TS912 RAIL TO RAIL CMOS DUAL OPERATIONAL AMPLIFIER 8 V CC

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RAIL TO RAIL CMOS DUAL OPERATIONAL AMPLIFIER RAIL TO RAIL INPUT AND OUTPUT OLT- AGE RANGES SINGLE (OR DUAL) SUPPLY OPERATION FROM.7 TO 16 EXTREMELY LOW INPUT BIAS CURRENT : 1pA typ LOW INPUT OFFSET OLTAGE : m max. SPECIFIED FOR 6Ω AND Ω LOADS LOW SUPPLY CURRENT : µa/ampli ( = ) LATCH-UP IMMUNITY ESD TOLERANCE : K SPICE MACROMODEL INCLUDED IN THIS- SPECIFICATION DESCRIPTION The is a RAIL TO RAIL CMOS dual operational amplifier designed to operate with a single or dual supply voltage. The input voltage range icm includes the two supply rails + and -. At, the output reaches : - +m + -m with R L = kω - +m + -m with This product offers a broad supply voltage operating range from.7 to 16 and a supply current of only µa/amp @ =. Source and sink output current capability is typically ma at =, fixed by an internal limitation circuit. ORDER CODE N DIP8 (Plastic Package) D SO8 (Plastic Micropackage) PIN CONNECTIONS (top view) Output 1 Inverting Input 1 Non-inverting Input 1 1 8 + 4 - + - + 7 6 5 Output Inverting Input Non-inverting Input Package Part Number Temperature Range N D I/AI/BI -, +15 C N=Dual in Line Package (DIP) D=Small Outline Package (SO) - also available in Tape & Reel (DT) June 1/1

SCHEMATIC DIAGRAM (1/ ) Non-inverting Input Inverting Input Interna l ref Output ABSOLUTE MAXIMUM RATINGS Symbol Parameter alue Unit Supply voltage 1) 18 id Differential Input oltage ) ±18 i Input oltage ) -. to 18 I in Current on Inputs ± ma I o Current on Outputs ± ma T Operating Free Air Temperature Range oper I/AI/BI - to + 15 C T stg Storate Temperature -65 to +1 C 1. All voltages values, except differential voltage are with respect to network ground terminal.. Differential voltagesare non-inverting input terminal with respect to the inverting input terminal.. The magnitude of input and output voltages must never exceed + +.. OPERATING CONDITIONS Symbol Parameter alue Unit Supply voltage.7 to 16 icm Common Mode Input oltage Range - -. to + +. /1

ELECTRICAL CHARACTERISTICS + =, cc - =, R L,C L connected to /,T amb =5 C (unless otherwise specified) Symbol Parameter Min. Typ. Max. Unit io Input Offset oltage ( ic = o = / ) A B A B io Input Offset oltage Drift 5 µ/ C I io Input Offset Current 1) 5 1 7 1 I Input Bias Current 1) 1 1 ib I Supply Current (per amplifier, A CL = 1, no load) CMR Common Mode Rejection Ratio ic = to, o = 1.5 7 db SR Supply oltage Rejection Ratio ( + =.7 to., o = / ) 8 db m pa pa µa A vd Large Signal oltage Gain (R L = kω, o = 1. to 1.8) /m OH High Level Output oltage ( id = 1) R L = kω R L = kω R L = Ω.95.9..96.6 R L = kω.8.1 OL Low Level Output oltage ( id = -1) R L = kω R L = kω R L = Ω 9 7 m R L = kω 6 I o Output Short Circuit Current ( id = ±1) Source ( o = - ) Sink ( o = + ) GBP Gain Bandwith Product (A CL =, R L = kω, C L = pf, f = khz).8 MHz SR + Slew Rate (A CL =1,R L = kω, C L = pf, i = 1. to 1.7).4 /µs SR - Slew Rate (A CL =1,R L = kω, C L = pf, i = 1. to 1.7). /µs φm Phase Margin Degrees en Equivalent Input Noise oltage (R s = Ω, f = 1kHz) n/ Hz 1. Maximum values including unavoidable inaccuracies of the industrial test ma /1

