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general description the max4460/max4461/max4462 are instrumentationamplifiers with precision specifications, low-power con- sumption, and excellent gain-bandwidth product. p roprietary design techniques allow ground-sensing capability combined with ultra-low input current andincreased common-mode rejection performance. these rail-to-rail output instrumentation amplifiers are offered in fixed or adjustable gains and the option for either a shut- down mode or a pin to set the output voltage relative to an external reference (see the ordering information and selector guide ). the max4460 has an adjustable gain and uses groundas its reference voltage. the max4461 is offered in fixed gains of 1, 10, and 100, uses ground as its reference volt- age, and has a logic-controlled shutdown input. the max4462 is offered in fixed gains of 1, 10, and 100 and has a reference input pin (ref). ref sets the output volt- age for zero differential input to allow bipolar signals in single-supply applications. the max4460/max4461/max4462 have high-impedance inputs optimized for small-signal differential voltages. the max4461/max4462 are factory trimmed to gains of 1, 10, or 100 (suffixed u, t, and h) with ?.1% accuracy. the typical offset of the max4460/max4461/max4462 is 100?. all devices have a gain-bandwidth product of 2.5mhz. these amplifiers operate with a single-supply voltage from 2.85v to 5.25v and with a quiescent current of only 700? (less than 1? in shutdown for the max4461). the max4462 can also be operated with dual supplies. smaller than most competitors, the max4460/ max4461/max4462 are available in space-saving 6-pin sot23 and tdfn packages. ________________________applications industrial process controlstrain-gauge amplifiers transducer interface precision low-side current sense low-noise microphone preamplifier differential voltage amplification battery-powered medical equipment features ? tiny 6-pin sot23 and tdfn packages ? input negative rail sensing ? 1pa (typ) input bias current ? 100? input offset voltage ? rail-to-rail output ? 2.85v to 5.25v single supply ? 700? supply current ? ?.1% gain error ? 2.5mhz gain-bandwidth product ? 18nv/ hz input-referred noise max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers ________________________________________________________________ maxim integrated products 1 19-2279; rev 4; 3/06 for pricing, delivery, and ordering information, please contact maxim/dallas direct! at 1-888-629-4642, or visit maxim? website at www.maxim-ic.com. ordering information part temp range pin- package top mark max4460 ett+t -40? to +85? 6 tdfn-ep* +ani max4460eut-t -40? to +85? 6 sot23-6 aass max4460esa -40? to +85? 8 so max4461 uett+t -40? to +85? 6 tdfn-ep* +anj max4461ueut-t -40? to +85? 6 sot23-6 aast max4461uesa -40? to +85? 8 so max4461tett+t -40? to +85? 6 tdfn-ep* +ank max4461teut-t -40? to +85? 6 sot23-6 aasu max4461tesa -40? to +85? 8 so max4461hett+t -40? to +85? 6 tdfn-ep* +anl max4461heut-t -40? to +85? 6 sot23-6 aasv max4461hesa -40? to +85? 8 so pin configurations appear at end of data sheet. v cm + ? v v cm - ? v 6 1 5 v cc 2 max4462 3 4 out ref t ypical application circuits selector guide appears at end of data sheet. typical application circuits continued at end of data sheet. + denotes lead-free package. * ep = exposed paddle. ordering information continued at end of data sheet. downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 2 _______________________________________________________________________________________ absolute maximum ratings stresses beyond those listed under ?bsolute maximum ratings?may cause permanent damage to the device. these are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. exposure to absolute maximum rating conditions for extended periods may affect device reliability. supply voltage (v dd to v ss ) ...................................-0.3v to +6v all other pins ...................................(v ss - 0.3v) to (v dd + 0.3v) output short-circuit duration to either supply.........................1s continuous power dissipation (t a = +70?) 6-pin sot23 (derate 8.7mw/? above +70?)............695mw 6-pin tdfn-ep (derate 18.2mw/? above +70?) ....1454mw 8-pin so (derate 5.9mw/? above +70?)..................470mw operating temperature range ...........................-40? to +85? junction temperature ......................................................+150? storage temperature range .............................-65? to +150? lead temperature (soldering, 10s)....................................300? electrical characteristics?ax4460/max4461(v dd = 5v, v cm = 0v, v diff = v in+ - v in- = 50mv to 100mv for g = 1, 20mv to 100mv for g = 10, 2mv to 48mv for g =100, max4460 is configured for g = 10, r l = 200k ? to gnd, t a = +25? , unless otherwise noted.) parameter symbol conditions min typ max units supply voltage v dd guaranteed by psrr test 2.85 5.25 v v dd = 5v, v diff = 0v 0.80 1.1 supply current v dd = 3v, v diff = 0v 0.68 0.9 ma shutdown supply current max4461, shdn = gnd v dd = 5v 0.1 1 a max4460esa 50 425 max4461esa 50 300 input offset voltage (note 1) v os max446_eut/max446_ett 100 600 ? differential mode 2 input resistance r in v cm = v dd /2 common mode 2 g ? input common-mode range v cm guaranteed by cmrr test -0.1 v dd - 1.7 v input common-moderejection ratio cmrr v cm = -0.1v to (v dd - 1.7v) 90 120 db power-supply rejection ratio psrr v dd = 2.85v to 5.25v 80 100 db input bias current i b (note 2) 1 100 pa fb input current max4460 (note 2) 1 100 pa v ih max4461 0.7 x v dd shdn logic levels v il max4461 0.3 x v dd v shdn input current max4461, v shdn = 0v or v dd (note 2) 1 100 pa f = 10khz 18 input voltage noise e n f = 1khz 38 nv/ hz r l = 200k ? 