general description the max1032/max1033 multirange, low-power, 14-bit, successive-approximation, analog-to-digital converters (adcs) operate from a single +5v supply and achieve throughput rates up to 115ksps. a separate digital sup- ply allows digital interfacing with 2.7v to 5.25v systems using the spi�-/qspi�-/microwire�-compatible serial interface. partial power-down mode reduces the supply current to 1.3ma (typ). full power-down mode reduces the power-supply current to 1? (typ). the max1032 provides eight (single-ended) or four (true differential) analog input channels. the max1033 provides four (single-ended) or two (true differential) analog input channels. each analog input channel is independently software programmable for seven sin- gle-ended input ranges 0 to (3 x v ref )/2, (-3 x v ref )/2 to 0, 0 to 3 x v ref , -3 x v ref to 0, (? x v ref )/4, (? x v ref )/2 , ? x v ref and three differential input ranges (? x v ref )/2 , 3 x v ref, ? x v ref . an on-chip +4.096v reference offers a small convenient adc solution. the max1032/max1033 also accept an external reference voltage between 3.800v and 4.136v. the max1032 is available in a 24-pin tssop package and the max1033 is available in a 20-pin tssop pack- age. each device is specified for operation from -40? to +85?. applications industrial control systems data-acquisition systems avionics robotics features � software-programmable input range for each channel � single-ended input ranges (v ref = 4.096v) (0 to (3 x v ref )/2, (-3 x v ref )/2 to 0, 0 to 3 x v ref , -3 x v ref to 0, (3 x v ref )/4, (3 x v ref )/2, 3 x v ref ) � differential input ranges (3 x v ref )/2, 3 x v ref , 6 x v ref � eight single-ended or four differential analog inputs (max1032) � four single-ended or two differential analog inputs (max1033) � 16.5v overvoltage tolerant inputs � internal or external reference � 115ksps maximum sample rate � single +5v power supply � 20-/24-pin tssop package max1032/max1033 8- and 4-channel, 3 x v ref multirange inputs, serial 14-bit adcs ________________________________________________________________ maxim integrated products 1 pin configurations ordering information 24 23 22 21 20 19 18 17 1 2 3 4 5 6 7 8 agnd1 agnd2 avdd2 agnd3 ch2 ch1 ch0 avdd1 top view ref refcap dvdd dvdd0 ch6 ch5 ch4 ch3 16 15 14 13 9 10 11 12 dgnd dgndo dout sclk sstrb din cs ch7 tssop max1032 + 19-3573; rev 5; 12/11 for pricing, delivery, and ordering information, please contact maxim direct at 1-888-629-4642, or visit maxim? website at www.maxim-ic.com. part pin-package channels max1032 beug+ 24 tssop 8 max1033 beup+ 20 tssop 4 spi and qspi are trademarks of motorola, inc. microwire is a trademark of national semiconductor corp. pin configurations continued at end of data sheet. note: all devices are specified over the -40? to +85? oper- ating temperature range. + denotes a lead(pb)-free/rohs-compliant package.
max1032/max1033 8- and 4-channel, 3 x v ref multirange inputs, serial 14-bit adcs 2 _______________________________________________________________________________________ absolute maximum ratings electrical characteristics (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (? x v ref ), c dout = 50pf, c sstrb = 50pf, t a = -40? to +85?, unless otherwise noted. typical values are at t a = +25?.) stresses beyond those listed under ?bsolute maximum ratings?may cause permanent damage to the device. these are stress rating s only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specificatio ns is not implied. exposure to absolute maximum rating conditions for extended periods may affect device reliability. avdd1 to agnd1 ....................................................-0.3v to +6v avdd2 to agnd2 ....................................................-0.3v to +6v dvdd to dgnd ........................................................-0.3v to +6v dvddo to dgndo ..................................................-0.3v to +6v dvdd to dvddo......................................................-0.3v to +6v dvdd, dvddo to avdd1 ........................................-0.3v to +6v avdd1, dvdd, dvddo to avdd2 ..........................-0.3v to +6v dgnd, dgndo, agnd3, agnd2 to agnd1 ......-0.3v to +0.3v cs , sclk, din, dout, sstrb to dgndo............................................-0.3v to (v dvddo + 0.3v) ch0?h7 to agnd1 .........................................-16.5v to +16.5v ref, refcap to agnd1 ......................-0.3v to (v avdd1 + 0.3v) continuous current (any pin) ...........................................?0ma continuous power dissipation (t a = +70?) 20-pin tssop (derate 11mw/? above +70?) ..........879mw 24-pin tssop (derate 12.2mw/? above +70?) .......976mw operating temperature range ...........................-40? to +85? junction temperature .....................................................+150? storage temperature range .............................-65? to +150? lead temperature (soldering, 10s) .................................+300? soldering temperature (reflow) .......................................+260? parameter symbol conditions min typ max units dc accuracy (notes 1, 2) resolution 14 bits integral nonlinearity inl ?.25 ? lsb differential nonlinearity dnl no missing codes ? lsb transition noise external or internal reference 1 lsb rms unipolar 0 ?0 single-ended inputs bipolar -1.0 ?2 offset error differential inputs (note 3) bipolar -2.0 ?0 mv channel-to-channel gain matching unipolar or bipolar 0.025 %fsr channel-to-channel offset error matching unipolar or bipolar 1 mv unipolar 3 bipolar 1 offset temperature coefficient fully differential 2 ?/? unipolar ?.5 bipolar ?.8 gain error fully differential ? %fsr unipolar 2 bipolar 1.0 gain temperature coefficient fully differential 2 ppm/? dynamic specifications f in(sine-wave) = 5khz, v in = fsr - 0.05db (notes 1, 2) differential inputs, ? x v ref 85 single-ended inputs, ? x v ref 84 single-ended inputs, (? x v ref )/2 83 signal-to-noise plus distortion sinad single-ended inputs, (? x v ref )/4 79 81 db
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs _______________________________________________________________________________________ 3 electrical characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf, t a = -40c to +85c, unless otherwise noted. typical values are at t a = +25c.) parameter symbol conditions min typ max units differential inputs, 6 x v ref 85 single-ended inputs, 3 x v ref 84 single-ended inputs, (3 x v ref )/2 83 signal-to-noise ratio snr single-ended inputs, (3 x v ref )/4 81 db total harmonic distortion (up to the 5th harmonic) thd -97 db spurious-free dynamic range sfdr 92 99 db aperture delay t ad figure 21 15 ns aperture jitter t aj figure 21 100 ps channel-to-channel isolation 105 db conversion rate external clock mode, figure 2 114 external acquisition mode, figure 3 84 byte-wide throughput rate f sample internal clock mode, figure 4 106 ksps analog inputs (ch0?h3 max1033, ch0?h7 max1032, agnd1) small-signal bandwidth all input ranges, v in = 100mv p-p (note 2) 2 mhz full-power bandwidth all input ranges, v in = 4v p-p (note 2) 700 khz r[2:1] = 001 (-3 x v ref )/4 (+3 x v ref )/4 r[2:1] = 010 (-3 x v ref )/2 0 r[2:1] = 011 0 (+3 x v ref )/2 r[2:1] = 100 (-3 x v ref )/2 (+3 x v ref )/2 r[2:1] = 101 -3 x v ref 0 r[2:1] = 110 0 +3 x v ref input voltage range (table 6) v ch_ r[2:1] = 111 -3 x v ref +3 x v ref v true-differential analog common-mode voltage range v cmdr dif/ sgl = 1 (note 4) -14 +9 v common-mode rejection ratio cmrr dif/ sgl = 1, input voltage range = (3 x v ref )/4 75 db input current i ch_ -3 x v ref < v ch_ < +3 x v ref -1250 +900 a input capacitance c ch_ 5pf input resistance r ch_ 17 k ?
