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| general description the max1407/max1408/max1409/max1414 are low- power, general-purpose, multichannel data-acquisition systems (das). these devices are optimized for low- power applications. all the devices operate from a sin- gle +2.7v to +3.6v power supply and consume a maximum of 1.15ma in run mode and only 2.5? in sleep mode. the max1407/max1408/max1414 feature a differential 8:1 input multiplexer to the adc, a programmable three-state digital output, an output to shutdown an external power supply, and a data ready output from the adc. the max1408 has eight auxiliary analog inputs, while the max1407/max1414 include four auxil- iary analog inputs and two 10-bit force/sense dacs. the max1414 features a 50mv trip threshold for the signal-detect comparator while the others have a 0mv trip threshold. the max1409 is a 20-pin version of the das family with a differential 4:1 input multiplexer to the adc, one auxiliary analog input, and one 10-bit force/sense dac. the max1407/max1408/max1414 are available in space-saving 28-pin ssop packages, while the max1409 is available in a 20-pin ssop package. applications medical instruments industrial control systems portable equipment data-acquisition system automatic testing robotics features +2.7v to +3.6v supply voltage range in standby, idle, and run mode (down to 1.8v in sleep mode) 1.15ma run mode supply current 2.5? sleep mode supply current (wake-up, rtc, and voltage monitor active) multichannel 16-bit sigma-delta adc ?.5 lsb (typ) integral nonlinearity 30hz or 60hz continuous conversion rate buffered or unbuffered mode gain of +1/3, +1, or +2v/v unipolar or bipolar mode on-chip offset calibration 10-bit force/sense dacs buffered 1.25v, 18ppm/? (typ) bandgap reference output spi�/qspi� or microwire�-compatible serial interface system support functions rtc (valid til 9999) and alarm high-frequency pll clock output (2.4576mhz) +1.8v and +2.7v reset and power-supply voltage monitors signal detect comparator interrupt generator ( int and drdy ) three-state digital output wake-up circuitry 28-pin ssop (max1407/max1408/max1414), 20-pin ssop (max1409) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ________________________________________________________________ maxim integrated products 1 19-2229; rev 0; 10/01 pin configurations continued at end of data sheet. typical operating circuit appears at end of data sheet. spi and qspi are trademarks of motorola, inc. microwire is a trademark of national semiconductor corp. ordering information part temp. range pin-package max1407 cai 0 c to +70 c 28 ssop max1408 cai 0 c to +70 c 28 ssop max1409 cap 0 c to +70 c 20 ssop max1414 cai 0 c to +70 c 28 ssop 28 27 26 25 24 23 22 21 20 19 18 17 16 15 1 2 3 4 5 6 7 8 9 10 11 12 13 14 out2 in3 dv dd dgnd sclk din dout clkin clkout fout in2 in1 cpll av dd agnd ref in0 out1 fb1 do fb2 top view max1407 max1414 cs wu2 reset wu1 int drdy shdn pin configurations 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.
max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 2 _______________________________________________________________________________________ absolute maximum ratings 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. av dd to agnd .........................................................-0.3v to +6v av dd to dv dd ...................................................... -0.3v to +0.3v analog inputs to agnd .........................-0.3v to +(av dd + 0.3v) digital inputs to dgnd.............................................-0.3v to +6v maximum current input into any pin ..................................50ma continuous power dissipation (t a = +70?) 20-pin ssop (derate 8.0mw/? above +70?) ...........640mw 28-pin ssop (derate 9.52mw/? above +70?) .........762mw dv dd to dgnd.........................................................-0.3v to +6v agnd to dgnd.....................................................-0.3v to +0.3v analog outputs to agnd ......................-0.3v to +(av dd + 0.3v) digital outputs to dgnd .......................-0.3v to +(av dd + 0.3v) ref to agnd.........................................-0.3v to +(av dd + 0.3v) operating temperature range: max14__ca_ ......................................................0? to +70? max14__ea_ ...................................................-40? to +85? lead temperature (soldering, 10s) ................................+300 ? storage temperature range .............................-65? to +150? junction temperature ......................................................+150? electrical characteristics (dv dd = av dd = +2.7v to 3.6v, 4.7? at ref, internal v ref , 18nf between cpll and av dd , 32.768khz crystal across clkin and clkout, t a = t min to t max , unless otherwise noted. typical values are at t a = +25?.) parameter symbol conditions min typ max u n i t s adc accuracy resolution (no missing codes) res 16 bits unbuffered mode, unipolar mode, gain = 1, v neg = 0.2v, fully differential input (note 7) 1.5 3.5 u nb uffer ed m od e, u ni p ol ar m od e, g ai n = 2, v n e g = 0.625v , p seud o- d i ffer enti al i np ut 1.75 unbuffered mode, bipolar mode, gain = 1, v neg = 0.625v, fully differential input 1.70 integral nonlinearity inl buffered mode, bipolar mode, gain = 2, v neg = 0.625v, fully differential input 2.50 lsb gain = 2 �5 gain = 1 ?0 unipolar gain = 1/3 ?0 gain = 2 �8 gain = 1 ?6.5 output rms noise (note 1) bipolar mode gain = 1/3 ?8.5 ? rms offset error on-chip calibration removes this error ? % of fs r offset drift ?.5 ?/? gain error excludes offset and reference errors ? % of fs r gain drift excludes offset and reference errors ? p p m /� c max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc _______________________________________________________________________________________ 3 electrical characteristics (continued) (dv dd = av dd = +2.7v to 3.6v, 4.7? at ref, internal v ref , 18nf between cpll and av dd , 32.768khz crystal across clkin and clkout, t a = t min to t max , unless otherwise noted. typical values are at t a = +25?.) parameter symbol conditions min typ max u n i t s 1/3 1 pga gain see pga gain section 2 v/v power-supply rejection ratio gain = 1, unipolar and buffered mode 70 db rate bit = 0 30 output update rate continuous conversion rate bit = 1 60 hz turn-on time excluding reference 50 s signal detect comparator max1407/max1408/max1409 -10 0 10 differential input-detection threshold voltage max1414 44 50 56 mv common-mode input voltage 0 0.8 v turn-on time 10 s analog inputs adc gain = 1 0 v ref adc gain = 2 0 v ref/2 unipolar mode adc gain = 1/3 0 av dd adc gain = 1 -v ref v ref adc gain = 2 -v ref/2 v ref/2 differential input voltage range bipolar mode adc gain = 1/3 -av dd av dd v unbuffered -0.05 av dd absolute input voltage range buffered 0.05 1.40 v unbuffered agnd av dd common-mode input voltage range buffered 0.05 1.40 v common-mode rejection ratio gain = 1, unipolar and buffered mode 90 db 30hz data rate 15.360 input sampling rate fout = 2.4576mhz 60hz data rate 30.720 khz input current buffered mode 0.5 na input capacitance 15 pf f o r c e- sen se d a c ( al l m easur em ents m ad e w i th fb1( 2) shor ted to o u t1( 2) , unl ess other w i se noted ) . ( m ax 1407/m ax 1409/m ax 1414 onl y) resolution 10 bits differential nonlinearity guaranteed monotonic (note 2) 1.0 lsb integral nonlinearity (note 2) 1.0 lsb offset error (note 3) 20 mv offset drift 5 v/ � c gain error excludes offset and reference drift 3.6 mv gain drift excludes offset and reference drift 10 ppm/ � c line regulation 190 v/v current into fb1(2) 0.5 na max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 4 _______________________________________________________________________________________ electrical characteristics (continued) (dv dd = av dd = +2.7v to 3.6v, 4.7f at ref, internal v ref , 18nf between cpll and av dd , 32.768khz crystal across clkin and clkout, t a = t min to t max , unless otherwise noted. typical values are at t a = +25 � c.) parameter symbol conditions min typ max u n i t s output slew rate 010hex to 3ffhex and 3ffhex to 010hex cod e sw i ng , r l = 12k ? , c l = 200p f 18.0 v/ms output settling time to 1/2 lsb (at 10-bit accuracy) of full- scale with code transition from 010hex to 3ffhex, r l = 12k ? , c l = 200pf 65 s turn-on time 100 s out1, out2 output range no load (note 4) 0.05 av dd - 0.2 v external reference (internal reference powered down) input voltage range 1.25 0.10 v input resistance 540 k ? input current 2.3 a internal reference (av dd = 3v, unless otherwise noted) output voltage t a = +25 � c 1.225 1.25 1.275 v output voltage temperature coefficient 18 p p m / � c output short-circuit current 3.4 ma line regulation ? v re f / ? v dd 2.7 max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 6 _______________________________________________________________________________________ electrical characteristics (continued) (dv dd = av dd = +2.7v to 3.6v, 4.7f at ref, internal v ref , 18nf between cpll and av dd , 32.768khz crystal across clkin and clkout, t a = t min to t max , unless otherwise noted. typical values are at t a = +25 � c.) parameter symbol conditions min typ max u n i t s d0 output low voltage (max1407/max1408/max1414 only) i sink = 200a, dv dd = +2.7v to +3.6v 0.7 mv d0 output high voltage (max1407/max1408/max1414 only) i s ou rc e = 2m a, d v d d = + 2.7v to + 3.6v dv dd - 0.1 v power requirements run, idle, and standby mode 2.7 3.6 supply voltage range v dd sleep mode 1.8 3.6 v max1407/max1414 1.15 max1408 1.03 run mode max1409 1.09 ma max1407/max1414 650 max1408 530 idle mode max1409 590 standby mode max1407/max1408/ max1409/max1414 330 supply current (note 5) i dd sleep mode v dd = 2.7v max1407/max1408/ max1409/max1414 1.7 2.5 a timing characteristics (max1407/max1408/max1409/max1414: av dd = dv dd = 2.7v to 3.6v, t a = t min to t max, unless otherwise noted.) parameter symbol conditions min typ max units timing parameters sclk operating frequency f sclk 2.1 mhz sclk cycle time t cyc 476 ns sclk pulse width high t ch 190 ns sclk pulse width low t cl 190 ns din to sclk setup t ds 100 ns din to sclk hold t dh 0ns sclk fall to output data valid t do c l = 50pf (see load circuit) 200 ns cs fall to output enable t dv c l = 50pf (see load circuit) 240 ns cs rise to output disable t tr c l = 50pf (see load circuit) 240 ns cs to sclk rise setup t css 100 ns cs to sclk rise hold t csh 0ns max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc _______________________________________________________________________________________ 7 note 1: single conversion. note 2: dnl and inl are measured between code 010hex and 3ffhex. note 3: offset error is referenced to code 010hex. note 4: output swing is a function of external gain-setting feedback resistors and ref voltage. note 5: measured with no load on fout, dout, and the dac amplifiers. sclk is idle, and all digital inputs are at dgnd or dv dd . note 6: shdn stays high if the pll is on. note 7: actual worst-case performance is 2.5lsb. guaranteed limit of 3.5lsb is due to production test limitation. note 8: guaranteed by design. not production tested. timing characteristics (continued) (max1407/max1408/max1409/max1414: av dd = dv dd = 2.7v to 3.6v, t a = t min to t max, unless otherwise noted.) parameter symbol conditions min typ max units typical timing parameters out1/out2 turn-off time input impedance > 1m ? (max1407/max1409/max1414 only) 100 s sleep voltage monitor timeout period t dslp the delay for the sleep voltage monitor output, reset , to go high after av dd rises above the reset threshold (+1.8v when bit vm = 1 and +2.7v, when bit vm = 0); this is largely driven by the startup of the 32khz oscillator 1.54 s wu1 or wu2 pulse width t wu minimum pulse width required to detect a wake-up event 1s shutdown deassert delay t dpu the delay for shdn to go high after a valid wake-up event 1s fout turn-on time t dfon the turn-on time for the high-frequency clock; it is gated by an and function with three signals � the reset signal, the internal low voltage v dd monitor signal, and the assertion of the pll; the time delay is timed from when the low-voltage monitor trips or the reset going high, whichever happens later; fout always starts in the low state 31.25 ms int delay t dfi the delay for int to go low after the fout clock output has been enabled; int is used as an interrupt signal to inform the p the high-frequency clock has started 7.82 ms fout disable delay t dfof the delay after a shutdown command has asserted and before fout is disabled; this gives the microcontroller time to clean up and go into sleep mode properly 1.95 ms shdn assertion delay t dpd the delay after a shutdown command has asserted and before shdn is pulled low (turning off the dc-dc converter) (note 6) 2.93 ms max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 8 _______________________________________________________________________________________ typical operating characteristics (a vdd = d vdd = 3v, max1407 used, t a = +25 � c, unless otherwise noted.) 