1 2.5 v oh v dd - v oh (note 3) r l = 20k ? 35 r l = 200k ? 0 0.2 output voltage swing v ol r l = 20k ? 0 0.2 mv short-circuit current i sc (note 4) 150 ma downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers _______________________________________________________________________________________ 3 electrical characteristics?ax4460/max4461 (continued)(v dd = 5v, v cm = 0v, v diff = v in+ - v in- = 50mv to 100mv for g = 1, 20mv to 100mv for g = 10, 2mv to 48mv for g =100, max4460 is configured for g = 10, r l = 200k ? to gnd, t a = +25? , unless otherwise noted.) parameter symbol conditions min typ max units g = 1v/v, max4461uesa 0.1 0.3 g = 10v/v, max4461tesa 0.12 0.35 g = 100v/v, max4461hesa 0.15 0.6 g = 10v/v, max4460esa 0.15 0.35 gain error r l = 20k ? max446_eut/max446_ett 0.15 0.6 % nonlinearity (note 1) r l = 20k ? 0.05 0.15 % maximum capacitive load c l no sustained oscillations 100 pf g = 1v/v, max4461u 2500 g = 10v/v, max4461t 250 -3db bandwidth bw -3db c l = 100pf g = 100v/v, max4461h 25 khz gain-bandwidth product gbwp c l = 100pf 2.5 mhz g = 1v/v 0.5 g = 10v/v 0.5 slew rate sr c l = 100pf g = 100v/v 0.25 v/? g = 1v/v 15 g = 10v/v 75 settling time t s c l = 100pf, within 0.1% of final value g = 100v/v 250 ? electrical characteristics?ax4460/max4461(v dd = 5v, v cm = 0v, v diff = v in+ - v in- = 50mv to 100mv for g = 1, 20mv to 100mv for g = 10, 2mv to 48mv for g = 100, max4460 is configured for g = 10, r l = 200k ? to gnd, t a = t min to t max , unless otherwise noted.) parameter symbol conditions min typ max units supply voltage v dd guaranteed by psrr test 2.85 5.25 v v dd = 5v, v diff = 0v 1.4 supply current v dd = 3v, v diff = 0v 1.15 ma shutdown supply current max4461, shdn = gnd v dd = 5v 1 a t a = 0 c to +85 c 750 max4460esa t a = -40 c to +85 c 950 g = 1 750 g = 10 500 t a = 0 c to +85 c g = 100 500 g = 1 950 g = 10 750 max4461esa t a = -40 c to +85 c g = 100 750 t a = 0 c to +85 c 1400 input offset voltage (note 1) v os max446_eut/max446_ett t a = -40 c to +85 c 1900 ? input offset-voltage drift tc vos (note 1) 1.5 ?/? downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 4 _______________________________________________________________________________________ electrical characteristics?ax4460/max4461 (continued)(v dd = 5v, v cm = 0v, v diff = v in+ - v in- = 50mv to 100mv for g = 1, 20mv to 100mv for g = 10, 2mv to 48mv for g = 100, max4460 is configured for g = 10, r l = 200k ? to gnd, t a = t min to t max , unless otherwise noted.) parameter symbol conditions min typ max units input common-mode range v cm guaranteed by cmrr test -0.1 v dd - 1.85 v input common-mode rejectionratio cmrr v cm = -0.1v to (v dd - 1.85v) 80 db power-supply rejection ratio psrr v dd = 2.85v to 5.25v 75 db input bias current i b (note 2) 100 pa fb input current max4460 (note 2) 100 pa v ih max4461 0.7 x v dd shdn logic levels v il max4461 0.3 x v dd v shdn input current max4461, v shdn = 0v or v dd (note 2) 100 pa r l = 200k ? 4 v oh v dd - v oh (note 3) r l = 20k ? 8 r l = 200k ? 0.25 output voltage swing v ol r l = 20k ? 0.25 mv t a = 0 c to +85 c 0.8 max4461uesa,r l = 20k ? t a = -40 c to +85 c 1.6 t a = 0 c to +85 c 0.8 max4461tesa,r l = 20k ? t a = -40 c to +85 c 1.7 t a = 0 c to +85 c 1.0 max4461hesa,r l = 20k ? t a = -40 c to +85 c 2.0 t a = 0 c to +85 c 0.8 max4460esa,r l = 20k ? t a = -40 c to +85 c 2.0 t a = 0 c to +85 c 1.8 gain error max446_eut/max446_ett, r l = 20k ? t a = -40 c to +85 c 3.0 % t a = 0 c to +85 c 0.20 nonlinearity r l = 20k ? (note 1) t a = -40 c to +85 c 0.25 % downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers _______________________________________________________________________________________ 5 electrical characteristics?ax4462(v dd = 5v, v ss = 0v, v cm = v ref = v dd /2, r l = 100k ? to v dd /2, t a = +25? , unless otherwise noted. v diff = v in+ - v in- = -100mv to +100mv for g = 1 and g = 10, -20mv to +20mv for g = 100.) parameter symbol conditions min typ max units supply voltage v dd guaranteed by psrr test 2.85 5.25 v v dd = 5v, v diff = 0v 0.8 1.1 supply current v dd = 3v, v diff = 0v 0.68 0.9 ma max4462_esa 50 250 input offset voltage (note 1) v os max4462_eut/max4462_ett 100 500 ? differential mode 2 input resistance r in v cm = v dd /2 common mode 2 g ? input common-mode range v cm guaranteed by input cmrr test v ss - 0.1 v dd - 1.7 v ref input range guaranteed by ref rejection test v ss + 0.1 v dd - 1.7 v input common-moderejection ratio cmrr v cm = (v ss - 0.1v) to (v dd - 1.7v) 90 120 db ref input rejection ratio v cm = (v ss + 0.1v) to (v dd - 1.7v) 85 100 db power-supply rejection ratio psrr v dd = 2.85v to 5.25v 80 100 db input bias current i b (note 2) 1 100 pa f = 10khz 18 input voltage noise e n f = 1khz 38 nv/ hz r l = 100k ? 