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 4 _______________________________________________________________________________________ parameter symbol conditions min typ max units internal reference (bypass refcap with 0.1? to agnd1 and ref with 1.0? to agnd1) reference output voltage v ref 4.056 4.096 4.136 v reference temperature coefficient tc ref 30 ppm/c ref shorted to agnd1 10 reference short-circuit current i refsc ref shorted to avdd -1 ma reference load regulation i ref = 0 to 0.5ma 0.1 10 mv external reference (refcap = avdd) reference input voltage range v ref 3.800 4.136 v refcap buffer disable threshold v rcth (note 5) v avdd1 - 0.4 v avdd1 - 0.1 v v ref = +4.096v, external clock mode, external acquisition mode, internal clock mode, or partial power-down mode 90 200 reference input current i ref v ref = +4.096v, full power-down mode 0.1 10 a external clock mode, external acquisition mode, internal clock mode, or partial power-down mode 20 45 reference input resistance r ref full power-down mode 40 k ? digital inputs (din, sclk, cs ) input high voltage v ih 0.7 x v dvddo v input low voltage v il 0.3 x v dvddo v input hysteresis v hyst 0.2 v input leakage current i in v in = 0v to v dvddo -10 +10 a input capacitance c in 10 pf digital outputs (dout, sstrb) v dvddo = 4.75v, i sink = 10ma 0.4 output low voltage v ol v dvddo = 2.7v, i sink = 5ma 0.4 v output high voltage v oh i source = 0.5ma v dvddo - 0.4 v dout three-state leakage i ddo cs = dvddo -10 +10 a electrical characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf, t a = -40c to +85c, unless otherwise noted. typical values are at t a = +25c.)
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs _______________________________________________________________________________________ 5 parameter symbol conditions min typ max units power requirements (avdd1 and agnd1, avdd2 and agnd2, dvdd and dgnd, dvddo and dgndo) analog supply voltage avdd1 4.75 5.25 v digital supply voltage dvdd 4.75 5.25 v preamplifier supply voltage avdd2 4.75 5.25 v digital i/o supply voltage dvddo 2.70 5.25 v internal reference 3 3.5 avdd1 supply current i avdd1 external clock mode, external acquisition mode, or internal clock mode external reference 2.3 3 ma dvdd supply current i dvdd external clock mode, external acquisition mode, or internal clock mode 0.8 2 ma avdd2 supply current i avdd2 external clock mode, external acquisition mode, or internal clock mode 13.5 20 ma dvddo supply current i dvddo external clock mode, external acquisition mode, or internal clock mode 0.01 1 ma partial power-down mode 1.3 ma total supply current full power-down mode 0.5 a power-supply rejection ratio psrr all analog input ranges 0.125 lsb timing characteristics (figures 15 and 16) external clock mode 0.272 62 external acquisition mode 0.228 62 sclk period t cp internal clock mode 0.1 s external clock mode 109 external acquisition mode 92 sclk high pulse width (note 6) t ch internal clock mode 40 ns external clock mode 109 external acquisition mode 92 sclk low pulse width (note 6) t cl internal clock mode 40 ns din to sclk setup t ds 40 ns din to sclk hold t dh 0ns sclk fall to dout valid t do 40 ns cs fall to dout enable t dv 40 ns cs rise to dout disable t tr 40 ns cs fall to sclk rise setup t css 40 ns cs high minimum pulse width t cspw 40 ns sclk fall to cs rise hold t csh 0ns sstrb rise to cs fall setup (note 4) 40 ns dout rise/fall time c l = 50pf 10 ns sstrb rise/fall time c l = 50pf 10 ns electrical characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf, t a = -40c to +85c, unless otherwise noted. typical values are at t a = +25c.)
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 6 _______________________________________________________________________________________ note 1: parameter tested at v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v. note 2: see definitions in the parameter definitions section at the end of the data sheet. note 3: guaranteed by correlation with single-ended measurements. note 4: not production tested. guaranteed by design. note 5: to ensure external reference operation, v refcap must exceed (v avdd1 - 0.1v). to ensure internal reference operation, v refcap must be below (v avdd1 - 0.4v). bypassing refcap with a 0.1f or larger capacitor to agnd1 sets v refcap 4.096v. the tran- sition point between internal reference mode and external reference mode lies between the refcap buffer disable threshold minimum and maximum values (figures 17 and 18). note 6: the sclk duty cycle can vary between 40% and 60%, as long as the t cl and t ch timing requirements are met. analog supply current vs. analog supply voltage max1032 toc01 v avdd1 (v) i avdd1 (ma) 5.15 5.05 4.95 4.85 2.2 2.3 2.4 2.5 2.6 2.1 4.75 5.25 external clock mode t a = +85c t a = +25c t a = -40c preamplifier supply current vs. preamplifier supply voltage max1032 toc02 v avdd2 (v) i avdd2 (ma) 5.15 5.05 4.85 4.95 11 12 13 14 16 15 17 18 10 4.75 5.25 external clock mode ain1?ain7 = agnd2 ain0 = +fs t a = +85c t a = +25c t a = -40c digital supply current vs. digital supply voltage max1032 toc03 v dvdd (v) i dvdd (ma) 5.15 5.05 4.95 4.85 0.80 0.85 0.90 0.95 0.75 4.75 5.25 external clock mode data rate = 115ksps t a = +85c t a = +25c t a = -40c typical operating characteristics (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf; unless otherwise noted.) electrical characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf, t a = -40c to +85c, unless otherwise noted. typical values are at t a = +25c.)
max1032/max1033 8- and 4-channel, 3 x v ref multirange inputs, serial 14-bit adcs _______________________________________________________________________________________ 7 digital i/o supply current vs. digital i/o supply voltage max1032 toc04 v dvddo (v) i dvddo (a) 5.15 5.05 4.95 4.85 17 18 19 20 21 16 4.75 5.25 t a = +85c t a = +25c t a = -40c external clock mode data rate = 115ksps analog supply current vs. analog supply voltage max1032 toc05 v avdd1 (v) i avdd1 (ma) 5.15 5.05 4.95 4.85 0.41 0.42 0.43 0.44 0.45 0.46 0.40 4.75 5.25 t a = +85c t a = +25c t a = -40c partial power-down mode typical operating characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf; unless otherwise noted.) preamplifier supply current vs. preamplifier supply voltage max1032 toc06 v avdd2 (v) i avdd2 (ma) 5.15 5.05 4.95 4.85 0.12 0.14 0.16 0.18 0.20 0.10 4.75 5.25 t a = +85c t a = +25c t a = -40c partial power-down mode ain1 ? ain7 = agnd2 ain0 = +fs digital supply current vs. digital supply voltage max1032 toc07 v dvdd (v) i dvdd (ma) 5.15 5.05 4.95 4.85 0.111 0.112 0.113 0.114 0.115 0.110 4.75 5.25 t a = +85c t a = +25c t a = -40c partial power-down mode
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 8 _______________________________________________________________________________________ analog supply current vs. conversion rate max1032 toc08 conversion rate (ksps) i avdd1 (ma) 100 80 60 40 20 2.33 2.34 2.35 2.36 2.37 2.38 2.39 2.32 0 120 continuous external clock mode analog supply current vs. conversion rate max1032 toc09 conversion rate (ksps) i avdd2 (ma) 100 80 60 40 20 13.86 13.87 13.88 13.89 13.90 13.91 13.92 13.93 13.94 13.95 13.85 0 120 continuous external clock mode typical operating characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf; unless otherwise noted.) digital supply current vs. conversion rate max1032 toc10 conversion rate (ksps) i dvdd (ma) 100 80 60 40 20 0.2 0.4 0.6 0.8 1.0 0 0120 continuous external clock mode digital i/o supply current vs. conversion rate max1032 toc11 conversion rate (ksps) i dvddo (ma) 100 80 60 40 20 0.02 0.04 0.06 0.08 0.10 0 0 120 continuous external clock mode note 6: for partial power-down and full power-down modes, external clock mode was used for a burst of continuous samples. partial power-down or full power-down modes were entered thereafter. by using this method, the conversion rate was found by averaging the number of conversions over the time starting from the first conversion to the end of the partial power-down or full power-down modes.