ELECTRICAL CHARACTERISTICS + = 5, cc - =, R L,C L connected to /,T amb =5 C (unless otherwise specified) Symbol Parameter Min. Typ. Max. Unit io Input Offset oltage ( ic = o = / ) A B A B io Input Offset oltage Drift 5 µ/ C I io Input Offset Current 1) 5 1 7 1 I Input Bias Current 1) 1 1 ib I Supply Current (per amplifier, A CL = 1, no load) 4 CMR Common Mode Rejection Ratio ic = 1.5 to.5, o =.5 6 85 db SR Supply oltage Rejection Ratio ( + = to 5, o = / ) 55 8 db m pa pa µa A vd Large Signal oltage Gain (R L = kω, o = 1.5 to.5) 7 /m OH High Level Output oltage ( id = 1) R L = kω R L = kω R L = Ω 4.95 4.9 4.5 4.95 4.55.7 R L = kω 4.8 4.1 OL Low Level Output oltage ( id = -1) R L = kω R L = kω R L = Ω 1 m R L = kω 1 7 I o Output Short Circuit Current ( id = ±1) Source ( o = - ) Sink ( o = + ) GBP Gain Bandwith Product (A CL =, R L = kω, C L = pf, f = khz) 1 MHz SR + Slew Rate (A CL =1,R L = kω, C L = pf, i = 1 to 4).8 SR - Slew Rate (A CL =1,R L = kω, C L = pf, i = 1 to 4).6 /µs en Equivalent Input Noise oltage (R s = Ω, f = 1kHz) n/ Hz O1 / O Channel Separation (f = 1kHz) db φm Phase Margin Degrees 1. Maximum values including unavoidable inaccuracies of the industrial test 45 45 65 65 ma 4/1

ELECTRICAL CHARACTERISTICS + =, cc - =, R L,C L connected to /,T amb =5 C (unless otherwise specified) Symbol Parameter Min. Typ. Max. Unit io Input Offset oltage ( ic = o = / ) A B A B io Input Offset oltage Drift 5 µ/ C I io Input Offset Current 1) 5 1 7 1 I Input Bias Current 1) 1 1 ib I CMR Supply Current (per amplifier, A CL = 1, no load) 6 7 Common Mode Rejection Ratio ic = to 7, o =5 ic = to, o =5 SR Supply oltage Rejection Ratio ( + = 5 to, o = / ) 6 9 db Large Signal oltage Gain (R A L = kω, o =.5 to 7.5) 15 vd /m OH High Level Output oltage ( id = 1) R L = kω R L = kω R L = Ω 6 9.95 9.85 9 9 75 9.95 9.5 7.8 m pa pa µa db R L = kω 9.8 8.8 OL Low Level Output oltage ( id = -1) R L = kω R L = kω R L = Ω 6 1 8 m R L = kω 1 9 I o Output Short Circuit Current ( id = ±1) Source ( o = - ) Sink ( o = + ) GBP Gain Bandwith Product (A CL =, R L = kω, C L = pf, f = khz) 1.4 MHz SR + Slew Rate (A CL =1,R L = kω, C L = pf, i =.5 to 7.5) 1. /µs SR - Slew Rate (A CL =1,R L = kω, C L = pf, i =.5 to 7.5).8 φm Phase Margin Degrees en Equivalent Input Noise oltage (R s = Ω, f = 1kHz) n/ Hz THD Total Harmonic Distortion (A CL =1,R L = kω, C L = pf, o = 4.75 to 5.5, f = 1kHz).4 % C in Input Capacitance 1.5 pf 1. Maximum values including unavoidable inaccuracies of the industrial test 45 65 75 ma 5/1

TYPICAL CHARACTERISTICS Figure 1 : Supply Current (each amplifier) vs Supply oltage Figure : Input Bias Current vs Temperature SUPPLY CURRENT, I ( µ A) 6 T amb = 5 C A CL = 1 = / O 4 8 1 16 S UPPLYOLTAGE, () INPUT BIAS CURRENT, I (pa) ib = i = 5 No loa d 1 5 75 15 TEMPERATURE, T amb ( C) Figure a : High Level Output oltage vs High Level Output Current Figure b : High Level Output oltage vs High Level Output Current OUTPUT OLTAGE, OH () 5 4 1 T amb =5 C id = m = +5 = + OUTPUT OLTAGE, OH () 16 1 8 4 T amb id = 5 C = m = +16 = + -7-56 -4-8 -14-7 -56-4 -8-14 OUTPUT CURRENT, I OH (ma) OUTPUT CURRENT, I OH (ma) Figure 4a : Low Level Output oltage vs Low Level Output Current Figure 4b : Low Level Output oltage vs Low Level Output Current OUTPUT OLTAGE, OL () 5 4 1 T amb id = 5 C = -m = + = +5 OUTPUT OLTAGE, OL () 8 6 4 T amb id = 5 C = -m = 16 = 14 8 4 56 7 14 8 4 56 7 OUTPUT CURRENT, I OL (ma) OUTP UT CURRENT, I OL (ma) 6/1