0 200 100 400 300 600 500 700 2.70 3.00 3.15 2.85 3.30 3.45 3.60 supply current vs. supply voltage max1407 toc01 supply voltage (v) supply current ( a) run mode idle mode standby 0 200 100 400 300 600 500 700 -40 10 35 -15 60 85 supply current vs. temperature max1407 toc02 temperature ( c) supply current ( a) standby idle mode run mode 1.0 2.0 1.5 3.0 2.5 3.5 4.0 1.80 2.80 2.30 3.30 sleep current vs. falling v dd max1407 toc03 suplly voltage (v) sleep current ( a) 0 1.0 0.5 2.0 1.5 2.5 3.0 -40 10 -15 35 60 85 sleep mode supply current vs. temperature max1407 toc04 temperature ( c) supply current ( a) load circuits 6k ? 6k ? dout dout dgnd dgnd dv dd a) v oh to high-z b) v ol to high-z c load 50pf c load 50pf load circuits for disable time 6k ? 6k ? dout dout dgnd dgnd dv dd a) high-z to v oh and v ol to v oh b) high-z to v ol and v oh to v ol c load 50pf c load 50pf load circuits for enable time max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc _______________________________________________________________________________________ 9 typical operating characteristics (continued) (a vdd = d vdd = 3v, max1407 used, t a = +25 � c, unless otherwise noted.) 0 1 3 2 4 5 2.7 3.1 2.9 3.3 3.5 maximum inl vs. v dd (unipolar mode, t = +25 c, pseudo-differential input) max1407 toc05 v dd (v) maximum inl (lsb) a b a: gain = 1, unbuffered mode, 60sps b: gain = 1, unbuffered mode, 30sps 0 1.5 1.0 0.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 2.7 3.1 2.9 3.3 3.5 maximum inl vs. v dd (bipolar mode, t = +25 c, fully differential input) max1407 toc06 v dd (v) maximum inl (lsb) a b a: gain = 2, buffered mode, 60sps b: gain = 2, buffered mode, 30sps 0 1.5 1.0 0.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 040 20 60 80 maximum inl vs. temperature (unipolar mode, v dd = 3v, pseudo-differential input) max1407 toc07 temperature (?) maximum inl (lsb) a b a: gain = 1, unbuffered mode, 60sps b: gain = 1, unbuffered mode, 30sps 0 1.5 1.0 0.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 040 20 60 80 maximum inl vs. temperature (bipolar mode, v dd = 3v, fully differential input) max1407 toc08 temperature ( c) maximum inl (lsb) a b a: gain = 2, buffered mode, 60sps b: gain = 2, buffered mode, 30sps max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 10 ______________________________________________________________________________________ typical operating characteristics (continued) (a vdd = d vdd = 3v, max1407 used, t a = +25 � c, unless otherwise noted.) 0 1.0 0.5 2.0 1.5 2.5 3.0 0.3 0.7 0.5 0.9 1.1 maximum inl vs. common-mode input voltage (bipolar mode, buffered mode, v dd = 2.7v, 30sps, fully differential input, t = +25 c) max1407 toc09 common-mode input voltage (v) maximum inl (lsb) a: gain = 1 b: gain = 2 a b -2.0 -1.5 -1.0 -0.5 0 0.5 1.0 1.5 2.0 -1.25 -0.75 -0.25 0.25 0.75 1.25 inl vs. fully differential input voltage (bipolar mode, gain = 1, unbuffered mode, v cm = 0.625v, v dd = 3v, t = +25 c) max1407 toc10 differential input voltage (v) inl (lsb) -2.0 -1.5 -1.0 -0.5 0 0.5 1.0 1.5 2.0 0 0.2 0.4 0.8 1.0 inl vs. pseudo-differential input voltage range (unipolar mode, gain = 1, unbuffered mode, v neg = 0, v dd = 3v, t = +25 c) max1407 toc11 differential voltage (v) inl (lsb) 1.2 0.6 0 1.5 1.0 0.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 040 20 60 80 uncorrected offset error vs. temperature (unbuffered mode, v dd = 3v) max1407 toc12 temperature ( c) offset error (lsb) a b a: gain = 1, unipolar mode b: gain = 2, bipolar mode max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 11 0.06 0.08 0.07 0.10 0.09 0.11 0.12 0 gain error vs. temperature max1407 toc13 temperature ( � c) gain error (%) 40 20 60 80 v dd = 3v b d a c a: gain = 1, unipolar mode, unbuffered mode b: gain = 1, bipolar mode, unbuffered mode c: gain = 2, unipolar mode, buffered mode d: gain = 2, bipolar mode, buffered mode -0.12 -0.08 -0.10 -0.04 -0.06 0 -0.02 0.02 -40 10 -15 35 60 85 reference voltage vs. temperature max1407 toc14 temperature ( � c) % deviation v ref = 1.24406v i ref = 0 1.24380 1.24390 1.24385 1.24400 1.24395 1.24405 1.24410 0 400 600 200 800 1000 1200 reference voltage vs. output source current max1407 toc15 source current ( a) reference voltage (v) 1.24398 1.24402 1.24400 1.24406 1.24404 1.24410 1.24408 1.24412 2.70 3.00 3.15 2.85 3.30 3.45 3.60 reference voltage vs. supply voltage max1407 toc16 supply voltage (v) reference voltage (v) no load -5.2 -4.8 -5.0 -4.2 -4.4 -4.6 -3.6 -3.8 -4.0 -3.4 -40 10 -15 35 60 85 dac offset error vs. temperature max1407 toc17 temperature ( � c) offset error (mv) idle mode -4.600 -4.575 -4.550 -4.525 -4.500 -4.475 -4.450 -4.425 -4.400 2.70 3.00 2.85 3.15 3.30 3.45 3.60 dac offset error vs. supply voltage max1407 toc18 supply voltage (v) offset error (mv) idle mode typical operating characteristics (continued) (a vdd = d vdd = 3v, max1407 used, t a = +25 � c, unless otherwise noted.) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 12 ______________________________________________________________________________________ typical operating characteristics (continued) (a vdd = d vdd = 3v, max1407 used, t a = +25 � c, unless otherwise noted.) -1.50 -1.20 -1.35 -0.60 -0.75 -1.05 0 -0.30 -0.45 0.15 -40 10 -15 35 60 85 dac gain error vs. temperature max1407 toc19 temperature ( � c) gain error (lsb) -0.15 -0.90 idle mode internal ref used -0.20 -0.10 -0.15 0 -0.05 0.05 0.10 2.70 3.00 3.15 2.85 3.30 3.45 3.60 dac gain error vs. supply voltage max1407 toc20 supply voltage (v) gain error (lsb) idle mode internal ref used -0.15 -0.05 -0.10 0.05 0 0.10 0.15 0 200 300 400 100 500 600 700 800 9001000 1100 dac integral nonlinearity vs. digital code (av dd = 2.7v) max1407 toc21 code inl (lsb) -0.15 -0.05 -0.10 0.05 0 0.10 0.15 0 200 300 400 100 500 600 700 800 9001000 1100 dac integral nonlinearity vs. digital code (av dd = 3.6v) max1407 toc22 code inl (lsb) -0.100 -0.075 0.075 -0.025 -0.050 0 0.025 0.050 0.100 0 200 300 400 100 500 600 900 800 1000 700 1100 dac differential nonlinearity vs. digital code (av dd = 2.7v) max1407 toc23 code dnl (lsb) -0.100 -0.075 0.075 -0.025 -0.050 0 0.025 0.050 0.100 0 200 300 400 100 500 600 900 800 1000 700 1100 dac differential nonlinearity vs. digital code (av dd = 3.6v) max1407 toc24 code dnl (lsb) dac large-signal output step response v ref = 1.25v, av dd = 3.0v, r l = 0 max1407 toc25 out_ 500mv/div cs 2v/div max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 13 typical operating characteristics (continued) (a vdd = d vdd = 3v, max1407 used, t a = +25 � c, unless otherwise noted.) 1.2450 1.2445 1.2440 1.2435 1.2430 2.7 3.0 3.3 3.6 dac output voltage vs. supply voltage max1407 toc26 supply voltage (v) dac output voltage (v) output at full scale no load dac buffer in unity gain 1.00 1.10 1.05 1.20 1.15 1.25 1.30 023 1 456 dac output voltage vs. source current max1407 toc27 load current (ma) dac output voltage (v) output at full scale dac buffer in unity gain 015 10 5202535 30 40 1.20 1.30 1.35 1.25 1.40 1.45 1.50 1.55 1.60 1.65 1.70 1.75 1.80 dac output voltage vs. sink current max1407 toc28 sink current (a) dac output voltage (v) -0.15 -0.06 -0.09 -0.12 -0.03 0 0.03 0.06 0.09 0.12 0.15 -40 10 -15 35 60 85 dac output voltage vs. temperature max1407 toc29 temperature ( � c) dac output voltage (%) v ref = 1.24406v i ref = 0 -0.25 -0.15 -0.20 -0.05 -0.10 0.05 0 0.10 -40 10 -15 35 60 85 voltage monitor threshold vs. temperature max1407 toc30 temperature ( c) % deviation v 1.8v_threshold = 1.865v v 2.7v_threshold = 2.75v max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 14 ______________________________________________________________________________________ max1407 max1414 max1408 max1409 pin function 1 fb2 force/sense dac2 feedback input � 1 � in7 analog input. analog input to the negative mux only. 1 fb1 force/sense dac1 feedback input 22 � d0 digital output. three-state general-purpose digital output. 3 fb1 force/sense dac1 feedback input � 3 � in6 analog input. analog input to the negative mux only. 4 � 2 out1 force/sense dac1 output � 4 � in4 analog input. analog input to the positive mux only. 5 5 3 in0 analog input. analog input to both the positive and negative mux. 6 6 4 ref 1.25v reference buffer output/external reference input. reference voltage for the adc and the dac. connect a 4.7f capacitor to ref between ref and agnd. 7 7 5 agnd analog ground. reference point for the analog circuitry. agnd connects to the ic substrate. 886av dd analog supply voltage 9 9 7 cpll pll capacitor connection pin. connect an 18nf ceramic capacitor between cpll and av dd . 10 10 8 wu1 active-low wake-up input. internally pulled up. the device will wake-up from sleep mode to standby mode when wu1 is asserted. 11 11 9 wu2 active-low wake-up input. internally pulled up. the device will wake-up from sleep mode to standby mode when wu2 is asserted. 12 12 10 reset active-low reset output. it remains low while av dd is below the threshold and stays low for a timeout period after av dd rises above the threshold. reset is an open-drain output. 13 13 � in1 analog input. analog input to both the positive and negative mux. 14 14 � in2 analog input. analog input to both the positive and negative mux. 15 15 � shdn programmable shutdown output. goes low in sleep mode. 16 16 � drdy active-low data ready output. a logic low indicates that a new conversion result is available in the data register. drdy returns high upon completion of a full output word read operation. drdy also signals the end of an adc offset-calibration. 17 17 11 fout 2.4576mhz clock output. fout can be used to drive the input clock of a p. 18 18 12 clkout 32khz crystal output. connect a 32khz crystal between clkin and clkout. 19 19 13 clkin 32khz crystal input. connect a 32khz crystal between clkin and clkout. pin description max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 15 detailed information the max1407/max1408/max1409/max1414 are low- power, general-purpose, multichannel das featuring a multiplexed fully differential 16-bit ? analog-to-digital converter (adc), 10-bit force/sense digital-to-analog converters (dac), a real-time clock (rtc) with an alarm, a bandgap voltage reference, a signal detect comparator, two power-supply voltage monitors, wake- up control circuitry, and a high-frequency phase-locked loop (pll) clock output all controlled by a 3-wire serial interface. (see table 1 for the max1407/max1408/ max1409/max1414 feature sets and figures 1, 2, 3 for the functional diagrams ). these das directly interface to various sensor outputs and once configured provide the stimulus, conditioning, and data conversion, as well as microprocessor support. figure 4 is a typical application circuit for the max1407/max1414. the 16-bit ? adc is capable of programmable contin- uous conversion rates of 30hz or 60hz and gains of 1/3, 1, and 2v/v to suit applications with different power and dynamic range constraints. the force/sense dacs provide 10-bit linearity for precise sensor applications. max1407 max1414 max1408 max1409 pin function 20 20 14 int active-low interrupt output. int goes low when the pll output is ready, when the signal-detect comparator is tripped, or when the alarm is triggered. 21 21 15 dout serial data output. dout outputs serial data from the internal shift register on sclk � s falling edge. when cs is high, dout is three-stated. 22 22 16 din serial data input. data on din is written to the input shift register and is clocked in at sclk � s rising edge when cs is low. 23 23 17 sclk serial clock input. apply an external serial clock to transfer data to and from the device. this serial clock can be continuous, with data transmitted in a train of pulses, or intermittent while cs is low. 24 24 18 cs active-low chip-select input. cs is used to select the active device in systems with more than one device on the serial bus. data will not be clocked into din unless cs is low. when cs is high, dout is three-stated. 25 25 19 dgnd digital ground. reference point for digital circuitry. 