max1032/max1033 offset drift vs. temperature max1032/33 toc14 temperature ( c) offset error (mv) 60 35 10 -15 -0.8 -0.6 -0.4 -0.2 0 0.2 0.4 0.6 0.8 1.0 -1.0 -40 85 bipolar bipolar +3 x v ref 3 x v ref 4 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs _______________________________________________________________________________________ 9 external reference input current vs. external reference input voltage max1032 toc12 external reference voltage (v) external reference current (a) 4.1 4.0 3.9 77 79 81 83 85 75 3.8 4.2 gain drift vs. temperature max1032/33 toc13 temperature ( c) gain error (%fsr) 60 35 10 -15 -0.08 -0.06 -0.04 -0.02 0 0.02 0.04 0.06 0.08 0.10 -0.10 -40 85 3 x v ref bipolar range 3 x v ref 4 bipolar range channel-to-channel isolation vs. input frequency max1032/33 toc15 frequency (khz) isolation (db) 1000 100 10 -100 -80 -60 -40 -20 0 -120 1 10,000 f sample = 115ksps 3 x v ref bipolar range ch0 to ch2 common-mode rejection ratio vs. frequency max1032/33 toc16 frequency (khz) cmrr (db) 1000 100 10 -90 -80 -70 -60 -50 -40 -30 -20 -10 0 -100 1 10,000 f sample = 115ksps 3 x v ref bipolar range integral nonlinearity vs. digital output code max1032/33 toc17 digital output code inl (lsb) 12,288 8192 4096 -0.5 0 0.5 1.0 -1.0 0 16,383 f sample = 115ksps 3 x v ref bipolar range differential nonlinearity vs. digital output code max1032 toc18 digital output code dnl (lsb) 12,288 4096 8192 -0.5 0 0.5 1.0 -1.0 0 16,383 f sample = 115ksps 3 x v ref bipolar range fft at 5khz max1032/33 toc19 frequency (khz) magnitude (db) 50 40 30 20 10 -120 -100 -80 -60 -40 -20 0 -140 0 f sample = 115ksps f in(sine wave) = 5khz 3 x v ref bipolar range typical operating characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf; unless otherwise noted.)
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 10 ______________________________________________________________________________________ snr, sinad, enob vs. analog input frequency max1032/33 toc20 frequency (khz) snr, sinad (db) 100 10 10 20 30 40 50 60 70 80 90 100 0 1 1000 enob (bits) 7 8 9 10 11 12 13 14 15 16 6 enob sinad snr f sample = 115ksps 3 x v ref bipolar range snr, sinad, enob vs. sample rate max1300/01 toc21 sample rate (ksps) snr, sinad (db) 100 10 1 20 40 60 80 100 0 0.1 1000 f in(sine wave) = 5khz 3 x v ref bipolar range enob (bits) 8 10 12 14 16 6 enob snr, sinad -sfdr, thd vs. sample rate max1300/01 toc22 sample rate (ksps) -sfdr, thd (db) 100 10 1 -100 -80 -60 -40 -20 0 -120 0.1 1000 f in(sine wave) = 5khz 3 x v ref bipolar range thd -sfdr -sfdr, thd vs. analog input frequency max1300/01 toc23 frequency (khz) -sfdr, thd (db) 100 10 -100 -80 -60 -40 -20 0 -120 1 1000 f sample = 115ksps 3 x v ref bipolar range thd -sfdr analog input current vs. analog input voltage max1032/33 toc24 analog input voltage (v) analog input current (ma) -0.6 -0.2 0.2 0.6 1.0 -1.0 all modes 0 -3 x v ref +3 x v re f 2 -3 x v ref 2 +3 x v ref small-signal bandwidth max1032/33 toc25 frequency (khz) attenuation (db) 1000 100 10 -40 -35 -30 -25 -20 -15 -10 -5 0 -45 1 10,000 typical operating characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf; unless otherwise noted.)
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 11 full-power bandwidth max1032/33 toc26 frequency (khz) attenuation (db) 1000 100 10 -40 -35 -30 -25 -20 -15 -10 -5 0 -45 1 10,000 reference voltage vs. time max1032/33 toc27 1v/div 0v 4ms/div noise histogram (code center) max1032/33 toc28 code number of hits 8193 10,000 20,000 30,000 40,000 50,000 60,000 70,000 0 8191 8195 8197 65,534 samples 8192 8194 8196 noise histogram (code edge) max1032/33 toc29 code number of hits 8194 5000 10,000 15,000 20,000 25,000 30,000 35,000 0 65,534 samples 8195 8193 8196 8197 8192 typical operating characteristics (continued) (v avdd1 = v avdd2 = v dvdd = v dvdd0 = 5v, v agnd1 = v dgnd = v dgndo = v agnd2 = v agnd3 = 0v, f clk = 3.5mhz (50% duty cycle), external clock mode, v ref = 4.096v (external reference operation), refcap = avdd1, maximum single-ended bipolar input range (3 x v ref ), c dout = 50pf, c sstrb = 50pf; unless otherwise noted.)
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 12 ______________________________________________________________________________________ pin description pin max1032 max1033 name function 1 2 avdd1 analog supply voltage 1. connect avdd1 to a +4.75v to +5.25v power-supply voltage. bypass avdd1 to agnd1 with a 0.1f capacitor. 2 3 ch0 analog input channel 0 3 4 ch1 analog input channel 1 4 5 ch2 analog input channel 2 5 6 ch3 analog input channel 3 6 ch4 analog input channel 4 7 ch5 analog input channel 5 8 ch6 analog input channel 6 9 ch7 analog input channel 7 10 7 cs active-low chip-select input. when cs is low, data is clocked into the device from din on the rising edge of sclk. with cs low, data is clocked out of dout on the falling edge of sclk. when cs is high, activity on sclk and din is ignored and dout is high impedance. 11 8 din serial data input. when cs is low, data is clocked in on the rising edge of sclk. when cs is high, transitions on din are ignored. 12 9 sstrb serial-strobe output. when using the internal clock, sstrb rising edge transitions indicate that data is ready to be read from the device. when operating in external clock mode, sstrb is always low. sstrb does not tri-state, regardless of the state of cs , and therefore requires a dedicated i/o line. 13 10 sclk serial clock input. when cs is low, transitions on sclk clock data into din and out of dout. when cs is high, transitions on sclk are ignored. 14 11 dout serial data output. when cs is low, data is clocked out of dout with each falling sclk transition. when cs is high, dout is high impedance. 15 12 dgndo d i gi tal i/o gr ound . d gnd , dgn d o, agn d 3, agnd 2, and agn d1 m ust be connected tog ether. 16 13 dgnd digital ground. dgnd, dgndo, agnd3, agnd2, and agnd1 must be connected together. 17 14 dvddo digital i/o supply voltage input. connect dvddo to a +2.7v to +5.25v power-supply voltage. bypass dvddo to dgndo with a 0.1f capacitor. 18 15 dvdd digital-supply voltage input. connect dvdd to a 4.75v to 5.25v power-supply voltage. bypass dvdd to dgnd with a 0.1f capacitor. 19 16 refcap bandgap-voltage bypass node. for external reference operation, connect refcap to avdd. for internal reference operation, bypass refcap with a 0.01f capacitor to agnd1 (v refcap 4.096v). 20 17 ref reference-buffer output/adc reference input. for external reference operation, apply an external reference voltage from 3.800v to 4.136v to ref. for internal reference operation, bypassing ref with a 1f capacitor to agnd1 sets v ref = 4.096v 1%. 21 18 agnd3 analog signal ground 3. agnd3 is the adc negative reference potential. connect agnd3 to agnd1. dgnd, dgndo, agnd3, agnd2, and agnd1 must be connected together.