1 2.5 v oh v dd - v oh (note 3) r l = 10k ? 35 r l = 100k ? 24 output voltage swing v ol v ol - v ss (note 3) r l = 10k ? 61 2 mv short-circuit current i sc (note 4) 150 ma g = 1v/v, max4462uesa 0.1 0.30 g = 10v/v, max4462tesa 0.12 0.35 g = 100v/v, max4462hesa 0.15 0.5 gain error r l = 10k ? max4462_eut/max4462_ett 0.15 0.5 % nonlinearity r l = 10k ? 0.05 0.15 % downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 6 _______________________________________________________________________________________ electrical characteristics?ax4462 (continued)(v dd = 5v, v ss = 0v, v cm = v ref = v dd /2, r l = 100k ? to v dd /2, t a = +25? , unless otherwise noted. v diff = v in+ - v in- = -100mv to +100mv for g = 1 and g = 10, -20mv to +20mv for g = 100.) parameter symbol conditions min typ max units maximum capacitive load c l no sustained oscillations 100 pf g = 1v/v, max4462u 2500 g = 10v/v, max4462t 250 -3db bandwidth bw -3db c l = 100pf g = 100v/v, max4462h 25 khz gain-bandwidth product gbwp c l = 100pf 2.5 mhz g = 1v/v, max4462u 0.5 g = 10v/v, max4462t 0.5 slew rate sr c l = 100pf g = 100v/v, max4462h 0.25 v/? g = 1v/v, max4462u 15 g = 10v/v, max4462t 75 settling time t s c l = 100pf, within 0.1% offinal value g = 100v/v, max4462h 250 ? parameter symbol conditions min typ max units supply voltage v dd guaranteed by psrr test 2.85 5.25 v v dd = 5v, v diff = 0v 1.4 supply current v dd = 3v, v diff = 0v 1.15 ma t a = 0? to +85? 500 max4462_esa t a = -40? to +85? 750 t a = 0? to +85? 1100 input offset voltage (note 1) v os max4462_eut/max4462_ett t a = -40? to +85? 1300 ? input offset voltage drift tcv os (note 1) 1.5 ?/? input common-mode range v cm guaranteed by input cmrr test v ss - 0.1 v dd - 1.85 v ref input range guaranteed by ref rejection test v ss + 0.1 v dd - 1.85 v input common-moderejection ratio cmrr v cm = (v ss ?0.1v) to (v dd - 1.85v) 80 db ref input rejection ratio v cm = (v ss + 0.1v) to (v dd - 1.85v) 75 db power-supply rejection ratio psrr v dd = 2.85v to 5.25v 75 db input bias current i b (note 2) 100 pa electrical characteristics?ax4462(v dd = 5v, v ss = 0v, v cm = v ref = v dd /2, r l = 100k ? to v dd /2, t a = t min to t max , unless otherwise noted. v diff = v in+ - v in- = -100mv to +100mv for g = 1 and g = 10, -20mv to +20mv for g = 100.) (note 5) downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers _______________________________________________________________________________________ 7 electrical characteristics?ax4462 (continued)(v dd = 5v, v ss = 0v, v cm = v ref = v dd /2, r l = 100k ? to v dd /2, t a = t min to t max , unless otherwise noted. v diff = v in+ - v in- = -100mv to +100mv for g = 1 and g = 10, -20mv to +20mv for g = 100.) (note 5) parameter symbol conditions min typ max units r l = 100k ? 4 v oh v dd - v oh (note 3) r l = 10k ? 8 r l = 100k ? 8 output voltage swing v ol v ol - v ss (note 3) r l = 10k ? 16 mv t a = 0? to +85? 0.8 r l = 10k ? , max4462uesa t a = -40? to +85? 1.6 t a = 0? to +85? 0.8 r l = 10k ? , max4462tesa t a = -40? to +85? 1.7 t a = 0? to +85? 0.8 r l = 10k ? , max4462hesa t a = -40? to +85? 1.7 t a = 0? to +85? 1.8 gain error ge r l = 10k ? , max4462_eut/max4462_ett t a = -40? to +85? 3.0 % t a = 0? to +85? 0.2 nonlinearity nl r l = 10k ? t a = -40? to +85? 0.25 % note 1: offset voltage is measured with a best straight-line (bsl) method (see a user guide to instrumentation amplifier accuracy specifications section). note 2: in+ and in- are gates to cmos transistors with typical input bias current of 1pa. cmos leakage is so small that it isimpractical to test and guarantee in production. limits shown are guaranteed by design. however, devices are functionally screened during production testing to eliminate defective units. note 3: output swing high is measured only on g = 100 devices. devices with g = 1 and g = 10 have output swing high limited bythe range of v ref , v cm , and v diff (see output swing section). note 4: short-circuit duration limited to 1s (see absolute maximum ratings) . note 5: sot23 and tdfn units are 100% production tested at +25?. limits over temperature are guaranteed by design. downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 8 _______________________________________________________________________________________ t ypical operating characteristics (v dd = 5v, v ss = 0v, v in + = v in- = v ref = v dd /2, r l = 100k ? to v dd /2, t a = +25?, unless otherwise noted. v diff = v in+ - v in - = -100mv to +100mv for g = 1 and g = 10, -20mv to +20mv for g = 100.) 10,000 1000 100 10 1 0.1 100 11 01 k 10k 100k input voltage noise vs. frequency max4460 toc07 frequency (hz) input voltage noise (nv/ hz) peak-to-peak noise (0.1hz to 10hz) max4460 toc08 1s/div 2 v/div input referredg = 1, 10, or 100 0 0.0100.005 0.015 0.020 0.025 0.030 0.035 0.040 0.045 10 100 1k 10k 100k total harmonic distortion plus noise vs. frequency max4460 toc09 frequency (hz) thd + n (%) v out = 100mv p-p g = 1r l = 100k ? 