2 1MmQ {4 = > R1 10 k2 v, (mv) 158-15.EPS DC SUMING AMPLIFIER V1 100k: v2 100 ki: 100 V3 100 k2 where Vo = V1+V2-V3-V4 (V1 + V2) > (V3+ V4) VS 1o0Kn to keep Vo > OV 158-16.EPS &7 POGROELECTIROGNCS 403LM158,A - LM258,A - LM358,A - LM2904 TYPICAL APPLICATIONS (single supply voltage) Vcc = +5Vpc (continued) HIGH INPUT IMPEDANCE, DC DIFFERENTIAL AMPLIFIER R2 R4 100kQ 100kQ Ri 100kQ . R3 41/2 100kKQ ~ 8 LM158 1/2 +V1 O-_____+ LM1 Vo +V2 0 + Ri R4 : . . for R= Ag (MAR depends on this resistor ratio match) Vo =( 14 BA) (ve-v1) As shown: V, =2 (V2- V1) 188-17.EPS USING SYMMETRICAL AMPLIFIERS TO REDUCE INPUT CURRENT (general concept) Us va r 158-18.EPS 10/12LM158,A - LM258,A - LM358,A - LM2904 TYPICAL APPLICATIONS (single supply voltage) Vcc = +5Vpc (continued) HIGH INPUT Z ADJUSTABLE-GAIN DC INSTRUMENTATION AMPLIFIER 100 ksz _}___ if A1= RS and R3- R4 = R6 RA? ~ AZ Ra 2R1 1/2 100 k32 100 ka vo-( + a) (v2-1) As shown : Vo = 101 (V2 - V1 158-19.EPS LOW DRIFT PEAK DETECTOR le oq3r 4V10 _ Zz ;: Input current lip compensation Sy 158-20.EPS 1412 i SGS-THOMSON VE imicRoELECrEOMeS 405pS Ee LM156,A - LM258,A - LM358,A - LM2904 TYPICAL APPLICATIONS (single supply voltage) Voc = +5Vpc (continued) ACTIVE BAND-PASS FILTER Rt 100k @ Re 100k Mo tte 7 10M 2 jd Ahir] F8 R3 470k 2 100k 2 4, OV, 12 R7 158 100k 2 f= 1kHz . . Vee Q=50 o A, = 100 (40dB) Ps ; Our <= S 158-21.EPS 1212 = s65-mhc IL $681 LECTROMICS