detailed description the max1032/max1033 multirange, low-power, 14-bit successive-approximation adcs operate from a single +5v supply and have a separate digital supply allowing digital interface with 2.7v to 5.25v systems. these 14-bit adcs have internal track-and-hold (t/h) circuitry that supports single-ended and fully differential inputs. for single-ended conversions, the valid analog input voltage range spans from -3 x v ref below ground to +3 x v ref above ground. the maximum allowable differential input voltage spans from -6 x v ref to +6 x v ref . data can be converted in a variety of software-programmable chan- nel and data-acquisition configurations. microprocessor (p) control is made easy through an spi-/qspi-/ microwire-compatible serial interface. the max1032 has eight single-ended analog input channels or four differential channels (see the block diagram at the end of the data sheet). the max1033 has four single-ended analog input channels or two differential channels. each analog input channel is independently soft- ware programmable for seven single-ended input ranges (0 to (3 x v ref )/2, (-3 x v ref )/2 to 0, 0 to 3 x v ref , -3 x v ref to 0, (3 x v ref )/4, (3 x v ref )/2 , 3 x v ref ) and three differential input ranges (3 x v ref )/2, 3 x v ref, 6 x v ref . additionally, all analog input channels are fault tol- erant to 16.5v. a fault condition on an idle channel does not affect the conversion result of other channels. max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 13 pin description (continued) pin max1032 max1033 name function 22 19 avdd2 analog supply voltage 2. connect avdd2 to a 4.75v to 5.25v power-supply voltage. bypass avdd2 to agnd2 with a 0.1f capacitor. 23 20 agnd2 analog ground 2. this ground carries approximately five times more current than agnd1. dgnd, dgndo, agnd3, agnd2, and agnd1 must be connected together. 24 1 agnd1 anal og gr ound 1. d gn d , d gn do, agn d 3, agn d 2, and agnd 1 must b e connected together . 4?0ma plc acceleration pressure temperature wheatestone wheatestone 1 f 0.1 f agnd2 dgndo agnd3 dgnd avdd2 dvdd avdd1 0.1 f 0.1 f 0.1 f 5.0v 5.0v 5.0v max1032 cho ch1 ch2 ch3 ch4 ch5 ch6 ch7 ref agnd1 refcap 0.1 f 3.3v mc68hcxx c dvdd0 sclk cs din sstrb dout v dd sck i/o mosi i/o miso v ss figure 1. typical application circuit
max1032/max1033 power supplies to maintain a low-noise environment, the max1032/ max1033 provide separate power supplies for each section of circuitry. table 1 shows the four separate power supplies. achieve optimal performance using separate avdd1, avdd2, dvdd, and dvddo supplies. alternatively, connect avdd1, avdd2, and dvdd together as close to the device as possible for a conve- nient power connection. connect agnd1, agnd2, agnd3, dgnd, and dgndo together as close to the device as possible. bypass each supply to the corre- sponding ground using a 0.1f capacitor (table 1). if significant low-frequency noise is present, add a 10f capacitor in parallel with the 0.1f bypass capacitor. converter operation the max1032/max1033 adcs feature a fully differen- tial, successive-approximation register (sar) conver- sion technique and an on-chip t/h block to convert voltage signals into a 14-bit digital result. both single- ended and differential configurations are supported with programmable unipolar and bipolar signal ranges. track-and-hold circuitry the max1032/max1033 feature a switched-capacitor t/h architecture that allows the analog input signal to be stored as charge on sampling capacitors. see figures 2, 3, and 4 for t/h timing and the sampling instants for each operating mode. the max1032/max1033 analog input circuitry buffers the input signal from the sampling capacitors, resulting in a constant analog input current with varying input voltage (figure 5). analog input circuitry select differential or single-ended conversions using the associated analog input configuration byte (table 2). the analog input signal source must be capable of dri- ving the adcs 17k ? input resistance (figure 6). figure 6 shows the simplified analog input circuit. the analog inputs are 16.5v fault tolerant and are protect- ed by back-to-back diodes. the summing junction volt- age, v sj , is a function of the channels input common- mode voltage: v r rr v r rr v sj cm . = + ? ? ? ? ? ? ++ + ? ? ? ? ? ? ? ? ? ? ? ? 1 12 2 375 1 1 12 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 14 ______________________________________________________________________________________ table 1. max1032/max1033 power supplies and bypassing power supply/ground supply voltage range (v) typical supply current (ma) circuit section bypassing dvddo/dgndo 2.7 to 5.25 0.07 digital i/o 0.1f to dgndo avdd2/agnd2 4.75 to 5.25 13.5 analog circuitry 0.1f to agnd2 avdd1/agnd1 4.75 to 5.25 3.0 analog circuitry 0.1f to agnd1 dvdd/dgnd 4.75 to 5.25 0.8 digital control logic and memory 0.1f to dgnd table 2. analog input configuration byte bit number name description 7 start start bit. the first logic 1 after cs goes low defines the beginning of the analog input configuration byte. 6c2 5c1 4c0 channel-select bits. sel[2:0] select the analog input channel to be configured (tables 4 and 5). 3 dif/ sgl differential or single-ended configuration bit. dif/ sgl = 0 configures the selected analog input channel for single-ended operation. dif/ sgl = 1 configures the channel for differential operation. in single-ended mode, input voltages are measured between the selected input channel and agnd1, as shown in table 4. in differential mode, the input voltages are measured between two input channels, as shown in table 5. be aware that changing dif/ sgl adjusts the fsr, as shown in table 6. 2r2 1r1 0r0 input-range-select bits. r[2:0] select the input voltage range, as shown in table 6 and figure 7.
as a result, the analog input impedance is relatively constant over input voltage as shown in figure 5. single-ended conversions are internally referenced to agnd1 (tables 3 and 4). in differential mode, in+ and in- are selected according to tables 3 and 5. when con- figuring differential channels, the differential pair follows the analog configuration byte for the positive channel. for example, to configure ch2 and ch3 for a 3 x v ref dif- ferential conversion, set the ch2 analog configuration byte for a differential conversion with the 3 x v ref range (1010 1100). to initiate a conversion for the ch2 and ch3 differential pair, issue the command 1010 0000. analog input bandwidth the max1032/max1033 input-tracking circuitry has a 2mhz small-signal bandwidth. the 2mhz input band- width makes it possible to digitize high-speed transient events. harmonic distortion increases when digitizing signal frequencies above 15khz as shown in the thd and -sfdr vs. input frequency plot in the typical operating characteristics . analog input range and fault tolerance figure 7 illustrates the software-selectable single- ended analog input voltage range that produces a valid digital output. each analog input channel can be inde- pendently programmed to one of seven single-ended input ranges by setting the r[2:0] control bits with dif/ sgl = 0. max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 15 cs sclk 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 din s c2 c1 c0 0 0 0 0 ** analog input track and hold* dout b13 b12 b11 b10 b9 b8 b7 b6 b5 b4 b3 b2 b1 b0 x x byte 1 byte 2 byte 3 byte 4 sstrb hold track hold high impedance high impedance t acq *track and hold timing is controlled by sclk. f sample f sclk / 32 sampling instant **din bytes 2 to 4 must be driven to logic 0 to obtain a valid conversion. figure 2. external clock-mode conversion (mode 0)