0 42 10 86 12 14 16 18 -300 -200 -150 -250 -100 -50 0 50 100 150 200 250 300 voltage offset histogram max4460 toc01 voltage offset ( v) percentage of units 0 42 6 12 1410 8 16 0 0.02 0.03 0.04 0.05 0.01 0.06 0.07 0.08 0.09 0.10 gain-linearity histogram max4460 toc04 linearity (%) percentage of units 0 42 6 12 1410 8 16 -5 -3 -2 -1 0 -4 1 2 3 4 5 voltage offset drift histogram max4460 toc02 voltage offset drift ( v/ c) percentage of units 0 42 86 10 12 -0.5 0 gain error histogram max4460 toc03 gain error (%) percentage of units -0.4 -0.2 -0.1 0.1 0.2 0.3 0.4 0.5 -0.3 a v = 100 -130 -120 -90 -100-110 -80 -70 -60 -50 -40 -30 -20 0.1 10 1 100 1k 10k common-mode rejection ratio vs. frequency max4460 toc05 frequency (hz) cmrr (db) a v = 1v/v power-supply rejection ratio vs. frequency frequency (hz) 0.01 10 100 1k 0.1 1 10k psrr (db) 0 -120 -100 -80 -60 -20-40 max4460 toc06 a v = 1v/v downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers _______________________________________________________________________________________ 9 300 650400 800750 700 900 950850 1000 2.75 3.50 3.75 3.00 3.25 4.00 4.25 4.50 4.75 5.00 supply current vs. supply voltage max4460 toc10 supply voltage (v) supply current ( a) 600550 500450 350 t a = +25 c t a = -40 c t a = +85 c 0 42 86 1210 14 shutdown current vs. supply voltage max4460 toc11 supply voltage (v) supply current (na) t a = +25 c t a = -40 c t a = +85 c 2.75 3.50 3.75 3.00 3.25 4.00 4.25 4.50 4.75 5.00 0 0.040.02 0.080.06 0.120.10 0.14 0.180.16 0.20 00 . 20 . 30.4 0.1 0.5 0.6 0.7 0.9 0.8 1.0 max4462h normalized output error vs. common-mode voltage max4460 toc12 v cm (v) normalized output error (%) v dd = +2.5v, v ee = -2.5v v diff = 20mv v out = 2v g = 100v/vv ref = 0v -0.30 -0.16-0.18 -0.20 -0.22 -0.24 -0.26 -0.28 -0.12-0.14 -0.08-0.10 -0.06 -0.02-0.04 0 -2.7 -2.1 -1.8 -2.4 -1.5 -1.2 -0.9 -0.6 0 -0.3 max4462h normalized output error vs. common-mode voltage max4460 toc13 v cm (v) normalized output error (%) v dd = +2.5v, v ee = -2.5v v diff = 20mv v out = 2v g = 100v/vv ref = 0v 0 4020 8060 120100 140 180160 200 0 234 15 6 7 9 81 0 output swing high vs. output current max4460 toc14 output current (ma) v dd - v out (mv) v dd = 3.3v v dd = 5.0v v dd = 2.85v 0 100 50 200150 300250 350 450400 500 0 234 1 567 9 81 0 output swing low vs. output current max4460 toc15 output current (ma) v out - v ss (mv) v dd = 2.85v v dd = 3.3v v dd = 5.0v t ypical operating characteristics (continued) (v dd = 5v, v ss = 0v, v in + = v in- = v ref = v dd /2, r l = 100k ? to v dd /2, t a = +25?, unless otherwise noted. v diff = v in+ - v in - = -100mv to +100mv for g = 1 and g = 10, -20mv to +20mv for g = 100.) -10 10 0 3020 40 50 gain vs. frequency max4460 toc16 frequency (hz) gain (db) 10 1k 10k 100 100k 1m 10m a v = 100v/v a v = 10v/v a v = 1v/v 22 23 2524 26 27 -40 10 -15 35 60 85 gain bandwidth vs. temperature max4460 toc17 temperature ( c) -3db bandwidth (khz) a v = 100v/v settling time (gain = 100) max4460 toc18 40 s/div input10mv/div output500mv/div output10mv/div downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 10 ______________________________________________________________________________________ t ypical operating characteristics (continued) (v dd = 5v, v ss = 0v, v in + = v in- = v ref = v dd /2, r l = 100k ? to v dd /2, t a = +25?, unless otherwise noted. v diff = v in+ - v in - = -100mv to +100mv for g = 1 and g = 10, -20mv to +20mv for g = 100.) large-signal pulse response (gain = 1v/v) max4460 toc19 input output 50mv/div 1 s/div large-signal pulse response (gain = 100v/v) max4460 toc20 input 10mv/div output 1v/div 20 s/div small-signal pulse response (gain = 1v/v) max4460 toc21 input output 10mv/div 1 s/div small-signal pulse response (gain = 1v/v) max4460 toc22 1 s/div input 10mv/div output c l = 100pf small-signal pulse response (gain = 100v/v) max4460 toc23 input 1mv/div output 100mv/div 20 s/div small-signal pulse response (gain = 100v/v) max4460 toc24 20 s/div input 1mv/div output 100mv/div gain = +100v/vc l = 100pf c l = 100pf downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers ______________________________________________________________________________________ 11 pin descriptions pin max4460 sot23/tdfn so name function 11 out output 22 gnd negative supply voltage 33 in+ positive differential input 4, 5 n.c. no connection. not internally connected. 46 in- negative differential input 57v dd positive supply voltage 68f b feedback input. connect fb to the center tap of a resistive divider fromout to gnd to set the gain. ep ep exposed pad. tdfn only. connect to gnd. pin max4461 sot23/tdfn so name function 11 out output 22 gnd negative supply voltage 33 in+ positive differential input 4, 5 n.c. no connection. not internally connected. 46 in- negative differential input 57v dd positive supply voltage 68 shdn shutdown control. drive shdn high for normal operation. ep ep exposed pad. tdfn only. connect to gnd. pin max4462 sot23/tdfn so name function 11 out output 22v ss negative supply voltage 33 in+ positive differential input 4, 5 n.c. no connection. not internally connected. 