26 26 20 dv dd digital supply voltage 27 27 � in3 analog input. analog input to both the positive and negative mux. 28 out2 force/sense dac2 output � 28 � in5 analog input. analog input to the positive mux only. pin description (continued) table 1. max1407/max1408/max1409/max1414 feature sets part adc auxiliary analog inputs force/ sense dac three- state digital output comparator threshold (mv) rtc adc data ready ( drdy ) external power- supply shutdown control adc differential input mux max1407 4 2 yes 0 yes yes yes 8 max1414 4 2 yes 50 yes yes yes 8 max1408 8 0 yes 0 yes yes yes 8 max1409 1 1 no 0 yes no no 4 max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 16 ______________________________________________________________________________________ with the use of two external resistors, the dac output can go from 0.05v to av dd - 0.2v. the adcs and dacs both utilize a precise low-drift 1.25v internal bandgap reference for conversions and setting of the full-scale range. for applications that require increased accuracy, power-down the internal reference and con- nect an external reference at ref. the rtc is leap year compensated until 9999 and provides an alarm function that can be used to wake-up the system or cause an interrupt at a predefined time. the power-supply volt- age monitors detect when av dd falls below a trip threshold voltage at either +1.8v or +2.7v causing the reset to be asserted. the 4-wire serial interface is used to communicate directly between spi, qspi, and microwire devices for system configuration and readback functions. analog input protection internal protection diodes clamp the analog input to av dd and agnd, which allow the channel input pins to swing from agnd - 0.3v to av dd + 0.3v without dam- age. however, for accurate conversions near full scale, the inputs must not exceed av dd by more than 50mv or be lower than agnd by 50mv. analog mux the max1407/max1408/max1414 include a dual 8 to 1 multiplexer for the positive and negative inputs of the adc. the max1409 has a dual 4 to 1 multiplexer at the inputs of the adc. figures 1, 2, and 3 illustrate which signals are present at the inputs of each multiplexer for the max1407/max1408/max1409/max1414. the muxp and muxn bits of the mux register choose which inputs will be seen at the input to the adc (tables 4 and 5) and the signal-detect comparator. see the mux register description under the on-chip registers section for multiplexer functionality. input buffers the max1407/max1408/max1409/max1414 provide input buffers to isolate the analog inputs from the capaci- tive load presented by the adc modulator (figure 5 and 6). the buffers are chopper stabilized to reduce the effect of their dc offsets and low-frequency noise. since the buffers can represent more than 25% of the total analog power dissipation (typically 220a), they may be shut down in applications where minimum power dissipation is required and the capacitive input load is not a concern (see adc and power1 registers ). disable the buffers in applications where the inputs must operate close to agnd or above +1.4v. the buffers are individually enabled or disabled. figure 1. max1407/max1414 functional diagram max1407/max1414 *max1414 has a +50mv signal-detect comparator threshold. 10-bit dac interrupt generator ref reset dgnd 16-bit adc pga buf buf wake-up logic serial interface 2.4576mhz pll 32.768khz oscillator 1.25v bandgap reference 1.8v/2.7v p supervisors reset generator rtc and alarm digital output 10-bit dac 8:1 input mux 8:1 input mux buf agnd cpll fout clkin clkout comparator av dd sclk din dout out2 out1 in3 in2 in1 in0 ref av dd fb2 fb1 in3 in2 in1 in0 ref agnd wu2 wu1 shdn int drdy d0 out1 fb1 out2 fb2 dv dd cs max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 17 figure 3. max1409 functional diagram max1409 interrupt generator ref reset dgnd 16-bit adc pga buf buf wake-up logic serial interface 2.4576mhz pll 32.768khz oscillator 1.25v bandgap reference 1.8v/2.7v p supervisors reset generator rtc and alarm 10-bit dac 4:1 input mux 4:1 input mux buf agnd cpll fout clkin clkout comparator av dd sclk din dout wu2 wu1 int out1 fb1 out1 av dd in0 ref dv dd fb1 in0 ref agnd cs figure 2. max1408 functional diagram max1408 interrupt generator ref reset dgnd 16-bit adc pga buf buf wake-up logic serial interface 2.4576mhz pll 32.768khz oscillator 1.25v bandgap reference 1.8v/2.7v p supervisors reset generator rtc and alarm digital output 8:1 input mux 8:1 input mux buf agnd cpll fout clkin clkout comparator av dd sclk din dout in5 in4 in3 in2 in1 in0 ref av dd in7 in6 in3 in2 in1 in0 ref agnd wu2 wu1 shdn int drdy d0 dv dd cs max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 18 ______________________________________________________________________________________ buffered mode when used in buffered mode, the buffers isolate the inputs from the sampling capacitors. the sampling- related gain error is dramatically reduced since only a small dynamic load is present from the chopper. the multiplexer exhibits an input leakage current of 0.5na (typ). with high-source resistances, this leakage cur- rent may result in a large dc offset error. figure 4. max1407/max1414 typical application circuit max1407 max1414 max1833 lx r l r f r t lx in0 ref in1 10 f 10 f v dd = 3.3v or v bat 0.1 f 0.1 f 18nf 4.7 f fb1 fb2 out2 out1 reset clkin clkout fout cs sclk din dout int drdy reset clkin 0.1 f output sck mosi miso input input p / c wu2 i/o v bat batt out rst shdn sensor we ce re gnd cpll agnd dgnd av dd dv dd v dd v ss shdn 32.768khz wu1 i/o figure 5. analog input � buffered mode r ext c ext r mux c pin r in c st c amp c sample c c max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 19 unbuffered mode when used in unbuffered mode, the switched capacitor sampling front end of the modulator presents a dynam- ic load to the driving circuitry. the size of the internal sampling capacitor and the input sampling frequency (figure 6) determines the dynamic load (see dynamic input impedance section). as the gain increases, the input sampling capacitance also increases. since the max1407/max1408/max1409/max1414 sample at a constant rate for all gain settings, the dynamic load pre- sented by the inputs varies with the gain setting. pga gain an integrated programmable-gain amplifier (pga) pro- vides three user-selectable gains: +1/3v/v, +1v/v, and +2v/v to maximize the dynamic range of the adc. bits gain1 and gain0 set the desired gain (see adc register ). the gain of +1/3v/v allows the direct mea- surement of the supply voltage through an internal mul- tiplexer input or through an auxillary input. adc modulator the max1407/max1408/max1409/max1414 perform analog-to-digital conversions using a single-bit, sec- ond-order, switched-capacitor delta-sigma modulator. the delta-sigma modulation converts the input signal into a digital pulse train whose average duty cycle rep- resents the digitized signal information. the pulse train is then processed by a digital decimation filter. the modulator provides 2nd-order frequency shaping of the quantization noise resulting from the single bit quantizer. the modulator is fully differential for maxi- mum signal-to-noise ratio and minimum susceptibility to power-supply noise. the modulator operates at one of two different sampling rates resulting in an output data rate of either 30hz or 60hz (see adc register ). adc offset calibration the max1407/max1408/max1409/max1414 are capa- ble of performing digital offset correction to eliminate changes due to power-supply voltage or system tem- perature. at the end of a calibration cycle, a 16-bit cali- bration value is stored in the offset register in two � s compliment format. after completing a conversion, the max1407/max1408/max1409/max1414 subtract the calibration value from the adc conversion result and write the offset compensated data to the data register (see offset register section). either a positive or nega- tive offset can be calibrated. during offset calibration, drdy will go high. drdy goes low after calibration is complete. the offset register can be programmed to skew the adc offset with a maximum range from -2 15 to (+2 15 - 1)lsbs, e.g., if the programmed 2 � s complement value is +2lsb (-2lsb), this translates to a -2lsb (+2lsb) shift in bipolar mode or a -4lsb (+4lsb) shift in unipolar mode.to maintain optimum performance, recal- ibrate the adc if the temperature changes by more than 20 � c. offset calibration should also be performed after any changes in pga gain, bipolar/unipolar input range, buffered/unbuffered mode, or conversion speed. during calibration, the two mulitplexers will be disabled and the inputs to the adc will internally be shorted to a com- mon-mode voltage. adc digital filter the on-chip digital filter processes the 1-bit data stream from the modulator using a sinc 3 filter function. the sinc 3 filters settle in three data word periods. the settling time is 3/60hz or 50ms (for rate bit in adc register set to 1) and 3/30hz or 100ms (for rate bit set to � 0 � ). adc digital filter characteristics the transfer function for a sinc 3 filter function is that of three cascaded sinc 1 filters. this can be described in the z-domain by: and in the frequency domain by: where n, the decimation factor, is the ratio of the modu- lator frequency f m to the output frequency f n . h ? () = ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? 1 3 n n m m sin sin hz () = ? () ? () ? ? ? ? ? ? ? ? ? ? ? ? 1 1 1 1 3 n z z n figure 6. analog input � unbuffered mode r ext c ext r mux c pin r sw c st c sample c c max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 20 ______________________________________________________________________________________ figure 7 shows the filter frequency response. the sinc 3 characteristic cutoff frequency is 0.262 times the first notch frequency. this results in a cutoff frequency of 15.72hz for a first filter notch frequency of 60hz (out- put data rate of 60hz). the response shown in figure 7 is repeated at either side of the digital filter � s sample frequency (f m ) (f m = 15.36khz for 30hz and f m = 30.72khz for 60hz) and at either side of the related har- monics (2f m , 3f m ,....). the output data rate for the digital filter corresponds with the positioning of the first notch of the filter � s fre- quency response. therefore, for the plot of figure 7 where the first notch of the filter is at 60hz, the output data rate is 60hz. the notches of this (sinx/x) 3 filter are repeated at multiples of the first notch frequency. the sinc 3 filter provides an attenuation of better than 100db at these notches. for step changes at the input, enough settling time must be allowed before valid data can be read. the settling time depends upon the output data rate chosen for the filter. the settling time of the sinc 3 filter to a full- scale step input can be up to four times the output data period, or three times if the step change is synchrozied with fsync. force/sense dac (max1407/max1409/max1414) the max1407/max1414 incorporate two 10-bit force/ sense dacs while the max1409 has one. the dacs use a precise 1.25v internal bandgap reference for set- ting the full-scale range. program the dac1 and dac2 registers through the serial interface to set the output voltages of the dacs seen at out1 and out2. shorting fb1(2) and out1(2) configures the dac in a unity-gain setting. connecting resistors in a voltage- divider configuration between out1(2), fb1(2), and gnd sets a different closed-loop gain for the output amplifier (see the applications information section). the dac output amplifier typically settles to 1 / 2 lsb from a full-scale transition within 65s, when it is con- nected in unity gain and loaded with 12k ? in parallel with 200pf. loads less than 2k ? may degrade perfor- mance. see the typical operating characteristics sec- tion for the source-and-sink capabilty of the dac output. the max1407/max1409/max1414 feature a software- programmable shutdown mode for the dacs that reduce the total power consumption when they are not used. the two dacs can be powered-down indepen- dently or simultaneously by clearing the da1e and da2e bits (see power1 register ). dac outputs out1 and out2 go high impedance when powered down. the dacs are automatically powered up and ready for a conversion when idle or run mode is entered. voltage monitors the max1407/max1408/max1409/max1414 include two on-board voltage monitors. when av dd is below the reset trip threshold, reset goes low and the rst bit of the status register is set to � 1 � . when av dd is below the low v dd trip threshold, the lvd bit of the status register is set to 1. reset voltage monitor the reset voltage monitor is powered up at all times (provided that vm = 0 and lvde = 1 or vm = 1 and lsde = 1). a threshold voltage of either +1.8v or +2.7v may be selected for the reset voltage monitor (see power2 register ). at initial power-up, the reset trip threshold is set to 2.7v. if the reset voltage monitor is tripped, the rst bit of the status register is set to � 1 � and reset goes low. reset is held low