max1032/max1033 figure 8 illustrates the software-selectable differential analog input voltage range that produces a valid digital output. each analog input differential pair can be inde- pendently programmed to one of three differential input ranges by setting the r[2:0] control bits with dif/ sgl = 1. regardless of the specified input voltage range and whether the channel is selected, each analog input is 16.5v fault tolerant. the analog input fault protection is active whether the device is unpowered or powered. any voltage beyond fsr, but within the 16.5v fault- tolerant range, applied to an analog input results in a full-scale output voltage for that channel. clamping diodes with breakdown thresholds in excess of 16.5v protect the max1032/max1033 analog inputs during esd and other transient events (figure 6). the clamping diodes do not conduct during normal device operation, nor do they limit the current during such transients. when operating in an environment with the potential for high-energy voltage and/or current tran- sients, protect the max1032/max1033 externally. 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 16 ______________________________________________________________________________________ cs sclk 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 din sc2c1c00000*** analog input track and hold* hold dout b13 b12 b11 b10 b9 b8 b7 b6 b5 b4 b3 b2 b1 b0 x x byte 1 byte 2 byte 3 byte 4 sstrb intclk** 1 2 3 14 15 16 17 track hold t acq 100ns to 400ns f intclk 4.5mhz f sample f sclk / 32 + f intclk / 17 *track and hold timing is controlled by sclk. **intclk is an internal signal and is not accessible to the user. sampling instant high impedance ***din bytes 2 to 4 must be driven to logic 0 to obtain a valid conversion. figure 3. external acquisition-mode conversion (mode 1)
figure 6. simplified analog input circuit max1032 max1033 r2 r1 v sj *r source analog signal source r2 r1 v sj *r source analog signal source in_+ in_+ *minimize r source to avoid gain error and distortion. max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 17 cs scl 1 2 3 4 5 6 7 8 17 18 19 20 21 22 23 24 din s c2 c1 c0 0 0 0 0 analog input trac and hold trac dout b13 b12 b11 b10 b9 b8 b7 b6 b5 b4 b3 b2 b1 b0 x x bte 1 bte 2 bte 3 sstrb intcl 1 2 3 25 26 27 28 9 10 11 12 13 14 15 16 10 11 12 13 14 hold hold t ac 100ns to 400ns f intcl 4.5mhz f sample f sclk / 24 + f intclk / 28 *track and hold timing is controlled by intclk, and is not accessible to the user. **intclk is an internal signal and is not accessible to the user. sampling instant high impedance *** ***din bytes 2 to 4 must be driven to logic 0 to obtain a valid conversion. figure 4. internal clock-mode conversion (mode 2) analog input voltage (v) analog input current (ma) 0 -0.6 -0.2 0.2 0.6 1.0 -1.0 -3 x v ref +3 x v ref all modes 2 -3 x v ref 2 +3 x v ref figure 5. analog input current vs. input voltage
differential common-mode range the max1032/max1033 differential common-mode range (v cmdr ) must remain within -14v to +9v to obtain valid conversion results. the differential com- mon-mode range is defined as: in addition to the common-mode input voltage limita- tions, each individual analog input must be limited to 16.5v with respect to agnd1. the range-select bits r[2:0] in the analog input config- uration bytes determine the full-scale range for the cor- responding channel (tables 2 and 6). figures 9, 10, and 11 show the valid analog input voltage ranges for the max1032/max1033 when operating with fsr = 3 x v ref /2, fsr = 3 x v ref , and fsr = 6 x v ref , respectively. the shaded area contains the valid com- mon-mode voltage ranges that support the entire fsr. v ch ch cmdr _ _ = + () + () ? 2 max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 18 ______________________________________________________________________________________ table 3. input data word formats data bit operation d7 (start) d6 d5 d4 d3 d2 d1 d0 conversion-start byte (tables 4 and 5) 1c2c1c00000 analog-input configuration byte (table 2) 1 c2 c1 c0 dif/ sgl r2 r1 r0 mode-control byte (table 7) 1m2m1m01000 table 4. channel selection in single-ended mode (dif/ sgl = 0) channel-select bit channel c2 c1 c0 ch0 ch1 ch2 ch3 ch4 ch5 ch6 ch7 agnd1 000+ - 001 + - 010 + - 011 + - 100 + - 101 + - 110 +- 111 +- table 5. channel selection in true-differential mode (dif/ sgl = 1) channel-select bit channel c2 c1 c0 ch0 ch1 ch2 ch3 ch4 ch5 ch6 ch7 agnd1 000+- 0 0 1 reserved 010 +- 0 1 1 reserved 100 +- 1 0 1 reserved 110 +- 1 1 1 reserved
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 19 001 010 011 100 101 110 111 0 -3 x v ref +3 x v ref each input is fault tolerant to 16.5v. v ref = 4.096v. (ch_) - agnd1 (v) input range selection bits, r[2:0] (3 x v ref )/2 (3 x v ref )/2 (3 x v ref )/2 3 x v ref 3 x v ref 3 x v ref 6 x v ref 2 -3 x v ref 2 +3 x v ref figure 7. single-ended input voltage ranges 001 010 011 100 101 110 111 +6 x v ref -6 x v ref each input is fault tolerant to 16.5v. v ref = 4.096v. (ch_+) - (ch_-) (v) input range selection bits, r[2:0] 0 3 x v ref 6 x v ref 12 x v ref 2 +3 x v ref 2 -3 x v ref 2 +3 x v ref 2 -3 x v ref figure 8. differential input voltage ranges digital interface the max1032/max1033 feature a serial interface that is compatible with spi/qspi and microwire devices. din, dout, sclk, cs , and sstrb facilitate bidirec- tional communication between the max1032/max1033 and the master at sclk rates up to 10mhz (internal clock mode, mode 2), 3.67mhz (external clock mode, mode 0), or 4.39mhz (external acquisition mode, mode 1). the master, typically a microcontroller, should use the cpol = 0, cpha = 0, spi transfer format, as shown in the timing diagrams of figures 2, 3, and 4. the digital interface is used to: ? select single-ended or true-differential input channel configurations ? select the unipolar or bipolar input range ? select the mode of operation: external clock (mode 0) external acquisition (mode 1) internal clock (mode 2) reset (mode 4) partial power-down (mode 6) full power-down (mode 7) ? initiate conversions and read results data input (din) din configures the conversion start byte, analog input configuration byte and mode-control byte. see figures 2C4 and tables 3C8. in each conversion mode, the din bits must be driven low after the first byte. chip select ( cs ) cs enables communication with the max1032/max1033. when cs is low, data is clocked into the device from din on the rising edge of sclk and data is clocked out of dout on the falling edge of sclk. when cs is high, activity on sclk and din is ignored and dout is high impedance allowing dout to be shared with other peripherals. sstrb is never high impedance and there- fore cannot be shared with other peripherals. serial-strobe output (sstrb) as shown in figures 3 and 4, the sstrb transitions high to indicate that the adc has completed a conversion and results are ready to be read by the master. sstrb remains low in the external clock mode (figure 2) and consequently may be left unconnected. sstrb is dri- ven high or low regardless of the state of cs , therefore sstrb cannot be shared with other peripherals.
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 20 ______________________________________________________________________________________ table 6. range-select bits dif/ sgl r2 r1 r0 mode transfer function 0 0 0 0 no range change* 0001 single-ended bipolar (-3 x v ref )/4 to (+3 x v ref )/4 full-scale range (fsr) = (3 x v ref )/2 figure 12 0010 single-ended unipolar (-3 x v ref )/2 to 0 fsr = (3 x v ref )/2 figure 13 0011 single-ended unipolar 0 to (+3 x v ref )/2 fsr = (3 x v ref )/2 figure 14 0100 single-ended bipolar (-3 x v ref )/2 to (+3 x v ref )/2 fsr = 3 x v ref figure 12 0101 single-ended unipolar (-3 x v ref )/2 to 0 fsr = 3 x v ref figure 13 0110 single-ended unipolar 0v to (+3 x v ref )/2 fsr = 3 x v ref figure 14 0111 default setting single-ended bipolar (-3 x v ref ) to (+3 x v ref ) fsr = 6 x v ref figure 12 1 0 0 0 no range change** 1001 differential bipolar (-3 x v ref )/2 to (+3 x v ref )/2 fsr = 3 x v ref figure 12 1 0 1 0 reserved 1 0 1 1 reserved 1100 differential bipolar 3 x v ref to +3 x v ref fsr = 6 x v ref figure 12 1 1 0 1 reserved 1 1 1 0 reserved 1111 differential bipolar -6 x v ref to +6 x v ref fsr = 12 x v ref figure 12 * conversion-start byte (see table 3). ** mode-control byte (see table 3).