46 in- negative differential input 57v dd positive supply voltage 68 ref output reference level. connect ref to an external, low-impedance reference voltage. ref sets the out voltage for zero differential inputs. ep ep exposed pad. tdfn only. connect to v ss . downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 12 ______________________________________________________________________________________ detailed description the max4460/max4461/max4462 family of instrumen-tation amplifiers implements maxim? proprietary indi- rect current-feedback design to achieve a precision specification and excellent gain-bandwidth product. these new techniques allow ground-sensing capability combined with an ultra-low input current and an increased common-mode rejection. the differential input signal is converted to a current by an input transconductance stage. an output transcon- ductance stage converts a portion of the output voltage (equal to the output voltage divided by the gain) into another precision current. these two currents are sub- tracted and the result is fed to a loop amplifier with a class ab output stage with sufficient gain to minimize errors (figure 1). the max4461u/t/h and max4462u/t/h have factory- trimmed gains of 1, 10, and 100, respectively. the max4460 has an adjustable gain, set with an external pair of resistors between pins out, fb, and gnd (figure 2). the max4462u/t/h has a reference input (ref) which is connected to an external reference for bipolar opera- tion of the device. the range for v ref is 0.1v to (v dd - 1.7v). for full output-swing capability, optimal perfor- mance is usually obtained with v ref = v dd /2 . the max4460/max4461/max4462 operate with single-supply voltages of 2.85v to 5.25v. it is possible to use the max4462u/t/h in a dual-supply configuration with up to ?.6v at v dd and v ss , with ref connected to ground. the max4461u/t/h has a shutdown feature to reduce the supply current to less than 1a. the max4461u/ t/h output is internally referenced to ground, making the part suitable for unipolar operations. the max4460 has an fb pin that can be used to exter- nally set the gain through a pair of resistors (see setting the gain (max4460) section). the max4460 output is internally referenced to ground, making the part suitablefor unipolar operations. max4460 g m g m fb v dd max4461 g m g m v dd shdn max4462 g m g m v dd ref v ss out out out figure 1. functional diagrams max4460 g m g m fb v dd r1 r2 out figure 2. max4460 external resistor configuration functional diagrams downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers ______________________________________________________________________________________ 13 input common-mode and output reference ranges max4460/max4461/max4462 have an input common-mode range of 100mv below the negative supply to 1.7v below the positive supply. the output reference voltage of max4462u/t/h is set by ref and ranges from 100mv above the negative supply to 1.7v below the positive supply. for maximum voltage sw ing in a bipolar operation, connect ref to v dd /2 . the output voltages of the max4460 and max4461u/t/h are referenced to ground. unlike the traditional three-op-amp configuration of common instrumentation amplifiers, the max4460/max4461/max4462 have ground-sensing capability (or to v ss in dual-supply configuration) in addition to the extremely high inputimpedances of mos input differential pairs. input differential signal range the max4460/max4461/max4462 feature a proprietaryinput structure optimized for small differential signals. the unipolar output of the max4460/max4461 is nomi- nally zero-for-zero differential input. however, these devices are specified for inputs of 50mv to 100mv for the unity-gain devices, 20mv to 100mv for gain of 10 devices, and 2mv to 48mv for gain of 100 devices. the max4460/max4461 can be used with differential inputs approaching zero, albeit with reduced accuracy. the bipolar output of the max4462 allows bipolar input ranges. the output voltage is equal to the reference voltage for zero differential input. the max4462 is specified for inputs of ?00mv for the unity gain and gain of 10 devices, and ?0mv for gain of 100 devices. the gain of 100 devices (max4462h) can be operated beyond 20mv signal provided the reference is chosen for unsymmetrical swing. output swing the max4460/max4461/max4462 are designed tohave rail-to-rail output voltage swings. however, depending on the selected gain and supply voltage (and output reference level of the max4462), the rail-to- rail output swing is not required. for example, consider the max4461u, a unity-gain device with its ground pin as the output reference level. the input voltage range is 0 to 100mv (50mv minimum to meet accuracy specifications). because the device is unity gain and the output reference level is ground, the output only sees excursions from ground to 100mv. devices with higher gain and with bipolar output such as the max4462, can be configured to swing to higher levels. in these cases, as the output approaches eithersupply, accuracy may degrade, especially under heavy output loading. shutdown mode the max4461u/t/h features a low-power shutdownmode. when the shdn pin is pulled low, the internal transconductance and amplifier blocks are switched off and supply current drops to typically less than 0.1? (figure 1). in shutdown, the amplifier