for 1.54 seconds (typ) after av dd rises above the reset voltage monitor threshold. if av dd is no longer below the reset threshold, reading the status register will clear rst. low v dd voltage monitor when the device is operating in run, idle, or standby mode (see power modes ) and av dd goes below +2.7v, the low v dd monitor trips, indicating that the supply volt- age is below the safe minimum for proper operation. when tripped, the low v dd voltage monitor sets the lvd bit of the status register to 1. if av dd is no longer below +2.7v, reading the status register will clear lvd. the low v dd monitor is powered down in sleep mode. when it is powered down, the lvd bit stays unchanged. the lvd is cleared if it is read in sleep mode. figure 7. frequency response of the sinc 3 filter (notch at 60hz) -160 -120 -140 -100 -80 -60 -20 -40 0 0 406080 20 100 120 140 160 180 200 frequency (hz) gain (db) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 21 internal/external reference the max1407/max1408/max1409/max1414 have an internal low-drift +1.25v reference used for both adc and dac conversion. the buffered reference output can be used as a reference source for other devices in the system. the internal reference requires a 4.7f low- esr ceramic capacitor or tantalum capacitor connect- ed between ref and agnd. for applications that require increased accuracy, power-down the internal reference by writing a 0 to the refe bit of the power1 register and connect an external reference source to ref. the valid external reference voltage range is 1.25v 100mv. crystal oscillator the on-chip oscillator requires an external crystal (or resonator) connected between clkin and clkout with an operating frequency of 32.768khz. this oscilla- tor is used for the rtc, alarm, signal-detect compara- tor, and pll. the oscillator is operational down to 1.8v. in any crystal-based oscillator circuit, the oscillator fre- quency is based on the characteristics of the crystal. it is important to select a crystal that meets the design requirements, especially the capacitive load (c l ) that must be placed across the crystal pins in order for the crystal to oscillate at its specified frequency. c l is the capacitance that the crystal needs to � see � from the oscillator circuit; it is not the capacitance of the crystal itself. the max1407/max1408/max1409/max1414 have 6pf of capacitance across the clkin and clk- out pins. choose a crystal with a 32.768khz oscillation frequency and a 6pf capacitive load such as the c- 002rx32-e from epson crystal. using a crystal with a c l that is larger than the load capacitance of the oscil- lator circuit will cause the oscillator to run faster than the specified nominal frequency of the crystal. conversely, using a crystal with a c l that is smaller than the load capacitance of the oscillator circuit will cause the oscillator to run slower than the specified nominal frequency of the crystal. phase-locked loop (pll) and fout an on-board phase-locked loop generates a 2.4576mhz clock at fout from the 32.768khz crystal oscillator. fout can be used to clock a p or other dig- ital circuitry. connect an 18nf ceramic capacitor from cpll to av dd to create the 2.4576mhz clock signal at fout. to power down the pll, clear plle in the power2 register (see power2 register ) or write to the sleep register. fout will be active for 1.95ms (t dfof ) after receiving either power-down command and then go low. this provides extra clock signals to the p to complete a shutdown sequence. the pll is active in all modes except the sleep mode (see power modes ). to reactivate the pll, the following conditions must be met: av dd is greater than the low v dd voltage monitor threshold, reset is deasserted, and the plle bit is equal to � 1 � . fout is enabled 31.25ms (t dfon ) after the pll is activated. at initial power-up, the pll is enabled. if reset is asserted while the pll is running, the pll does not shut down. real-time clock (rtc) the integrated rtc provides the current second, minute, hour, date, month, day, year, century, and mil- lenium information. an internally generated reference clock of 1.024khz (derived from the 32.768khz crystal) drives the rtc. the rtc operates in either 24-hour or 12-hour format with an am/pm indicator (see rtc_hour register ). an internal calendar compensates for months with less than 31 days and includes leap year correc- tion through the year 9999. the rtc operates from a supply voltage of +1.8v to +3.6v and consumes less than 1a current. time of day alarm the max1407/max1408/max1409/max1414 offer a time of day alarm which generates an interrupt when the rtc reaches a preset combination of seconds, minutes, hours, and day (see alarm registers ). in addition to set- ting a � single-shot � alarm, the time of day alarm can also be programmed to generate an alarm every sec- ond, minute, hour, day, or week. � don � t care � states can be inserted into one or more fields if it is desired for them to be ignored for the alarm condition. the time of day alarm wakes up the device into standby mode if it is in sleep mode. the time of day alarm operates from a supply voltage of +1.8v to +3.6v. interrupt ( i i n n t t ) int indicates one of three conditions. after receiving a valid interrupt ( int goes low), read the status register and the al_status register (if the alarm is enabled) to identify the source of the interrupt. the three sources of interrupts are from the clk, sdc, and alirq bits. pll ready on power-up, int is high. 7.82ms (t dfi ) after the pll output appears on fout, int goes low (see figure 15). the clk bit of the status register is set to � 1 � after fout is enabled. reading the status register clears the clk bit. int remains low until the device detects a start bit through the serial interface from the p. the purpose of this interrupt is to inform the p that the fout clock signal is present. max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 22 ______________________________________________________________________________________ signal detect the int pin will also go low and stay low when the dif- ferential voltage on the selected analog inputs exceeds the signal-detect comparator trip threshold (0mv for the max1407/max1408/max1409 and 50mv for the max1414). this will latch the sdc bit of the status reg- ister to one. additional signal detect interrupts cannot be generated unless the sdc bit is cleared. to clear the sdc bit, the status register must be read and the input must be below the signal-detect threshold. powering down the signal detect-comparator without reading the status register will also clear the sdc bit. similar to the power-up case, int goes high when the device detects a start bit through the serial interface from the p. time of day alarm if the device is in sleep mode, the alarm will wake up the device and set the alirq bit. int is asserted when the pll is turned on. if an alarm occurs while the device is awake (biase = 1), the alirq bit will be set and int will go low. int remains low until the device detects a start bit through the serial interface from the p. alirq is reset to 0 when any alarm register is read or written to. shutdown ( s s h h d d n n ) shdn is an active-low output that can be used to con- trol an external power supply. powering up the pll (plle = 1) or writing a � 1 � to the shde bit of the power2 register causes shdn to go high. shdn goes low when the shde bit is set to 0 only if the pll is pow- ered down (plle = 0). the shdn output stays high for 2.93ms (t dpd ) after receiving a power-down command, allowing the external power supply to stay alive so that the p can properly complete a shutdown sequence. shdn is not available on the max1409. note: entering sleep mode automatically sets plle and shde to 0. any wake-up event will cause shdn to go high. (see wake-up section.) data ready ( d d r r d d y y ) this pin will go low and stay low upon completion of an adc conversion or end of an adc calibration. this sig- nals the p that a valid conversion or calibration result has been written to the data or the offset register. the drdy pin goes high either when the p has fin- ished reading the conversion/calibration result on the last rising edge of sclk (see figure 8), or when the next conversion result is about to be written to the data register. when no read operation is performed, drdy pulses at 60hz with a pulse high time of 162.76s (or 30hz with a pulse high time of 325.52s) drdy is not available on the max1409. to see when the adc has completed a normal conversion or a cali- bration conversion for the max1409, check the status of the add bit in the status register. serial digital interface the spi/qspi/microwire-serial interface consists of chip select ( cs ), serial clock (sclk), data in (din), and data out (dout) (see figure 9). the serial interface provides access to 29 on-chip registers, allowing con- trol to all the power modes and functional blocks, including the adcs, dacs, and rtc. table 2 lists the address and read/write accessibility of all the registers. a logic high on cs three-states dout and causes the max1407/max1408/max1409/max1414 to ignore any signals on sclk and din. to clock data into or out of the internal shift register, drive cs low. sclk synchro- nizes the data transfer. the rising edge of sclk clocks din into the shift register, and the falling edge of sclk figure 8. adc conversion timing diagram cs sclk din dout 1 0 a4 a3 a2 a1 a0 x 1 1 a4 a3 a2 a1 a0 x d7 d6 d5 d4 d3 d2 d1 d0 d8 d9 d15 d14 d13 d12 d11 d10 drdy d7 d6 d5 d4 d3 d2 d1 d0 adc conv max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 23 clocks dout out of the shift register. din and dout are transferred as msb first (data is left justified). figure 10 shows detailed serial interface timing. all communication with the max1407/max1408/ max1409/max1414 begins with a command byte on din, where the first logic 1 on din will be recognized as the start bit (msb) for the command byte (table 3). the following seven clock cycles load the command into a shift register. these seven bits specify which of the registers will be accessed, whether a read or write oper- ation will take place, and the length of the subsequent data (0-bit, 8-bit, 16-bit, or burst mode). idle din low between writes to the max1407/max1408/max1409/ max1414. figures 11 � 14 show the read and write timing for 8- and 16-bit data. data is updated on the last rising edge of the sclk in the command word. cs should not go high between data transfers. if cs is toggled before the end of a write or read operation, the device can enter an incorrect mode. clock in 72 zeros to clear this state and re-arm the serial interface. after loading the command byte into the shift register, additional clocks shift out data on dout for a read and shift in data on din for a write operation. figure 9. spi/qspi interface connections max1407 max1408 max1409 max1414 drdy not available on max1409 reset clkin clkout fout cs sclk din dout int drdy reset clkin output sck mosi miso input input p/ c wu2 i/o 32.768khz wu1 i/o figure 10. detailed serial interface timing ? ? ? ? ? ? ? ? ? ? ? ? cs sclk din dout t csh t cl t ds t dh t dv t ch t cyc t do t tr t csh t css max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 24 ______________________________________________________________________________________ cs allows the sclk, din, and dout signals to be shared among several devices. when short on proces- sor i/o pins, connect cs to dgnd, and operate the seri- al digital interface in cpol = 1, cpha = 1 or cpol = 0, cpha = 0 modes using sclk, din, and dout. cs sclk din dout 1 0 a4 a3 a2 a1 d7 d6 d5 d4 d3 d2 d1 d0 d8 d9 a0 x d15 d14 d13 d12 d11 d10 figure 11. serial interface 16-bit write timing diagram cs sclk din dout 1 0 a4 a3 a2 a1 d7 d6 d5 d4 d3 d2 d1 d0 a0 x figure 12. serial interface 8-bit write timing diagram cs sclk din dout 1 1 a4 a3 a2 a1 a0 x d7 d6 d5 d4 d3 d2 d1 d0 d8 d9 d15 d14 d13 d12 d11 d10 figure 13. serial interface 16-bit read timing diagram max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 25 figure 14. serial interface 8-bit read timing diagram cs sclk din dout 1 1 a4 a3 a2 a1 a0 x d7 d6 d5 d4 d3 d2 d1 d0 target register r/w access add4:add0 adc register r/w 00000 mux register r/w 00001 data register r 00010 offset register r/w 00011 dac1 register r/w 00100 dac2 register r/w 00101 status register r 00110 al_burst register r/w 01000 al_sec register r/w 01001 al_min register r/w 01010 al_hour register r/w 01011 al_day register r/w 01100 al_status register r 01101 al ar m /cl ock_c trl reg i ster r/w 01110 rtc_burst register r/w 01111 target register r/w access add4:add0 rtc_sec register r/w 10000 rtc_min register r/w 10001 