start bit communication with the max1032/max1033 is accom- plished using the three input data word formats shown in table 3. each input data word begins with a start bit. the start bit is defined as the first high bit clocked into din with cs low when any of the following are true: ? data conversion is not in process and all data from the previous conversion has clocked out of dout. ? the device is configured for operation in external clock mode (mode 0) and previous conversion-result bits b13Cb1 have clocked out of dout. ? the device is configured for operation in external acquisition mode (mode 1) and previous conversion- result bits b13Cb5 have clocked out of dout. ? the device is configured for operation in internal clock mode, (mode 2) and previous conversion- result bits b13Cb2 have clocked out of dout. output data format output data is clocked out of dout in offset binary for- mat on the falling edge of sclk, msb first (b13). for output binary codes, see the transfer function section and figures 12, 13, and 14. configuring analog inputs each analog input has two configurable parameters: ? single-ended or true-differential input ? input voltage range these parameters are configured using the analog input configuration byte as shown in table 2. each analog input has a dedicated register to store its input configura- tion information. the timing diagram of figure 15 shows how to write to the analog input configuration registers. figure 16 shows dout and sstrb timing. transfer function an adcs transfer function defines the relationship between the analog input voltage and the digital output code. figures 12, 13, and 14 show the max1032/ max1033 transfer functions. the transfer function is determined by the following characteristics: ? analog input voltage range ? single-ended or differential configuration ? reference voltage the axes of an adc transfer function are typically in least significant bits (lsbs). for the max1032/max1033, an lsb is calculated using the following equation: where n is the number of bits (n = 14) and fsr is the full-scale range (see figures 7 and 8). 1 2 4 096 . lsb fsr v v ref n = max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 21 input voltage (v) common-mode voltage (v) 12 6 0 -6 -12 -12 -8 -4 0 4 8 12 -16 -18 18 figure 9. common-mode voltage vs. input voltage (fsr = 3 x v ref ) input voltage (v) common-mode voltage (v) 12 6 0 -6 -12 -12 -8 -4 0 4 8 12 -16 -18 18 figure 10. common-mode voltage vs. input voltage (fsr = 6 x v ref ) input voltage (v) common-mode voltage (v) 12 6 0 -6 -12 -12 -8 -4 0 4 8 12 -16 -18 18 figure 11. common-mode voltage vs. input voltage (fsr = 12 x v ref )
mode control the max1032/max1033 contain one byte-wide mode- control register. the timing diagram of figure 15 shows how to use the mode-control byte, and the mode-con- trol byte format is shown in table 7. the mode-control byte is used to select the conversion method and to control the power modes of the max1032/max1033. selecting the conversion method the conversion method is selected using the mode- control byte (see the mode control section), and the con- version is initiated using a conversion-start command (table 3, and figures 2, 3, and 4).the max1032/ max1033 convert analog signals to digital data using one of three methods: ? external clock mode, mode 0 (figure 2) ? highest maximum throughput (see the electrical characteristics table) ? user controls the sample instant ? cs remains low during the conversion ? user supplies sclk throughout the adc con- version and reads data at dout ? external acquisition mode, mode 1 (figure 3) ? lowest maximum throughput (see the electrical characteristics table) ? user controls the sample instant ? user supplies two bytes of sclk, then drives cs high to relieve processor load while the adc converts ? after sstrb transitions high, the user supplies two bytes of sclk and reads data at dout ? internal clock mode, mode 2 (figure 4) ? high maximum throughput (see the electrical characteristics table) ? the internal clock controls the sampling instant max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 22 ______________________________________________________________________________________ 1 lsb = fsr x v ref 16,384 x 4.096v binary output code (lsb [hex]) 3fff 3ffe 3ffd 2001 2000 1fff 0003 0002 0001 0000 fsr 0 1 2 3 8,192 16,381 16,383 input voltage (lsb [decimal]) (agnd1) fsr figure 13. ideal unipolar transfer function, single-ended input, -fsr to 0 1 lsb = fsr x v ref 16,384 x 4.096v binary output code (lsb [hex]) 3fff 3ffe 3ffd 2001 2000 1fff 0003 0002 0001 0000 fsr 0 1 2 3 8,192 16,381 16,383 input voltage (lsb [decimal]) (agnd1) fsr figure 14. ideal unipolar transfer function, single-ended input, 0 to +fsr 1 lsb = fsr x v ref 16,384 x 4.096v binary output code (lsb [hex]) 3fff 3ffe 3ffd 2001 2000 1fff 0003 0002 0001 0000 fsr -8,192 -8,190 0 +8,189 +8,191 input voltage (lsb [decimal]) agnd1 (dif/sgl = 0) ch_- (dif/sgl = 1) fsr -1 +1 figure 12. ideal bipolar transfer function, single-ended or differential input
? user supplies one byte of sclk, then drives cs high to relieve processor load while the adc converts ? after sstrb transitions high, the user supplies two bytes of sclk and reads data at dout external clock mode (mode 0) the max1032/max1033s fastest maximum throughput rate is achieved operating in external clock mode. sclk controls both the acquisition and conversion of the analog signal, facilitating precise control over when the analog signal is captured. the analog input sam- pling instant is at the falling edge of the 14th sclk (figure 2). since sclk drives the conversion in external clock mode, the sclk frequency should remain constant while the conversion is clocked. the minimum sclk frequency prevents droop in the internal sampling capacitor voltages during conversion. sstrb remains low in the external clock mode, and as a result may be left unconnected if the max1032/ max1033 will always be used in the external clock mode. max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 23 cs sclk din dout 18 start sel2 sel1 sel0 r2 r1 r0 dif/sgl t cl t cp t ch t dv t css t ds t dh t csh t cspw t tr 18 start m2 m1 m0 1 0 0 0 analog input configuration byte mode control byte high impedance high impedance high impedance figure 15. analog input configuration byte and mode-control byte timing cs sclk dout t css sstrb t sscs msb t do note: sstrb and cs remain low in external clock mode (mode 0). high impedance figure 16. dout and sstrb timing table 7. mode-control byte bit number bit name description 7 start start bit. the first logic 1 after cs goes low defines the beginning of the mode-control byte. 6m2 5m1 4m0 mode-control bits. m[2:0] select the mode of operation as shown in table 8. 3 1 bit 3 must be a logic 1 for the mode-control byte. 2 0 bit 2 must be a logic 0 for the mode-control byte. 1 0 bit 1 must be a logic 0 for the mode-control byte. 0 0 bit 0 must be a logic 0 for the mode-control byte.