Figure 5a : Gain and Phase vs Frequency Figure 5b : Gain and Phase vs Frequency GAIN (db) - PHASE T amb = 5 C = R L = k Ω C L = pf A CL = GAIN Gain Bandwidth P roduc t 4 5 6 FREQUENCY, f (Hz) Phase Margin 7 45 9 15 18 PHASE (Degrees) GAIN (db) - PHASE T amb = 5 C = C L = pf A CL = GAIN Gain Ba ndwidth Product 4 5 6 FREQUENCY, f (Hz) Phase Margin 7 45 9 15 18 PHASE (Degrees) Figure 6a : Gain Bandwidth Product vs Supply oltage Figure 6b : Gain Bandwidth Product vs Supply oltage GAIN BANDW. PROD., GBP (khz) 18 T amb = 5 C R L = kω 1 C L = pf 6 4 8 1 16 GAIN BANDW. PROD., GBP (khz) 18 T amb = 5 C 1 C L= pf 6 4 8 1 16 SUPPLY OLTAGE, () SUPP LY OLTAGE, () Figure 7a : Phase Margin vs Supply oltage Figure 7b : Phase Margin vs Supply oltage PHASE MARGIN, m (Degrees) φ 6 T amb = 5 C R L = kω C L= pf 4 8 1 16 SUPPLY OLTAGE, () PHASE MARGIN, φ m (Degrees) 6 T amb = 5 C C L = pf 4 8 1 16 S UPPLY OLTAGE, () 7/1

Figure 8 : Input oltage Noise vs Frequency EQUIALENT INPUT OLTAGE NOISE (n/hz) 1 = T amb =5 C R S =Ω FREQUENCY (Hz) 8/1

MACROMODEL Applies to : ( = ) ** Standard Linear Ics Macromodels, 199. ** CONNECTIONS : * 1 INERTING INPUT * NON-INERTING INPUT * OUTPUT * 4 POSITIE POWER SUPPLY * 5 NEGATIE POWER SUPPLY.SUBCKT _ 1 4 5 (analog) **********************************************************.MODEL MDTH D IS=1E-8 KF=6.56444E-14 CJO=F * INPUT STAGE CIP 5 1.E-1 CIN 1 5 1.E-1 EIP 5 5 1 EIN 16 5 1 5 1 RIP 11 6.E+ RIN 15 16 6.E+ RIS 11 15 1.715E+1 DIP 11 1 MDTH E-1 DIN 15 14 MDTH E-1 OFP 1 1 DC.E+ OFN 1 14 DC IPOL 1 5 4.E-5 CPS 11 15.1586E-8 DINN 17 1 MDTH E-1 IN 17 5.e+ DINR 15 18 MDTH E-1 IP 4 18.E+ FCP 4 5 OFP 5.E+ FCN 5 4 OFN 5.E+ * AMPLIFYING STAGE FIP 5 19 OFP.7E+ FIN 5 19 OFN.7E+ RG1 19 5 1.91685E+5 RG 19 4 1.91685E+5 19 9.E-8 HZTP 9 OFP 1.E+ HZTN 5 OFN 1.E+ DOPM 19 MDTH E-1 DONM 1 19 MDTH E-1 HOPM 8 OUT 8 IPM 8 4 1 HONM 1 7 OUT 8 INM 5 7 1 EOUT 6 19 5 1 OUT 5 ROUT 6 75 COUT 5 1.E-1 DOP 19 68 MDTH E-1 OP 4 5 1.74 HSCP 68 5 SCP1.8E8 DON 69 19 MDTH E-1 ON 4 5 1.74197 HSCN 4 69 SCN1.8E+8 SCTHP 6 61.875 ** SCTHP = le seuil au dessus de vio * ** c.a.d 75U-U dus a l offset DSCP1 61 6 MDTH E-1 SCP166 ISCP 64 1.E-8 DSCP 64 MDTH E-1 DSCN 74 MDTH E-1 ISCN 74 1.E-8 SCN1 7 74 DSCN1 71 7 MDTH E-1 SCTHN 71 7 -.55 ** SCTHN = le seuil au dessous de vio * ** c.a.d -75U-U dus a l offset ESCP 6 1 ESCN 7 1 -.ENDS ELECTRICAL CHARACTERISTICS + =, - =, R L,C L connected to /,T amb =5 C (unless otherwise specified) Symbol Conditions alue Unit io m A vd R L = kω /m I No load, per operator µa icm -. to. OH R L = kω.96 OL R L = kω m I sink O = ma I source O = ma GBP R L = kω, C L = pf.8 MHz SR R L = kω, C L = pf. /µs 9/1