rtc_hour register r/w 10010 rtc_date register r/w 10011 rtc_month register r/w 10100 rtc_day register r/w 10101 rtc_year register r/w 10110 rtc_century register r/w 10111 power1 register r/w 11000 power2 register r/w 11001 sleep register w 11010 standby register w 11011 idle register w 11100 run register w 11101 table 2. register summary and addressing table 3. command byte format command bit 7 (msb) bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0 (lsb) write 1 0 add4:add0 (see table 2) x read 1 1 add4:add0 (see table 2) x max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 26 ______________________________________________________________________________________ mode: conversion mode bit. a logic zero selects a normal adc conversion, while a logic 1 selects an offset calibration conversion. after completing a calibration conversion, mode automatically resets to zero. rate: conversion rate bit. a logic zero selects a 30hz conversion rate while a logic 1 selects a 60hz conver- sion rate. gain1, gain0: gain bits. the gain bits select the pga gain. for an adc gain of +1/3, +1, and 2v/v, [gain1 gain0] are 00, 01, and 10, respectively. bufp: positive buffer bit. when this bit is 0, the positive input buffer is bypassed and powered down. when this bit is 1 and the bufe bit in the power1 register is 1, the positive input buffer drives the adc input sampling capacitors. bufn: negative buffer bit. when this bit is 0, the nega- tive input buffer is bypassed and powered-down. when this bit is 1 and the bufe bit in the power1 register is 1, the negative input buffer drives the adc input sampling capacitors. bip: unipolar/bipolar bit. a logic zero selects unipolar mode while a logic 1 selects bipolar mode. sta1: start bit. setting sta1 to a logic 1 resets the reg- isters inside the adc filter, updates the adc configura- tion according to the adc register, and initiates an analog-to-digital conversion or offset calibration. the initial conversion requires three cycles for valid output data, and each subsequent conversion cycle will output valid data. after completing the intial conversion, sta1 automatically resets to 0; however, the adc will contin- ue to do conversions until it is powered down. writing to the adc register with sta1 set to 0 updates the adc register without changing the adc configura- tion and allows the adc to continue conversions unin- terrupted. this allows the adc and mux configuration to be updated simultaneously. see sta2 bit of the mux register. adc register (00000) first bit (msb) (lsb) name mode rate gain1 gain0 bufp bufn bip sta1 defaults 00000000 on-chip registers muxp2, muxp1, muxp0: positive multiplexer bits. muxp[2:0] direct one-of-eight positive inputs to the positive input of the adc. table 4 relates the muxp bits to the positive multiplexer inputs. muxn2, muxn1, muxn0: negative multiplexer bits. muxn[2:0] direct one-of-eight (one-of-four for the max1409) negative inputs to the negative input of the adc. table 5 relates the muxn bits to the negative multiplexer inputs. dbit: digital output bit. this bit controls the output state of d0. when the output buffer is enabled, d0 is low if dbit is equal to 0, and high if dbit is equal to 1. d0 is enabled by the d0e bit of the power2 register. sta2: start bit. setting sta2 to a logic 1 updates the mux selection, resets the registers inside the adc filter, updates the adc configuration according to the adc register, and initiates an analog-to-digital conversion. the initial conversion requires three cycles for valid out- put data, and each subsequent conversion cycle will output valid data. sta2 automatically resets to 0 after the initial conversion completes. the adc will continue to do conversions until it is powered down. writing to the mux register with the sta2 bit set to 0, updates the mux register and selection, but leaves the adc config- uration unchanged. the mux input can be switched with the adc continuously converting without the digital filter resetting. mux register (00001) first bit (msb) (lsb) name muxp2 muxp1 muxp0 muxn2 muxn1 muxn0 dbit sta2 defaults 00000000 max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 27 the data register contains the 16-bit result from the most recently completed adc conversion. the data for- mat is binary for unipolar mode and two � s complement for bipolar mode. after power-up, the data register contains all zeros. table 4. positive mux decoding positive mux input max1407/max1414 max1408 max1409 muxp2 muxp1 muxp0 av dd av dd av dd 000 ref ref ref 0 0 1 out1 in4 out1 0 1 0 in0 in0 in0 0 1 1 in1 in1 � 100 in2 in2 � 101 in3 in3 � 110 out2 in5 � 111 table 5. negative mux decoding negative mux input max1407/max1414 max1408 max1409 muxn2 muxn1 muxn0 agnd agnd agnd 0 0 0 ref ref ref 0 0 1 fb1 in6 fb1 0 1 0 in0 in0 in0 0 1 1 in1 in1 � 100 in2 in2 � 101 in3 in3 � 110 fb2 in7 � 111 data register?ead-only (00010) first bit (msb) adc15 adc14 adc13 adc12 adc11 adc10 adc9 adc8 adc7 adc6 adc5 adc4 adc3 adc2 adc1 adc0 (lsb) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 28 ______________________________________________________________________________________ the offset register contains the 16-bit result from the most recently completed adc offset calibration. the data format is two � s complement and is subtracted from the filter output before writing to the data register. after power-up, the offset register contains all zeros. each change in ambient operating condition (power supply and temperature), pga gain, bipolar/unipolar input range, buffered/unbuffered mode, or conversion speed requires an offset calibration. the offset for a given adc configuration can be read and stored by the p to avoid adc recalibration. when returning to an adc configuration where the offset was stored, write back the stored offset to the offset register. the stored offset stays valid as long as the ambient operating con- dition remains unchanged (within 20 � c). force sense dac registers (max1407/max1409/max1414 only) writing to the dac1 register updates the output of dac1. writing to the dac2 register updates the output of dac2. the dac data is 10-bit long and left justified. follow the timing diagrams of figure 11 and figure 13 to program these registers. writing a logic 0 to the da1e or da2e bit in the power2 register disables dac1 or dac2, respectively. at power-up, dac1 and dac2 are disabled. offset register (00011) first bit (msb) off15 off14 off13 off12 off11 off10 off9 off8 off7 off6 off5 off4 off3 off2 off1 off0 (lsb) dac2 register (00101) writing to the dac1 register will update the dac1 output (out1). the output voltage in a unity gain configuration is v ref x n/(2 10 ), where n is the integer value of dac1[9:0] (0 to 1023), and v ref is the reference voltage for the dac. the dac1 data is 10-bit long and left justified. after power-up, the dac1 register contains all zeros. first bit (msb) dac1[9] dac1[8] dac1[7] dac1[6] dac1[5] dac1[4] dac1[3] dac1[2] dac1[1] dac1[0] x xxxxx (lsb) dac1 register (00100) writing to the dac2 register will update the dac2 output (out2). the output voltage in a unity-gain configuration is v ref x n/(2 10 ), where n is the integer value of dac2[9:0] (0 to 1023), and v ref is the reference voltage for the dac. the dac2 data is 10-bit long and left justified. after power-up, the dac2 register contains all zeros. first bit (msb) dac2[9] dac2[8] dac2[7] dac2[6] dac2[5] dac2[4] dac2[3] dac2[2] dac2[1] dac2[0] x xxxxx (lsb) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 29 wu2: wake-up2 status bit. when wu2 is pulled low, wu2 is set to a logic 1. reading the status register clears wu2, unless wu2 is still low. when wu2 is pulled low when the device is awake (not in sleep mode), wu2 is cleared. wu1: wake-up1 status bit. when wu1 is pulled low, wu1 is set to a logic 1. reading the status register clears wu1, unless wu1 is still low. when wu1 is pulled low when the device is awake (not in sleep mode), wu1 is cleared. rst: reset status bit. when av dd drops below the reset voltage monitor trip threshold (+1.8v or +2.7v), rst is set to 1. this corresponds to the assertion of the reset pin. reading the status register clears rst, unless av dd is still below the reset voltage monitor trip threshold. at power-up, rst is at a logic 1 until the status register is read. lvd: low v dd status bit. when av dd drops below the low v dd voltage monitor trip threshold (+2.7v), lvd is set to a logic 1. reading the status register clears lvd unless av dd is still below 2.7v. at power-up, lvd is at a logic 1 until the status register is read. when the low v dd voltage monitor is powered down (lvde = 0), the lvd bit stays unchanged. sdc: signal-detect comparator status bit. sdc is set to � 1 � when the differential polarity voltage across the signal-detect comparator exceeds the signal-detect threshold (0mv for the max1407/max1408/max1409 and 50mv for the max1414). this corresponds to the assertion of the int pin. reading the status register clears sdc unless the condition remains true. sdc is also reset to 0 when the signal-detect comparator is powered down (sdce = 0). clk: fout clock enable status bit. clk is set to � 1 � after the fout clock pin has been enabled in t dfon milliseconds (see figure 15). reading the status register clears the clk bit. add: adc done status bit. add is set to � 1 � to indicate that the adc has completed either a normal conversion or a calibration conversion, and the conversion result is available to be read. this corresponds to the assertion of the drdy pin. reading either the data or offset register clears the add bit. reading the status register will not clear this bit. alarm registers the al_sec, al_min, al_hour, al_day registers are pro- grammed through the serial port to store the preset time data in binary-coded decimal format (bcd). see table 6 for decimal to bcd conversion. these registers can be accessed individually or consecutively using burst mode (see al_burst register section). to enable the alarm, set the ae bit of the alarm/clock_ctrl register to 1 (see alarm and rtc programming section). when an alarm occurs in any mode, the alirq bit of the al_status register will change from 0 to 1, and the int output will go low unless you are in sleep mode. if not already awake, the device will wake-up from sleep mode to standby mode and int goes low when the pll output is available. the crystal oscillator, rtc, wake-up circuitry, reset voltage monitor, low v dd voltage monitor (if applicable), and the pll are all powered up in standby mode. four alarm registers (al_sec, al_min, al_hour, and al_day) are used to store the preset time value for the alarm function. bit 7 of the al_sec, al_min, al_hour, al_day registers is the mask bit and is used to program how often the alarm occurs. table 7 shows how bit 7 of the four alarm registers should be set for the time of day alarm to occur. other combinations of mask bits are possible to set different alarms. first bit (msb) (lsb) name wu2 wu1 rst lvd sdc clk add � default 0 0 1 1 0 0 0 0 status register (00110) table 6. bcd conversion decimal digit bcd 0 0000 1 0001 2 0010 3 0011 4 0100 5 0101 6 0110 7 0111 8 1000 9 1001 unused codes 1010 1011 1100 1101 1110 1111 max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 30 ______________________________________________________________________________________ al_burst register (01000) writing to this register begins the alarm burst mode transfer. all the alarm clock registers are consecutively read from or written to starting with bit7 of the al_sec register followed by the al_min register, al_hour regis- ter, and finally the al_day register. table 7. common mask bits combinations alarm register mask bits (bit 7) al_sec al_min m_hour m_day function how often? 1 1 1 1 alarm occurs once per second once per second 0 1 1 1 alarm occurs when seconds match once per minute 001 1 alarm occurs when minutes and seconds match once per hour 000 1 alarm occurs when hours, minutes, and seconds match once per day 000 0 alarm occurs when day, hours, minutes, and seconds match once per week m_sec: alarm mask bit. a logic 1 masks out the sec- onds alarm comparator. 10sec[2:0]: these are the 10-second bits (0 � 50 sec- onds) of the alarm. sec[3:0]: these are the second bits (0 � 9 seconds) of the alarm. first bit (msb) (lsb) name m_sec 10sec2 10sec1 10sec0 sec3 sec2 sec1 sec0 default 0 0 000000 al_sec register (01001) m_min: alarm mask bit. a logic 1 masks out the minute alarm comparator. 10min[2:0]: these are the 10-minute bits (0 � 50 min- utes) of the alarm. min[3:0]: these are the minute bits (0 � 9 minutes) of the alarm. first bit (msb) (lsb) name m_min 10min2 10min1 10min0 min3 min2 min1 min0 default 0 0 000000 al_min register (01010) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 31 m_hr: alarm mask bit. a logic 1 masks out the hour alarm comparator. 