external acquisition mode (mode 1) the slowest maximum throughput rate is achieved with the external acquisition method. sclk controls the acqui- sition of the analog signal in external acquisition mode, facilitating precise control over when the analog signal is captured. the internal clock controls the conversion of the analog input voltage. the analog input sampling instant is at the falling edge of the 16th sclk (figure 3). for the external acquisition mode, cs must remain low for the first 15 clock cycles and then rise on or after the falling edge of the 16th clock cycle as shown in figure 3. for optimal performance, idle din and sclk during the conversion. with careful board layout, transitions at din and sclk during the conversion have a minimal impact on the conversion result. after the conversion is complete, sstrb asserts high and cs can be brought low to read the conversion result. sstrb returns low on the rising sclk edge of the subsequent start bit. internal clock mode (mode 2) in internal clock mode, the internal clock controls both acquisition and conversion of the analog signal. the inter- nal clock starts approximately 100ns to 400ns after the falling edge of the eighth sclk and has a rate of about 4.5mhz. the analog input sampling instant occurs at the falling edge of the 11th internal clock signal (figure 4). for the internal clock mode, cs must remain low for the first seven sclk cycles and then rise on or after the falling edge of the eighth sclk cycle. after the conver- sion is complete, sstrb asserts high and cs can be brought low to read the conversion result. sstrb returns low on the rising sclk edge of the subsequent start bit. reset (mode 4) as shown in table 8, set m[2:0] = 100 to reset the max1032/max1033 to its default conditions. the default conditions are full power operation with each channel configured for 3 x v ref , bipolar, single-ended conver- sions using external clock mode (mode 0). partial power-down mode (mode 6) as shown in table 8, when m[2:0] = 110, the device enters partial power-down mode. in partial power- down, all analog portions of the device are powered down except for the reference voltage generator and bias supplies. to exit partial power-down, change the mode by issu- ing one of the following mode-control bytes (see the mode control section): ? external-clock-mode control byte ? external-acquisition-mode control byte ? internal-clock-mode control byte ? reset byte ? full power-down-mode control byte this prevents the max1032/max1033 from inadvertent- ly exiting partial power-down mode because of a cs glitch in a noisy digital environment. full power-down mode (mode 7) when m[2:0] = 111, the device enters full power-down mode and the total supply current falls to 1a (typ). in full power-down, all analog portions of the device are powered down. when using the internal reference, upon exiting full power-down mode, allow 10ms for the internal reference voltage to stabilize prior to initiating a conversion. to exit full power-down, change the mode by issuing one of the following mode-control bytes (see the mode control section): ? external-clock-mode control byte ? external-acquisition-mode control byte ? internal-clock-mode control byte ? reset byte ? partial power-down-mode control byte max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 24 ______________________________________________________________________________________ m2 m1 m0 mode 0 0 0 external clock (default) 0 0 1 external acquisition 0 1 0 internal clock 0 1 1 reserved 1 0 0 reset 1 0 1 reserved 1 1 0 partial power-down 1 1 1 full power-down table 8. mode-control bits m[2:0]
this prevents the max1032/max1033 from inadvertent- ly exiting full power-down mode because of a cs glitch in a noisy digital environment. power-on reset the max1032/max1033 power up in normal operation configured for external clock mode with all circuitry active (tables 7 and 8). each analog input channel (ch0Cch7) is set for single-ended conversions with a 3 x v ref bipolar input range (table 6). allow the power supplies to stabilize after power-up. do not initiate any conversions until the power supplies have stabilized. additionally, allow 10ms for the internal reference to stabilize when c ref = 1.0f and c refcap = 0.1f. larger reference capacitors require longer stabilization times. internal or external reference the max1032/max1033 operate with either an internal or external reference. the reference voltage impacts the adcs fsr (figures 12, 13, and 14). an external refer- ence is recommended if more accuracy is required than the internal reference provides, and/or multiple converters require the same reference voltage. internal reference the max1032/max1033 contain an internal 4.096v bandgap reference. this bandgap reference is connect- ed to refcap through a nominal 5k ? resistor (figure 17). the voltage at refcap is buffered creating 4.096v at ref. when using the internal reference, bypass refcap with a 0.1f or greater capacitor to agnd1 and bypass ref with a 1.0f or greater capacitor to agnd1. external reference for external reference operation, disable the internal reference and reference buffer by connecting refcap to avdd1. with avdd1 connected to refcap, ref becomes a high-impedance input and accepts an external reference voltage. the max1032/ max1033 can accept an external reference voltage of 4.096v or less. however, to meet all of the electrical characteristics specifications, v ref must be > 3.8v. the max1032/max1033 external reference current varies depending on the applied reference voltage and the operating mode (see the external reference input current vs. external reference input voltage in the typical operating characteristics ). applications information noise reduction additional samples can be taken and averaged (over- sampling) to remove the effect of transition noise on conversion results. the square root of the number of samples determines the improvement in performance. for example, with 2/3lsb rms (4lsb p-p ) transition noise, 16 (4 2 = 16) samples must be taken to reduce the noise to 1lsb p-p . interface with 0 to 10v signals in industrial-control applications, 0 to 10v signaling is common. for 0 to 10v applications, configure the selected max1032/max1033 input channel for the sin- gle-ended 0 to 3 x v ref input range (r[2:0] = 110, table 6). the 0 to 3 x v ref range accommodates 0 to 10v where the signals saturate at approximately 3 x v ref if out of range. interface with 4?0ma signals figure 19 illustrates a simple interface between the max1032/max1033 and a 4C20ma signal. 4C20ma sig- naling can be used as a binary switch (4ma represents a logic-low signal, 20ma represents a logic-high sig- nal), or for precision communication where currents between 4ma and 20ma represent intermediate analog data. for binary switch applications, connect the 4C20ma signal to the max1032/max1033 with a resis- tor to ground. for example, a 250 ? resistor converts the 4C20ma signal to a 1v to 5v signal. adjust the resistor value so the parallel combination of the resistor and the max1032/max1033 source impedance is 250 ? . in this application, select the single-ended 0 to 3 x v ref /2 range (r[2:0] = 011, table 6). for applications that require precision measurements of continuous analog currents between 4ma and 20ma, use a buffer to prevent the max1032/max1033 input from diverting current from the 4C20ma signal. max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 25 ref refcap agnd1 4.096v bandgap reference 5k ? 1x sar adc ref 4.096v 1.0 f 0.1 f v rcth max1032 max1033 figure 17. internal reference operation
bridge application the max1032/max1033 convert 1khz signals more accurately than a similar sigma-delta converter that might be considered in bridge applications. the input impedance of the max1032, in combination with the cur- rent-limiting resistors, can affect the gain of the max1032. in many applications this error is acceptable, but for applications that cannot tolerate this error, the max1032 inputs can be buffered (figure 20). connect the bridge to a low-offset differential amplifier and then the true-differential inputs of the max1032/max1033. larger excitation voltages take advantage of more of the 3 x v ref /4 differential input voltage range. select an input voltage range that matches the amplifier output. be aware of the amplifier offset and offset-drift errors when selecting an appropriate amplifier. dynamically adjusting the input range software control of each channels analog input range and the unipolar endpoint overlap specification make it possible for the user to change the input range for a channel dynamically and improve performance in some applications. changing the input range results in a small lsb step-size over a wider output voltage range. for example, by switching between a (-3 x v ref )/2 to 0v range and a 0v to (+3 x v ref )/2 range, an lsb is but the input voltage range effectively spans from (-3 x v ref )/2 to (+3 x v ref )/2, fsr = 3 x v ref ). layout, grounding, and bypassing careful pc board layout is essential for best system per- formance. boards should have separate analog and digi- tal ground planes and ensure that digital and analog signals are separated from each other. do not run analog and digital (especially clock) lines parallel to one another, or digital lines underneath the device package. figure 1 shows the recommended system ground con- nections. establish an analog ground point at agnd1 and a digital ground point at dgnd. connect all analog grounds to the star analog ground. connect the digital grounds to the star digital ground. connect the digital ground plane to the analog ground plane at one point. for lowest noise operation, make the ground return to the star grounds power-supply low impedance and as short as possible. high-frequency noise in the avdd1 power supply degrades the adcs high-speed comparator perfor- mance. bypass avdd1 to agnd1 with a 0.1f ceramic surface-mount capacitor. make bypass capacitor con- nections as short as possible. parameter definitions integral nonlinearity (inl) inl is the deviation of the values on an actual transfer function from a straight line. this straight line is either a best straight-line fit or a line drawn between the end- points of the transfer function once offset and gain errors have been nullified. the max1032/max1033 inl is measured using the endpoint method. () ,. + 32 16 384 4 096 vv ref ref max1032/max1033 8- and 4-channel, 3 x v ref multirange inputs, serial 14-bit adcs 26 ______________________________________________________________________________________ ref refcap agnd1 4.096v bandgap reference 5k ? 1x sar adc ref 4.096v 1.0 f v rcth max1032 max1033 avdd1 max6341 v+ 1.0 f out gnd in figure 18. external reference operation