MACROMODEL Applies to : ( = 5) ** Standard Linear Ics Macromodels, 199. ** CONNECTIONS : * 1 INERTING INPUT * NON-INERTING INPUT * OUTPUT * 4 POSITIE POWER SUPPLY * 5 NEGATIE POWER SUPPLY * 6 STANDBY.SUBCKT _5 1 4 5 (analog) **********************************************************.MODEL MDTH D IS=1E-8 KF=6.56444E-14 CJO=F * INPUT STAGE CIP 5 1.E-1 CIN 1 5 1.E-1 EIP 5 5 1 EIN 16 5 1 5 1 RIP 11 6.E+ RIN 15 16 6.E+ RIS 11 15 7.9E+ DIP 11 1 MDTH E-1 DIN 15 14 MDTH E-1 OFP 1 1 DC.E+ OFN 1 14 DC IPOL 1 5 4.E-5 CPS 11 15.49897E-8 DINN 17 1 MDTH E-1 IN 17 5.e+ DINR 15 18 MDTH E-1 IP 4 18.E+ FCP 4 5 OFP 5.7E+ FCN 5 4 OFN 5.7E+ ISTB 5 4 N * AMPLIFYING STAGE FIP 5 19 OFP 4.E+ FIN 5 19 OFN 4.E+ RG1 19 5 4.94961E+5 RG 19 4 4.94961E+5 19 9.E-8 HZTP 9 OFP 1.8E+ HZTN 5 OFN 1.8E+ DOPM 19 MDTH E-1 DONM 1 19 MDTH E-1 HOPM 8 OUT 8 IPM 8 4 HONM 1 7 OUT 8 INM 5 7 EOUT 6 19 5 1 OUT 5 ROUT 6 8 COUT 5 1.E-1 DOP 19 68 MDTH E-1 OP 4 5 1.74 HSCP 68 5 SCP1.8E+8 DON 69 19 MDTH E-1 ON 4 5 1.74197 HSCN 4 69 SCN1.8E+8 SCTHP 6 61.875 ** SCTHP = le seuil au dessus de vio * ** c.a.d 75U-U dus a l offset DSCP1 61 6 MDTH E-1 SCP166 ISCP 64 1.E-8 DSCP 64 MDTH E-1 DSCN 74 MDTH E-1 ISCN 74 1.E-8 SCN1 7 74 DSCN1 71 7 MDTH E-1 SCTHN 71 7 -.55 ** SCTHN = le seuil au dessous de vio * ** c.a.d -75U-U dus a l offset ESCP 6 1 ESCN 7 1 -.ENDS ELECTRICAL CHARACTERISTICS + = 5, - =, RL, CL connected to /, Tamb = 5 C (unless otherwise specified) Symbol Conditions alue Unit io m A vd R L = kω /m I No load, per operator µa icm -. to 5. OH R L = kω 4.95 OL R L = kω m I sink O =5 65 ma I source O = 65 ma GBP R L = kω, C L = pf 1 MHz SR R L = kω, C L = pf.8 /µs /1

PACKAGE MECHANICAL DATA 8 PINS - PLASTIC DIP Millimeters Inches Dim. Min. Typ. Max. Min. Typ. Max. A..11 a1.51. B 1.15 1.65.45.65 b.56.55.14. b1.4.4.8.1 D.9. E 7.95 9.75.1.84 e.54. e 7.6. e4 7.6. F 6.6 6 i 5.8. L.18.81.15.1 Z 1.5.6 11/1

PACKAGE MECHANICAL DATA 8 PINS - PLASTIC MICROPACKAGE (SO) Millimeters Inches Dim. Min. Typ. Max. Min. Typ. Max. A 1.75.69 a1.1.5.4. a 1.65.65 a.65.85.6. b.5.48.14.19 b1.19.5.7. C.5.5.. c1 45 (typ.) D 4.8 5..189.197 E 5.8 6..8.44 e 1.7. e.81.1 F.8 4..1.157 L.4 1.7.16. M.6.4 S 8 (max.) Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infring ement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics. The ST logo is a registered trademark of STMicroelectronics 1/1 STMicroelectronics - Printed in Italy - All Rights Reserved STMicroelectronics GROUP OF COMPANIES Australia - Brazil - China - Finland - France - Germany - Hong Kong - India - Italy - Japan - Malaysia - Malta - Morocco Singapore - Spain - Sweden - Switzerland - United Kingdom http://www. st.com

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