12/24: 12/24-hour mode bit. a logic 1 selects 12-hour mode while a logic 0 selects 24-hour mode. this bit must be the same as the 12/24-bit of the rtc_hour register for correct operation. ap: am/pm bit. in 12-hour mode, a logic 1 indicates pm and a logic 0 indicates am. in 24-hour mode, this bit is the second 10-hour bit (20 hours). 10hr: this is the 10-hour bit (0 � 10 hours) of the alarm. hr[3:0]: these are the hour bits (0 � 9 hours) of the alarm. first bit (msb) (lsb) name m_hr 12/24 ap 10hr hr3 hr2 hr1 hr0 default 0 0 000000 al_hour register (01011) m_day: alarm mask bit. a logic 1 masks out the day alarm comparator. day[2:0]: these are the day of the week bits (sunday � saturday). the following table is the hex code for each day of the week. alirq: alarm interrupt request bit. a logic 1 indicates that the current time has matched the preset time in the alarm registers (this corresponds to the assertion of the int pin). alirq resets to 0 when any alarm register is read or written to. first bit (msb) (lsb) name m_day �� day2 day1 day0 default 0 0 0 0 0 0 0 1 al_day register (01100) al_day sun mon tue wed thu fri sat day[2:0] 1h 2h 3h 4h 5h 6h 7h first bit (msb) (lsb) name alirq � default 0 0 0 0 0 0 0 0 al_status register (01101) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 32 ______________________________________________________________________________________ we: write enable bit. we must be set to � 1 � before any write operation to the clock and the alarm register. a logic 0 disables write operations to the clock and alarm registers, including the ae bit. the we signal takes effect after the 8th sclk rising edge for an 8-bit write. ae: alarm enable bit. a logic 0 disables the alarm func- tion. when ae equals � 1 � , the alirq bit in the al_status register will be set to 1 whenever the current time matches that of the alarm registers. real-time clock (rtc) the rtc_sec, rtc_min, rtc_hour, rtc_date, rtc_month, rtc_day, rtc_year, and rtc_century registers can be accessed one register at a time or in burst mode (see rtc_burst register section). the rtc runs continuously and does not stop for read or write operations. to prevent the data from changing during a read operation, complete all read operations on the rtc registers (single register reads and burst reads) in less than 1ms. using single reads to read all the rtc registers could lead to errors as much as a century. since the registers are updated between read operations, the register con- tents may change before all rtc registers have been read, when reading one register at a time. the most accurate way to get the time information of the rtc registers is with a burst read. in the burst read, a snap- shot of the eight rtc registers (rtc_sec, rtc_min, rtc_hour, rtc_date, rtc_month, rtc_day, rtc_year, rtc_century) is taken once and read sequentially with the msb of the seconds register first. they must all be read out as a group of eight registers of eight bits each, for proper execution of the burst read function. the worst-case error that can occur between the � actual � time and the � reported � time is one second. as with a read operation, using single writes to update the rtc can lead to collisions. to guarantee an accurate update of the rtc, use the burst write mode (see alarm and rtc programming section). the rtc defaults to 24-hr mode, 00:00:00, sunday, january 01, 1970 during power-up. january 01, 1970 falls on a thursday, but since this rtc is not time- based, the default values do not have an impact on the functionality of the clock, and they merely provide some means for testing. if the alarm or rtc registers are pro- grammed to some unused states, the device chooses the default values. rtc_burst register (01111) writing to this address begins the burst mode transfer. in this mode, all the real-time clock registers are contin- uously read or written starting with bit 7 of the rtc_sec, rtc_min, rtc_hour, rtc_date, rtc_month, rtc_day, rtc_year, and rtc_century registers. when reading, the contents of din will be ignored and each register � s 8-bit data will be clocked out at dout on the falling edge of sclk (total of 64 clock cycles). when writing, start with the seconds � register msb first and continue through the century register (see alarm and rtc programming section). alarm/clock_ctrl register (01110) first bit (msb) (lsb) name we �� ae default 00000000 ch: clock halt bit. writing a � 1 � to ch disables the real-time clock and oscillator. 10sec[2:0]: these are the 10 second bits (10 � 50 sec- onds) of the rtc. sec[3:0]: these are the second bits (0 � 9 seconds) of the rtc. first bit (msb) (lsb) name ch 10sec2 10sec1 10sec0 sec3 sec2 sec1 sec0 default 0 0 0 0 0 0 0 0 rtc_sec register (10000) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 33 10min[2:0]: these are the 10 minute bits (0 � 50 min- utes) of the rtc. min[3:0]: these are the minute bits (0 � 9 minutes) of the rtc. 12/24: 12/24-hour mode bit. a logic 1 selects 12-hour mode while a logic 0 selects 24-hour mode. this bit must be the same as the 12-/24-bit of the al_hour reg- ister for correct operation. ap: am/pm-bit. in 12-hour mode, a logic 1 indicates pm and a logic 0 indicates am. in 24 hour mode, this bit is the second 10-hour bit (20 hours). 10hr: this is the 10-hour bit (0 � 10 hours) of the rtc. hr[3:0]: these are the hour bits (0 � 9 hours) of the rtc. rtc_min register (10001) first bit (msb) (lsb) name � 10min2 10min1 10min0 min3 min2 min1 min0 default 0 0 0 0 0 0 0 0 first bit (msb) (lsb) name � 12/24 ap 10hr hr3 hr2 hr1 hr0 default 0 0 000000 rtc_hour register (10010) 10date[1:0]: these are the 10 day bits (0 � 30 days) of the rtc. date[3:0]: these are the day bits (0 � 9 days) of the rtc. first bit (msb) (lsb) name 10date1 10date0 date3 date2 date1 date0 default 0 0 0 0 0 0 0 1 10mo: this is the 10 month bit (0 � 10 months) of the rtc. first bit (msb) (lsb) name � 10mo mo3 mo2 mo1 mo0 default 0 0 0 0 0 0 0 1 rtc_month register (10100) rtc_date register (10011) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 34 ______________________________________________________________________________________ 10mo: this is the 10 month bit (10 � 12 months) mo[3:0]: these are the month bits (0 � 9 months) for the rtc. the following table is the hex code for the twelve months of the year. mill[3:0]: these are the millennium bits (0000 � 9000 years) of the rtc. cent[3:0]: these are the century bits (000 � 900 years) of the rtc. day[2:0]: these bits select the day of the week (sunday � saturday). the following table is the hex code for day of the week. 10year[3:0]: these are the 10 year bits (0 � 90 years) of the rtc. year[3:0]: these are the year bits (0 � 9 years) of the rtc. al_day sun mon tue wed thu fri sat day[2:0] 1h 2h 3h 4h 5h 6h 7h first bit (msb) (lsb) name ��� day2 day1 day0 default 0 0 0 0 0 0 0 1 rtc_day register (10101) first bit (msb) (lsb) name 10year3 10year2 10year1 10year0 year3 year2 year1 year0 default 01110000 rtc_year register (10110) first bit (msb) (lsb) name mill3 mill2 mill1 mill0 cent3 cent2 cent1 cent0 default 0 0 0 1 1 0 0 1 rtc_century register (10111) month jan feb mar apr may jun 10mo mo[3:0] 01h 02h 03h 04h 05h 06h month jul aug sep oct nov dec 10mo mo[3:0] 07h 08h 09h 10h 11h 12h max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 35 refe: internal reference power enable. when refe is set to 1, the internal reference is powered up. when refe is set to 0, the internal reference is powered down allowing an external reference to be connected to ref. adce: adc power enable. when adce is set to 1, the adc is powered up. when adce is set to 0, the adc is powered down. bufe: adc input buffer power enable. a logic 1 enables the power-up of the adc input buffers, while a logic 0 powers-down the buffers. muxe: multiplexer enable. a logic 0 disables the multi- plexer outputs while a logic 1 enables them. power-control registers table 8 shows the bit values of some key registers in different power modes under various conditions. use this as a quick reference when programming the max1407/max1408/max1409/max1414 family. table 8. related bit values during specified mode circuit block bit initial power-up sleep standby idle run wake-up event 32khz oscillator ch 0 (oscillator is on) n/a n/a n/a n/a n/a rtc ch 0 (rtc is on) n/a n/a n/a n/a n/a low v dd voltage monitor (2.7v) lvde 1 (2.7v monitor is on) 1 if vm = 0 0 if vm = 1 111 1 reset voltage monitor (1.8v) lsde 0 (1.8v monitor is off) 0 if vm = 0 1 if vm = 1 0 if vm = 0 1 if vm = 1 0 if vm = 0 1 if vm = 1 0 if vm = 0 1 if vm = 1 n/a reset bit rst 1 ( reset asserted) n/a n/a n/a n/a n/a low v dd status bit lvd 1 (low v dd ) n/a n/a n/a n/a n/a voltage-monitor threshold selection vm 0 (select 2.7v) n/a n/a n/a n/a n/a bias circuit biase biase = 1 (biase circuit is on) 0111 1 pll plle 1 (pll is on) 0 1 1 1 1 pll output plle 1 (fout is enabled) 0 1 1 1 1 shdn output shde 1 ( s hd n p i n = hi g h) 0111 1 dac1 da1e 0 0 0 1 1 n/a dac2 da2e 0 0 0 1 1 n/a adc mux mux 0 0 0 1 1 n/a bandgap reference refe 0 0 0 1 1 n/a signal-detect comparator sdce 0 0 0 1 1 n/a adc buffers bufe 0 0 0 0 1 n/a adc adc 0 0 0 0 1 n/a n/a: programming the part into these modes would not alter the content of the corresponding bit. power1 register (11000) first bit (msb) (lsb) name refe adce bufe muxe da1e da2e default 00000000 max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 36 ______________________________________________________________________________________ power2 register (11001) da1e: dac1 power enable. a logic 1 powers dac1, while a logic 0 powers it down. the output buffer goes high impedance in power-down mode. da2e: dac2 power enable. a logic 1 powers dac2, while a logic 0 powers it down. the output buffer goes high impedance in power-down mode. shde: shutdown enable bar. if shde is set to 1, shdn is pulled high. a wake-up event such as an assertion of wu1 or wu2 , a time-of-day alarm, or by writing to the power1, power2, standby, idle, or run registers sets this bit to 1 and drives shdn high. if the shde bit is set to 0 in standby, idle, or run mode and the pll is still operational (plle = 1), the shdn pin will remain high until 2.93ms (t dpd ) after plle is set to 0. plle: phase-locked loop power enable. a logic 1 powers the pll and enables fout while a logic 0 pow- ers down the pll and disables fout. a wake-up event sets this bit to 1. see wake-up section. lvde: +2.7v voltage monitor power enable. a logic 1 powers the +2.7v voltage comparator circuitry, while a logic 0 powers down the +2.7v voltage comparator cir- cuitry. a wake-up event sets lvde to 1. see wake-up section. lsde: +1.8v voltage monitor power enable. a logic 1 powers the +1.8v voltage comparator circuitry, while a logic 0 powers down the +1.8v voltage comparator cir- cuitry. see wake-up section. sdce: signal-detect comparator power enable. a logic 1 powers the signal-detect comparator while a logic 0 powers down this comparator. d0e: d0 enable bit. a logic 0 three-states the d0 ouput. when d0e is set to � 1 � , the output of d0 is con- tolled by the state of dbit in the mux register. programming the device in different modes does not alter the state of this bit. vm: reset voltage monitor threshold selection bit. a logic 0 selects a +2.7v threshold while a logic 1 selects a +1.8v threshold for the reset voltage monitor. the vm bit effects the lvde and lsde bits in different modes of operation (see table 8). biase: bias enable. a logic 1 powers up the master bias circuit block. a wake-up event sets this bit to a logic 1. see wake-up section. sleep register (11010) addressing the sleep register places the max1407/ max1408/max1409/max1414 in sleep mode. this occurs after the last bit of the command byte is clocked into the device. it requires an 8-bit write, no data bits are needed. sleep mode powers down all functional blocks except for the crystal oscillator, rtc, alarm, ser- ial interface, wake-up circuitry, and reset voltage monitor. while in sleep mode, pulling either wu1 or wu2 low or an alarm event places the device into standby mode. standby register (11011) addressing the standby register places the max1407/ max1408/max1409/max1414 in standby mode. this occurs after the last bit of the address byte is clocked into the device. it requires an 8-bit write, no data bits are needed. standby mode powers up the same blocks as sleep mode, as well as the master bias circuitry, the pll, and the low v dd voltage monitor. fout is also enabled and shdn is set high in standby mode. idle register (11100) addressing the idle register