output is high impedance. the output transistors are turned off, but the feedback resistor network remains connected. if the external load is referenced to gnd, the output drops to approximate- ly gnd in shutdown. the output impedance in shut- down is typically greater than 100k ? . drive shdn high or connect to v cc for normal operation. a user guide to instrumentation amplifier accuracy specifications as with any other electronic component, a complete understanding of instrumentation amplifier specifica- tions is essential to successfully employ these devices in their application circuits. most of the specifications for these differential closed-loop gain blocks are similar to the well-known specifications of operational ampli- fiers. however, there are a few accuracy specifications that could be confusing to first-time users. therefore, some explanations and examples may be helpful. accuracy specifications are measurements of close- ness of an actual output response to its ideal expected value. there are three main specifications in this category: gain error gain nonlinearity error offset error in order to understand these terms, we must look at thetransfer function of an ideal instrumentation amplifier. as expected, this must be a straight line passing through origin with a slope equal to the ideal gain (figure 3). if the ideal gain is equal to 10 and the extreme applied input voltages are -100mv and +100mv, then the value of the output voltages are -1v and +1v, respectively. note that the line passes through the origin and therefore a zero input voltage gives a zero output response. the transfer function of a real instrumentation amplifier is quite different from the ideal line pictured in figure 3. rather, it is a curve such as the one indicated as the typical curve in figure 4, connecting end points a and b. downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 14 ______________________________________________________________________________________ looking at this curve, one can immediately identifythree types of errors. first, there is an obvious nonlinearity (curvature) when this transfer function is compared to a straight line. more deviation is measured as greater nonlinearity error. this is explained in more detail below. second, even if there was no nonlinearity error, i.e., the actual curve in figure 4 was a straight line connecting end points a and b, there exists an obvious slope devi- ation from that of an ideal gain slope (drawn as the ?deal?line in figure 4). this rotational error (delta slope) is a measure of how different the actual gain (g a ) is from the expected ideal gain (g i) and is called gain error (ge) (see the equation below).third, even if the actual curve between points a and b was a straight line (no nonlinearity error) and had the same slope as the ideal gain line (no gain error), there is still another error called the end-point offset error (oe on vertical axis), since the line is not passing through the origin. figure 5 is the same as figure 4, but the ideal line (cd) is shifted up to pass through point e (the y intercept of end-points line ab). this is done to better visualize the rotational error (ge), which is the difference between the slopes of end points line ab and the shifted ideal line cd. mathematically: ge (%) = 100 x (g a - g i ) / g i v out v out2 v out1 v in1 v in v in2 ideal transferfunction (line) 0 figure 3. transfer function of an ideal instrumentationamplifier (straight line passing through the origin) v out actual curve a e 0 b z end-point line ideal line v in figure 4. typical transfer function for a real instrumentationamplifier v out actual curve end-point line ideal line shift nl+ nl- c 0 e z b d a v in slope (cd) = ideal gain = g i slope (ab) = actual gain = g a gain error (%) = ge (%) = 100 x (g a - g i ) / g i offset (end point) = oe nl- = nl+ figure 5. typical transfer function for a real instrumentationamplifier (ideal line (cd) is shifted by the end-points offset (oe) to visualize gain error) downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers ______________________________________________________________________________________ 15 the rotational nature of gain error, and the fact that it ispivoted around point e in figure 5, shows that gain- error contribution to the total output voltage error is directly proportional to the input voltage. at zero input voltage, the error contribution of gain error is zero, i.e., the total deviation from the origin (the expected zero output value) is only due to end-points oe and nonlin- earity error at zero value of input (segment ez on the vertical axis). the nonlinearity is the maximum deviation from a straight line, and the end-point nonlinearity is the devia- tion from the end-point line. as shown in figure 5, it is likely that two nonlinearities are encountered, one posi- tive and the other a negative nonlinearity error, shown as nl+ and nl- in figure 5. generally, nl+ and nl- have different values and this remains the case if the device is calibrated (trimmed) for end-points errors (which means changing the gain of the instrumentation amplifier in such a way that the slope of line ab becomes equal to