differential nonlinearity (dnl) dnl is the difference between an actual step width and the ideal value of 1 lsb. a dnl error specification of greater than -1 lsb guarantees no missing codes and a monotonic transfer function. transition noise transition noise is the amount of noise that appears at a code transition on the adc transfer function. conversions performed with the analog input right at the code transi- tion can result in code flickering in the lsbs. channel-to-channel isolation channel-to-channel isolation indicates how well each analog input is isolated from the others. the channel-to- channel isolation for these devices is measured by applying a near full-scale magnitude 5khz sine wave to the selected analog input channel while applying an equal magnitude sine wave of a different frequency to all unselected channels. an fft of the selected chan- nel output is used to determine the ratio of the magni- tudes of the signal applied to the unselected channels and the 5khz signal applied to the selected analog input channel. this ratio is reported, in db, as channel- to-channel isolation. max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 27 max1032 250 ? 4?0ma input 250 ? 4?0ma input ch0 ch8 c figure 19. 4C20ma application max1032 max1033 ch0 ref p ch1 low-offset differential amplifier bridge figure 20. bridge application
unipolar offset error -fsr to 0v when a zero-scale analog input voltage is applied to the converter inputs, the digital output is all ones (0x3fff). ideally, the transition from 0x3fff to 0x3ffe occurs at agnd1 - 0.5 lsb. unipolar offset error is the amount of deviation between the measured zero-scale transition point and the ideal zero-scale transition point, with all untested channels grounded. 0v to +fsr when a zero-scale analog input voltage is applied to the converter inputs, the digital output is all zeros (0x0000). ideally, the transition from 0x0000 to 0x0001 occurs at agnd1 + 0.5 lsb. unipolar offset error is the amount of deviation between the measured zero-scale transition point and the ideal zero-scale transition point, with all untested channels grounded. bipolar offset error when a zero-scale analog input voltage is applied to the converter inputs, the digital output is a one followed by all zeros (0x2000). ideally, the transition from 0x1fff to 0x2000 occurs at (2 n-1 - 0.5)lsb. bipolar off- set error is the amount of deviation between the mea- sured midscale transition point and the ideal midscale transition point, with untested channels grounded. gain error when a positive full-scale voltage is applied to the con- verter inputs, the digital output is all ones (0x3fff). the transition from 0x3ffe to 0x3fff occurs at 1.5 lsb below full scale. gain error is the amount of deviation between the measured full-scale transition point and the ideal full-scale transition point with the offset error removed and all untested channels grounded. unipolar endpoint overlap unipolar endpoint overlap is the change in offset when switching between complementary input voltage ranges. for example, the difference between the volt- age that results in a 0x3fff output in the -3 x v ref /2 to 0v input voltage range and the voltage that results in a 0x0000 output in the 0 to +3 x v ref /2 input voltage range is the unipolar endpoint overlap. the unipolar endpoint overlap is positive for the max1032/max1033, preventing loss of signal or a dead zone when switch- ing between adjacent analog input voltage ranges. small-signal bandwidth a 100mv p-p sine wave is applied to the adc, and the input frequency is then swept up to the point where the amplitude of the digitized conversion result has decreased by -3db. full-power bandwidth a 95% of full-scale sine wave is applied to the adc, and the input frequency is then swept up to the point where the amplitude of the digitized conversion result has decreased by -3db. common-mode rejection ratio (cmrr) cmrr is the ability of a device to reject a signal that is common to or applied to both input terminals. the common-mode signal can be either an ac or a dc sig- nal or a combination of the two. cmr is expressed in decibels. common-mode rejection ratio is the ratio of the differential signal gain to the common-mode signal gain. cmrr applies only to differential operation. power-supply rejection ratio (psrr) psrr is the ratio of the output-voltage shift to the power-supply-voltage shift for a fixed input voltage. for the max1032/max1033, avdd1 can vary from 4.75v to 5.25v. psrr is expressed in decibels and is calculated using the following equation: for the max1032/max1033, psrr is tested in bipolar operation with the analog inputs grounded. aperture jitter aperture jitter, t aj , is the statistical distribution of the variation in the sampling instant (figure 21). aperture delay aperture delay, t ad , is the time from the falling edge of sclk to the sampling instant (figure 21). signal-to-noise ratio (snr) snr is computed by taking the ratio of the rms signal to the rms noise. rms noise includes all spectral com- ponents to the nyquist frequency excluding the funda- mental, the first five harmonics, and the dc offset. signal-to-noise plus distortion (sinad) sinad is computed by taking the ratio of the rms sig- nal to the rms noise plus distortion. rms noise plus distortion includes all spectral components to the nyquist frequency excluding the fundamental and the dc offset. sinad db signal noise rms rms ( ) log = ? ? ? ? ? ? 20 psrr db vv vv out v out v [ ] log . . (. ) (. ) = ? ? ? ? ? ? ? ? 20 525 475 525 475 max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 28 ______________________________________________________________________________________
effective number of bits (enob) enob indicates the global accuracy of an adc at a specific input frequency and sampling rate. with an input range equal to the adcs full-scale range, calcu- late the enob as follows: total harmonic distortion (thd) for the max1032/max1033, thd is the ratio of the rms sum of the input signals first four harmonic com- ponents to the fundamental itself. this is expressed as: where v 1 is the fundamental amplitude, and v 2 through v 5 are the amplitudes of the 2nd- through 5th-order harmonic components. spurious-free dynamic range (sfdr) sfdr is the ratio of rms amplitude of the fundamental (maximum signal component) to the rms value of the next-largest spectral component. thd vvvv v log = +++ ? ? ? ? ? ? ? ? 20 2 2 3 2 4 2 5 2 1 enob sinad . . = ? ? ? ? ? ? ? 176 602 max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 29 t ad t aj intclk (mode 2) analog input track and hold track hold sample instant sclk (mode 0) 13 14 15 sclk (mode 1) 15 16 10 11 12 figure 21. aperture diagram
max1032/max1033 8- and 4-channel, ? x v ref multirange inputs, serial 14-bit adcs 30 ______________________________________________________________________________________ chip information process: bicmos block diagram max1032 ch0 ch1 ch2 ch3 ch4 ch5 ch6 ch7 agnd1 analog input mux and multirange circuitry pga agnd2 avdc2 4.096v bandgap reference 1x 5k ? in ref refcap ref control logic and registers fifo clock out sar adc serial i/o agnd2 avdd2 agnd3 avdd1 dgnd dvdd dgndo sclk dout sstrb din cs dvddo pin configurations (continued) 20 19 18 17 16 15 14 13 1 2 3 4 5 6 7 8 agnd2 avdd2 agnd3 ref ch1 ch0 avdd1 agnd1 refcap dvdd dvdd0 dgnd din cs ch3 ch2 12 11 9 10 dgndo dout sclk sstrb max1033 tssop top view +
max1300/max1301 8- and 4-channel, 3 x v ref multirange inputs, serial 14-bit adcs ______________________________________________________________________________________ 31 package information for the latest package outline information and land patterns (footprints), go to www.maxim-ic.com/packages . note that a ?? ?? or ??in the package code indicates rohs status only. package drawings may show a different suffix character, but the drawing per tains to the package regardless of rohs status. package type package code outline no. land pattern no. 20 tssop u20+2 21-0066 90-0116 24 tssop u24+1 21-0066 90-0118
max1032/max1033 8- and 4-channel, 3 x v ref multirange inputs, serial 14-bit adcs maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a maxim product. no circu it patent licenses are implied. maxim reserves the right to change the circuitry and specifications without notice at any time. the parametric values (min and max limits) shown in the electrical characteristics table are guaranteed. other parametric values quoted in this data sheet are provided for guidanc e. 32 ____________________maxim integrated products, 120 san gabriel drive, sunnyvale, ca 94086 408-737-7600 � 2011 maxim integrated products maxim is a registered trademark of maxim integrated products, inc. revision history revision number revision date description pages changed 0 2/05 initial release � 2 12/06 updated the electrical characteristics and package information . added revision history . 1, 3?, 30, 31 3 7/07 updated ordering information , electrical characteristics , and differential common-mode range section. 1, 3, 18 4 8/11 updated general description , features , electrical characteristics , typical operating characteristics , detailed description and other sections, tables 1 and 6, figures 2?, 7, and 8. 1?0, 13?7, 18?1, 24?6, 28 5 12/11 released the max1032 and updated the electrical characteristics . 1, 2
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