places the max1407/ max1408/max1409/max1414 in idle mode. this occurs after the last bit of the address byte is clocked into the device. requires an 8-bit write, no data bits are needed. in idle mode, all circuits are powered up with the exception of the adc and the adc input buffers. run register (11101) addressing the run register puts the max1407/ max1408/max1409/max1414 into run mode. this occurs after the last bit of the address byte is clocked into the device. requires an 8-bit write, no data bits are needed. all the functional blocks are powered up in run mode. first bit (msb) (lsb) name shde plle lvde lsde sdce d0e vm biase default 11100001 max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 37 applications information alarm and rtc programming three write operations are needed for every update of the alarm and rtc registers. first set the we bit of the alarm/clock_ctrl register to 1. update the alarm, rtc, and alarm/clock_ctrl register with the new val- ues, and then set the we bit back to 0. this will avoid collisions in setting the time. power-on reset or power-up at initial power-up, the max1407/max1408/max1409/ max1414 are in standby mode. figure 15 illustrates the timing of various signals during initial power-up, sleep mode, and wake-up. t dslp after av dd exceeds +2.7v, reset goes high. t dfon after reset goes high, fout is enabled. int is enabled to t dfi after fout is enabled. power modes the max1407/max1408/max1409/max1414 have fou distinct power modes, sleep mode, standby mode, idle mode, and run mode. table 9 lists the power-on status of the various blocks of the max1407/max1408/ max1409/max1414. each individual circuit block can be powered up through the serial interface by writing to the appropriate power registers. sleep mode in sleep mode, only the crystal oscillator, rtc, data registers, wake-up circuitry, and reset voltage monitor are powered up. sleep mode is entered by addressing the sleep register through the serial inter- face. sleep mode preserves any data in the data regis- ters. to exit sleep mode, pull either wu1 or wu2 low or address other power mode registers (standby, idle, run, power1, or power2 registers). asserting wu1 or wu2 or the occurence of a time of day alarm while in sleep mode places the device in standby mode. standby mode after initial power-up or after exiting sleep mode through a wake-up event, the max1407/max1408/ max1409/max1414 are in standby mode. standby mode can also be entered by addressing the standby register. in standby mode, shdn is high, fout is enabled, the low v dd voltage monitor and the pll are powered up, and int is low. int will return to a logic high after the p begins writing to any register through the serial interface (once a start bit is detected through the serial interface). idle mode in idle mode, only the adc and adc input buffers are shutdown. all the other blocks are powered up. enter idle mode by addressing the idle register. run mode in run mode, all the functional blocks are powered up and the adc is ready to start conversion. enter run mode by either writing to the run register or by individu- ally powering up each circuit through the serial interface. wake-up wake-up mode is entered whenever a wake-up event, such as an assertion of wu1 or wu2 or a time-of-day alarm occurs. the low v dd monitor, pll, fout are enabled, and shdn goes high. different from the standby mode, the status of the other power blocks remains unchanged. analog filtering the digital filter does not provide any rejection close to the harmonics of the modulator sample frequency. however, due to the high oversampling ratio of the max1407/max1408/max1409/max1414, these bands occupy only a small fraction of the spectrum and most broadband noise is filtered. therefore, the analog filter- ing requirements in front of the max1407/max1408/ max1409/max1414 are considerably reduced com- pared to a conventional converter with no on-chip filter- ing. in addition, because the part � s common-mode rejection of 90db extends out to several khz, common- mode noise susceptibility in this frequency range is substantially reduced. depending on the application, it may be necessary to provide filtering prior to the max1407/max1408/ max1409/max1414 to eliminate unwanted frequencies the digital filter does not reject. it may also be necessary in some applications to provide additional filtering to ensure that differential noise signals outside the frequen- cy band of interest do not saturate the analog modulator. if passive components are placed in front of the max1407/max1408/max1409/max1414 when the part is used in unbuffered mode, ensure that the source impedance is low enough not to introduce gain errors in the system. this can significantly limit the amount of passive anti-aliasing filtering that can be applied in front of the max1407/max1408/max1409/max1414 in unbuffered mode. however, when the part is used in buffered mode, large source impedances will simply result in a small dc offset error (a 1k ? source resis- tance will cause an offset error of less than 0.5v). therefore, where significant source impedances are required, operate the device in buffered mode. max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 38 ______________________________________________________________________________________ dynamic input impedance when designing with the max1407/max1408/ max1409/max1414, as with any other switched-capac- itor adc input, consider the advantages and disadvan- tages of series input resistance. a series resistor reduces the transient current impulse to the external driving amplifier. this improves the amplifier phase margin and reduces the possibility of ringing. the resis- figure 15. initial power-up, sleep mode, and wake-up timing diagram with av dd >2.7v t dfon sleep write three-stated t dfi t dfof t wu t dpu t dfon t dfi t dpd 0v 1 2 3 av dd t dslp reset (open-drain) lo hi 32khz clock lo hi wu1,wu2 (int. pullup) lo hi cs lo hi drdy lo hi 4 2.7v shdn lo hi dout lo hi fout (2.4576mhz) lo hi sclk, din lo hi int lo hi initial power-up sleep mode wake-up max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 39 tor spreads the transient-load current from the sampler over time due to the rc time constant of the circuit. however, an improperly chosen series resistance can hinder performance in high-resolution converters. the settling time of the rc network can limit the speed at which the converter can operate properly, or reduce the settling accuracy of the sampler. in practice, this means ensuring that the rc time constant, resulting from the product of the driving source impedance and the capacitance presented by both the device � s input and any external capacitance is sufficiently small to allow settling to the desired accuracy. table 10 sum- marizes the maximum allowable series resistance vs. external shunt capacitance for each different gain set- ting in order to ensure 16-bit performance in unbuffered mode (for 60sps conversion rate). performing a conversion or offset- calibration with the adc upon power-up, the max1407/max1408/max1409/ max1414 are in standby mode. at this point, the adc register default settings are set for a normal adc conver- sion (mode = 0), conversion rate of 30hz (rate = 0), gain of 1/3 v/v (gain [00]), input buffers bypassed and powered down (bufp = bufn = 0), and unipolar mode table 9. power states of individual blocks at different modes of operation power modes circuit blocks sleep standby idle run wa k e- u p even t serial interface xxxx x wake-up circuitry xxxx x crystal oscillator xxxx x rtc with alarm xxxx x reset voltage monitor xxxx x low v dd voltage monitor � xxx x master bias circuit � xxx x pll � xxx x fout � xxx x shdn = high � xxx x dac1 x x n/a dac2 x x n/a bandgap x x n/a bandgap buffer x x n/a signal detect comparator x x n/a adc multiplexer x x n/a adc input buffers � x n/a adc � x n/a x = powered-up n/a = programming the parts into the wake-up mode would not alter the content of these blocks table 10. rext, cext values for less than 16-bit gain error in unbuffered mode external resistance r ext (k ? ) pga gain (v/v) c ext = 0pf c ext = 50pf c ext = 100pf c ext = 200pf c ext = 500pf 1 194 56 33 19 9 2 100 30 16 9 4.5 max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 40 ______________________________________________________________________________________ (bip = 0). to initiate an adc conversion: 1) enter run mode by addressing the run register 2) select the desired channels for conversion by writing to the mux register, (e.g., 94h selects in1 for the positive channel and in2 for the negative channel) 3) initiate the conver- sion by writing to the adc register, (e.g., 01h). the first conversion result becomes available in 100ms. the adc will keep doing conversions at a rate of 30hz until pow- ered down. to perform an on-chip offset calibration on a specific configuration, write to the adc register with the mode bit and sta1 bit set to 1. the adc will do one calibra- tion using the inputs to the adc specified in the mux register and then stop. the calibration result will be stored in the offset register in two � s complement form. subsequent adc conversion results will have the offset value subtracted before written to the data register. the mode bit will be reset to 0 automatically upon completion of the calibration. the adc is now ready for a normal conversion. the offset for a given adc configuration can be stored by the p to avoid another adc recalibration. write the stored offset back to the offset register when returning back to that particular adc configuration where the cal- ibration was taken. subsequent adc conversion results will have the offset value subtracted before they are written to the data register. dac unipolar output for a unipolar output, the output voltages and the refer- ence have the same polarity. figure 16 shows the max1407/max1409/max1414s � unipolar output circuit, which is also the typical operating circuit for the dacs. table 11 lists some unipolar input codes and their cor- responding output voltages. for larger output swing see figure 17. this circuit shows the output amplifiers configured with a closed- loop gain of +2v/v to provide 0 to 2.5v full-scale range with the 1.25v reference. dac bipolar output the max1407/max1409/max1414 dac outputs can be configured for bipolar operation using the application circuit on figure 18: figure 16. unipolar output circuit max1407/max1409/max1414 the max1409 has one dac v ref = 1.25v fb1 ref fb2 out1 out2 agnd dgnd dac 1 dac 2 figure 17. unipolar rail-to-rail output circuit max1407/max1409/max1414 the max1409 has one dac v ref = 1.25v fb1 10k ? 10k ? ref fb2 out1 out2 agnd dgnd dac 1 10k ? 10k ? dac 2 figure 18. bipolar output circuit max1407/max1409/max1414 +5v -5v fb_ r1 r2 r2 = r1 ref out_ dac_ v out max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 41 table 11. unipolar code table dac contents msb lsb analog output 1111 1111 11 +v ref (1023/1024) 1000 0000 01 +v ref (513/1024) 1000 0000 00 +v ref (512/1024) = +v ref /2 0111 1111 11 +v ref (511/1024) 0000 0000 01 +v ref (1/1024) 0000 0000 00 0 table 12. bipolar code table dac contents msb lsb analog output 1111 1111 11 +v ref (511/512) 1000 0000 01 +v ref (1/512) 1000 0000 00 0 0111 1111 11 -v ref (1/512) 0000 0000 01 -v ref (511/512) 0000 0000 00 -v ref (512/512) = -v ref figure 19. power-supply circuit using max1833 step-up dc-dc converter max1407 max1408 max1414 max1833 lx in0 10 f 10 f 10 h v dd = 3.3v or v bat 0.1 f 0.1 f 0.1 f 18nf reset reset p/ c v bat batt e1* out rst shdn gnd cpll agnd dgnd av dd dv dd v dd v ss shdn *one li+ coin, two alkaline, or two button cells input wu1 figure 20. power-supply circuit using max1759 buck-boost dc-dc converter max1407 max1408 max1414 max1759 in in0 10 f 10 f 0.33 f v dd = 3.3v 0.1 f 0.1 f 0.1 f 18nf reset reset p/ c v bat e1* out pok shdn gnd fb pgnd cxn cxp cpll agnd dgnd av dd dv dd v dd v ss shdn *one li+ coin, one li+, 2-3 alkaline, 2-3 nimh, or 2-3 button cells input wu1 r r max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 42 ______________________________________________________________________________________ where nb is the decimal value of the dac � s binary input code. table 12 shows digital codes (offset binary) and corresponding output voltages for figure 18 assuming r1 = r2. power supplies power to the max1407/max1408/max1409/max1414 family can be supplied in a number of ways. figures 19, 20, 21, and 22 are power-supply circuits using a step-up converter, buck-boost converter, step-down converter, and a direct battery, respectively. choose the correct power-supply circuit for your specific application. connect the max1407/max1408/max1409/max1414 av dd and dv dd power supplies together. while the latch-up performance of the max1407/max1408/ max1409/max1414 is adequate, it is important that power is applied to the device before the analog input signals (in_) to avoid latch-up. if this is not possible, limit the current flow into any of these pins to 50ma. electrochemical sensor operation the max1407/max1408/max1409/max1414 family inter- face with electrochemical sensors. the 10-bit dacs with the force/sense buffers have the flexibility to connect to many different types of sensors. figure 23 shows how to interface with a two electrode potentiostat. a single dac is required to set the bias across the sensor relative to ground and an external precision resistor completes the transimpedance amplifier configuration to convert the current generated by the sensor to a voltage to be mea- sured by the adc. the induced error from this source is negligible due to fb1 � s extremely low input bias current. internally, the adc can differentially measure directly across the external transimpedance resistor, r f , eliminat- ing any errors due to voltages drifting over time, tempera- ture, or supply voltage. figure 24 shows a two electrode potentiostat application that is driven at the working elec- trode and measured at the counter electrode. with this application, the dac connected to the working electrode is configured in unity gain and the dac connected to the vv out ref = ? ? ? ? ? ? ? ? ? ? ? ? ? 