that of cd, and the offset becomes trimmed such that oe vanishes to zero). this is an undesirable situation when nonlinearity is of prime interest. the straight line shown in figure 6 is in parallel to end- points line ab and has a y intercept of os on the verti- cal axis. this line is a shifted end-points line such that the positive and negative nonlinearity errors with respect to this line are equal. for this reason, the line is called the best straight line (bsl). maxim internally trims the max4460/max4461/max4462 with respect to this line (changing the gain slope to be as close as possible to the slope of the ideal line and trimming the offset such that os gets as close to the origin as possi- ble) to minimize all the errors. the total accuracy error is still the summation of the gain error, nonlinearity, and offset errors. as an example, assume the following specification for an instrumentation amplifier: gain = 10ge = 0.15% offset (bsl) = 250? nl = 0.05% v dif (input) = -100mv to +100mv what is the maximum total error associated with thege, offset (bsl), and nl? with a differential input range of -0.1v to +0.1v and a gain of 10, the output voltage assumes a range of -1v to +1v, i.e., a total full-scale range of 2v. the individual errors are as follows: ge = (0.15%) (10) (100mv) = 1.5mvoffset (bsl) = (250?) (10) = 2.5mv nl = (0.05%) (2v) = 1mv maximum total error = 1.5mv + 2.5mv + 1mv = 5mv so, the absolute value of the output voltage, consider-ing the above errors, would be at worst case between 0.995v to 1.005v. note that other important parameters such as psrr, cmrr, and noise also contribute to the total error in instrumentation applications. they are not considered here. v in v out actual curve end-point line bsl line nl+ nl- 0 e z b s a nl+ = nl- = nlnl bsl (%) = (nl / full-scale output range) x 100 offset (bsl) = oslgain and offset will be factory-trimmed for best straight line figure 6. to minimize nonlinearity error, the max4460/max4461/max4462 are internally trimmed to adjust gain and offset for the best straight line so nl- = nl+ downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 16 ______________________________________________________________________________________ applications information setting the gain (max4460) the max4460 gain is set by connecting a resistive-divider from out to gnd, with the center tap connect- ed to fb (figure 2). the gain is calculated by: gain = 1 + r2 / r1 because fb has less than 100pa ib, high-valued resis-tors can be used without significantly affecting the gain accuracy. the sum of resistors (r1 + r2) near 100k ? is a good compromise. resistor accuracy directly affectsgain accuracy. resistor sum less than 20k ? should not be used because their loading can slightly affect outputaccuracy. capacitive-load stability the max4460/max4461/max4462 are capable of dri- ving capacitive loads up to 100pf. applications needing higher capacitive drive capability may use an isolation resistor between out and the load to reduce ringing on the output signal. however this reduces the gain accuracy due to the voltage drop across the isolation resistor. output loading for best performance, the output loading should be tothe potential seen at ref for the max4462 or to ground for the max4460/max4461. ref input (max4462) the ref input of the max4462 can be connected to anyvoltage from (v ss + 0.1v) to (v dd - 1.7v). a buffered voltage-divider with sink and source capability works well to center the output swing at v dd / 2. unbuffered resistive dividers should be avoided because the 100k ? (typ) input impedance of ref causes amplitude-depen- dent variations in the divider? output. bandgap references, either series or shunt, can be used to drive ref. this provides a voltage and temper- ature invariant reference. this same reference voltage can be used to bias bridge sensors to eliminate supply voltage ratiometricity. for proper operation, the refer- ence must be able to sink and source at least 25?. in many applications, the max4462 is connected to a codec or other device with a reference voltage out- put. in this case, the receiving device? reference out- put makes an ideal reference voltage. verify the reference output of the device is capable of driving the max4462? ref input. power-supply bypass and layout good layout technique optimizes performance bydecreasing the amount of stray capacitance at the instrumentation amplifier? gain-setting pins. excess capacitance produces peaking in the amplifier? fre- quency response. to decrease stray capacitance, min- imize trace lengths by placing external components as close to the instrumentation amplifier as possible. for best performance, bypass each power supply to ground with a separate 0.1? capacitor. microphone amplifier the max4462? bipolar output, along with its excellentcommon-mode rejection ratio, makes it suitable for pre- cision microphone amplifier applications. figure 7 illus- trates one such circuit. in this case, the electret microphone is resistively biased to the supply voltage through a 2.2k ? pullup resistor. the max4462 directly senses the output voltage at its noninverting input, andindirectly senses the microphone? ground through an ac-coupling capacitor. this technique provides excel- lent rejection of common-mode noise picked up by the microphone lead wires. furthermore, ground noise from distantly located microphones is reduced. the single-ended output of the max4462 is converted to differential through a single op amp, the max4335. the op amp forces the midpoint between out+ and out- to be equal to the reference voltage. the configuration does not change the max4662t? fixed gain of 10. downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers ______________________________________________________________________________________ 17 selector guide part gain ref shutdown max4460 adjustable gnd no max4461u 1 gnd yes max4461t 10 gnd yes max4461h 100 gnd yes max4462u 1 ext no max4462t 10 ext no max4462h 100 ext no max4462teut v dd mic v ref 1 5 out- out+ 34 4 3 1 2 2 6 6 3.3k ? 20k ? 100k ? 2.2k ? 20k ? 0.1 f 4.7 f max4335 figure 7. differential i/o microphone amplifier chip information transistor count: 421process: bicmos ? v > 0 v cm 6 1 5 v cc 2 max4461 3 4 out shdn ? v v cm + ? v t ypical application circuits (continued) ordering information (continued) part temp range pin- package top mark max4462 uett+t -40? to +85? 6 tdfn-ep* +anm max4462ueut-t -40? to +85? 6 sot23-6 aasw max4462uesa -40? to +85? 8 so max4462tett+t -40? to +85? 6 tdfn-ep* +ann max4462teut-t -40? to +85? 6 sot23-6 aasx max4462tesa -40? to +85? 8 so max4462hett+t -40? to +85? 6 tdfn-ep* +ano max4462heut-t -40? to +85? 6 sot23-6 aasy max4462hesa -40? to +85? 8 so + denotes lead-free package. * ep = exposed paddle. downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers 18 ______________________________________________________________________________________ pin configurations in- n.c. n.c. 12 8 7 fb v dd gnd in+ out so 3 4 6 5 max4460 in- n.c. n.c. 12 8 7 v dd gnd in+ out so 3 4 6 5 max4461 in- n.c. n.c. 12 8 7 ref v dd v ss in+ out so 3 4 6 5 max4462 top view gnd in- in+ 16 shdn 5 v dd out max4461 sot23 234 v ss in- in+ 16 ref 5 v dd out max4462 sot23 234 shdn gnd in- in+ 16 fb 5 v dd out max4460 sot23 234 + denotes lead-free packaging max4460 fb v dd in- out gnd 1 2 3 6 5 4 tdfn + in+ *ep max4461 shdn v dd in- out gnd 1 2 3 6 5 4 tdfn + in+ *ep max4462 ref v dd in- out v ss 1 2 3 6 5 4 tdfn + in+ *ep downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers ______________________________________________________________________________________ 19 package information (the package drawing(s) in this data sheet may not reflect the most current specifications. for the latest package outline information, go to www.maxim-ic.com/packages .) 6, 8, &10l, dfn thin.eps l c l c pin 1 index area d e l e l a e e2 n g 1 2 21-0137 package outline, 6,8,10 & 14l,tdfn, exposed pad, 3x3x0.80 mm -drawing not to scale- k e [(n/2)-1] x e ref. pin 1 id 0.35x0.35 detail a b d2 a2 a1 common dimensions symbol min. max. a 0.70 0.80 d 2.90 3.10 e 2.90 3.10 a1 0.00 0.05 l 0.20 0.40 pkg. code n d2 e2 e jedec spec b [(n/2)-1] x e package variations 0.25 min. k a2 0.20 ref. 2.300.10 1.500.10 6 t633-1 0.95 bsc mo229 / weea 1.90 ref 0.400.05 1.95 ref 0.300.05 0.65 bsc 2.300.10 8 t833-1 2.00 ref 0.250.05 0.50 bsc 2.300.10 10 t1033-1 2.40 ref 0.200.05 - - - - 0.40 bsc 1.700.10 2.300.10 14 t1433-1 1.500.101.500.10 mo229 / weec mo229 / weed-3 0.40 bsc - - - - 0.200.05 2.40 ref t1433-2 14 2.300.10 1.700.10 t633-2 6 1.500.10 2.300.10 0.95 bsc mo229 / weea 0.400.05 1.90 ref t833-2 8 1.500.10 2.300.10 0.65 bsc mo229 / weec 0.300.05 1.95 ref t833-3 8 1.500.10 2.300.10 0.65 bsc mo229 / weec 0.300.05 1.95 ref -drawing not to scale- g 2 2 21-0137 package outline, 6,8,10 & 14l,tdfn, exposed pad, 3x3x0.80 mm downbonds allowed nono no no yes no yes no note: max446_ _ett+t uses tdfn package option t633-2. downloaded from: http:///
max4460/max4461/max4462 sot23, 3v/5v, single-supply, rail-to-rail instrumentation amplifiers maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a maxim product. no circuit patent licenses are implied. maxim reserves the right to change the circuitry and specifications without notice at any time. 20 ____________________maxim integrated products, 120 san gabriel drive, sunnyvale, ca 94086 408-737-7600 2006 maxim integrated products printed usa is a registered trademark of maxim integrated products, inc. soicn .eps package outline, .150" soic 1 1 21-0041 b rev. document control no. approval proprietary information title: top view front view max 0.010 0.069 0.019 0.157 0.010 inches 0.150 0.007 e c dim 0.014 0.004 b a1 min 0.053 a 0.19 3.80 4.00 0.25 millimeters 0.10 0.35 1.35 min 0.49 0.25 max 1.75 0.050 0.016 l 0.40 1.27 0.394 0.386 d d min dim d inches max 9.80 10.00 millimeters min max 16 ac 0.337 0.344 ab 8.75 8.55 14 0.189 0.197 aa 5.00 4.80 8 n ms012 n side view h 0.244 0.228 5.80 6.20 e 0.050 bsc 1.27 bsc c h e e b a1 a d 0 -8 l 1 variations: package information (continued) (the package drawing(s) in this data sheet may not reflect the most current specifications. for the latest package outline information, go to www.maxim-ic.com/packages .) 6lsot.eps package outline, sot 6l body 21-0058 1 1 g downloaded from: http:///

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