2 1024 1 nb figure 21. power-supply circuit using max640 step-down dc-dc converter max1407 max1408 max1409 max1414 max640 v+ d1 in0 reset reset p/ c wu1 input 100 f 0.1 f 0.1 f 0.1 f r 33 f *one transistor (9v), one j cell (6v), or four alkaline cells e1* v bat v dd (+3.3v) 100 h 2r shdn lx vout vfb lbi gnd cpll agnd dgnd 18nf av dd dv dd v dd v ss figure 22. power-supply circuit using direct battery connection max1407 max1408 max1409 max1414 reset reset p/ c wu1 input 10 f 0.1 f 0.1 f 0.1 f *one li+ coin or two button cells e1* cpll agnd dgnd 18nf av dd v bat dv dd v dd v ss max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 43 counter electrode is configured as a transimpedance amplifier to measure the current. figure 25 shows a three electrode potentiostat application that is driven at all the electrodes and measured at the working electrode. with this application, the dac connected to the working elec- trode sets the bias voltage relative to the reference elec- trode and also measures the current that the sensor pro- duces. the dac connected to the reference and counter electrodes takes advantage of the force/sense outputs to figure 23. self-biased two electrode potentiostat application max1407 max1409 max1414 in0 aux. voltage inputs ref in1 in2 in3 all i/o available as inputs to adc and comparator. max1409 has in0, out1, fb1, and ref only. band gap fb1 ref out1 i f r f sensor we ce 4.7 f buf 10-bit dac figure 24. driven two electrode potentiostat application max1407 max1414 in0 aux. voltage inputs ref in1 in2 in3 all i/o available as inputs to adc and comparator. band gap fb1 fb2 ref ref out1 out2 i f r f sensor we ce 4.7 f buf 10-bit dac 10-bit dac figure 25. driven three electrode potentiostat application max1407 max1414 in0 aux. voltage inputs ref in1 in2 in3 all i/o available as inputs to adc and comparator. band gap fb1 fb2 ref ref out1 out2 i f r f sensor we ce re 4.7 f buf 10-bit dac 10-bit dac figure 26. optical reflectometry application max1407 max1414 in0 aux. voltage inputs ref in1 in2 in3 all i/o available as inputs to adc and comparator. band gap fb1 fb2 ref ref out1 led qb photo- diode v bat out2 r b 4.7 f buf 10-bit dac 10-bit dac i f r f max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 44 ______________________________________________________________________________________ maintain the reference electrode bias voltage by virtue of the feedback path through the sensor. optical reflectometry figure 26 illustrates the max1407/max1414 in an optical reflectometry application. the first dac is used with an external transistor to set the bias current through the led and the second dac is used to properly bias and convert the photodiode current to a voltage measured by the adc. the low input bias current into the dac feedback pin (fb2) allows the measurement of very small currents. the dacs provide the flexibility in setting an accurate and stable led current and adjusting the bias across the photodiode. set the led bias current externally if the max1409 is used in this application. thermistor measurement a thermistor connected in a half-bridge configuration as shown in figure 27 is used to measure temperatures very accurately with the max1407/max1408/ max1409/max1414. the internal reference drives the thermistor as well as the adc, so the reference varia- tion is cancelled out when calculating the temperature. the only significant errors are from the r l resistor and the thermistor itself. the adc performs a unipolar con- version with the pga set to a gain of 1v/v. figure 27. thermistor application circuit max1407 max1408 max1409 max1414 ref drdy not available on the max1409 band gap wake-up interrupt generator ref drdy int r l r t agnd 4.7 f buf 8:1 mux 16b adc cmp ref in0 8:1 mux figure 28. thermocouple application circuit max1407 max1408 max1414 ref c c band gap wake-up interrupt generator ref drdy int r r 4.7 f buf 8:1 mux 16b adc cmp agnd thermocouple junction in1 in0 in2 8:1 mux cjc max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 45 thermocouple measurement figure 28 shows a thermocouple connected to the dif- ferential inputs of the max1407/max1408/max1409/ max1414. in this application, the internal buffers are enabled to allow for the decoupling shown at the input. the decoupling eliminates noise pickup from the ther- mocouple. with the internal buffers enabled, the input common-mode range is reduced so the in2 input is biased to the internal reference voltage at +1.25v. when the buffer is enabled, the in1 input is limited to +1.4v. strain-gauge operation connect the differential inputs of the max1407/ max1408/max1409/max1414 to the bridge network of the strain gauge as shown in figure 29. when connect- ed to the internal reference, the adc can resolve below 10v at the differential inputs. the internal buffers pro- vide a high input impedance as long as the signal is within the reduced common-mode range of the input buffers. the bridge may also be driven directly from the supply voltage. in this configuration, the adc first mea- sures the supply voltage and then the differential input in sequence, and then calculates the ratio. grounding and layout for best performance, use printed circuit boards with separate analog and digital ground planes. the device perfomance will be highly degraded when using wire- wrap boards. design the printed circuit board so that the analog and digital sections are separated and confined to different areas of the board. join the digital and analog ground planes at one point. if the max1407/max1408/ max1409/max1414 is the only device requiring an agnd to dgnd connection, then the ground planes should be connected at the agnd pin of the max1407/ max1408/max1409/max1414. in systems where multi- ple devices require agnd to dgnd connections, the connection should still be made at only one point. make the star ground as close to the max1407/max1408/ max1409/max1414 as possible. avoid running digital lines under the device because these may couple noise onto the die. run the analog ground plane under the max1407/max1408/ max1409/max1414 to minimize coupling of digital noise. make the power-supply lines to the max1407/ max1408/max1409/max1414 as wide as possible to provide low-impedance paths and reduce the effects of glitches on the power-supply line. shield fast switching signals such as clocks with digital ground to avoid radiating noise to other sections of the board. avoid running clock signals near the analog inputs. avoid crossover of digital and analog signals. traces on opposite sides of the board should run at right angles to each other. this will reduce the effects of feedthrough on the board. a microstrip technique is best, but is not always possible with double-sided boards. in this technique, the component side of the board is dedicated to ground planes while signals are placed on the solder side. good coupling is important when using high-resolution adcs. decouple all analog supplies with 1f capaci- tors in parallel with 0.1f hf ceramic capacitors to agnd. place these components as close to the device as possible to achieve the best decoupling. crystal layout since it is possible for noise to be coupled onto the crystal pins, care must be taken when placing the external crystal on a pc board layout. it is very impor- tant to follow a few basic layout guidelines concerning figure 29. strain-gauge application circuit max1407 max1408 max1414 ref drdy not available on the max1409 band gap wake-up interrupt generator ref drdy int in1 4.7 f buf 8:1 mux 16-bit adc cmp ref or av dd in0 8:1 mux r a r b r d r c max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 46 ______________________________________________________________________________________ the placement of the crystal on the pc board layout to insure that extra clock � ticks � do not couple onto the crystal pins. 1) it is important to place the crystal as close as possi- ble to the clkin and clkout pins. keeping the trace lengths between the crystal and pins as small as possible reduces the probability of noise cou- pling by reducing the length of the � antennae � . keeping the trace lengths small also decreases the amount of stray capacitance. 2) keep the crystal bond pads and trace width to the clkin and clkout pins as small as possible. the larger these bond pads and traces are, the more likely it is that noise can couple from adjacent signals. 3) if possible, place a guard ring (connect to ground) around the crystal. this helps to isolate the crystal from noise coupled from adjacent signals. 4) insure that no signals on other pc board layers run directly below the crystal or below the traces to the clkin and clkout pins. the more the crystal is isolated from other signals on the board, the less likely it is that noise will be coupled into the crystal. there should be a minimum of 0.200 inches between any digital signal and any trace connected to clkin or clkout. 5) it may also be helpful to place a local ground plane on the pc board layer immediately below the crystal guard ring. this helps to isolate the crystal from noise coupling from signals on other pc board lay- ers. note: the ground plane needs to be in the vicinity of the crystal only and not on the entire board. definitions integral nonlinearity integral nonlinearity (inl) is the deviation of the values on an actual transfer function (with offset and gain error removed) from a straight line. this straight line can be either a best straight-line fit or a line drawn between the endpoints of the transfer function, once offset and gain errors have been nullified. the static linearity parame- ters for the max1407/max1408/max1409/max1414 are measured using the endpoint method. differential nonlinearity differential nonlinearity (dnl) is the difference between an actual step width and the ideal value of 1lsb. a dnl error specification of less than 1lsb guarantees no missing codes and a monotonic transfer function. top view cs wu2 reset wu1 int 20 19 18 17 16 15 14 13 1 2 3 4 5 6 7 8 dv dd dgnd sclk ref in0 out1 fb1 din dout clkin cpll av dd agnd 12 11 9 10 clkout fout max1409 28 27 26 25 24 23 22 21 20 19 18 17 16 15 1 2 3 4 5 6 7 8 9 10 11 12 13 14 in5 in3 dv dd dgnd sclk din dout clkin clkout fout in2 in1 cpll av dd agnd ref in0 in4 in6 do in7 max1408 cs wu2 reset wu1 int drdy shdn pin configurations (continued) max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc ______________________________________________________________________________________ 47 max1407 max1414 dc-dc converter lx in0 ref in1 fb1 fb2 out2 out1 reset clkin clkout fout cs sclk din dout int drdy reset clkin output sck mosi miso input input p / c wu2 i/o v bat batt out rst shdn sensor we ce re gnd cpll agnd dgnd av dd dv dd v dd v ss shdn wu1 i/o typical operating circuit max1407/max1408/max1409/max1414 low-power, 16-bit multichannel das with internal reference,10-bit dacs, and rtc 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. 48 ____________________maxim integrated products, 120 san gabriel drive, sunnyvale, ca 94086 408-737-7600 ? 2001 maxim integrated products printed usa is a registered trademark of maxim integrated products. package information ssop.eps |
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