|
If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
Datasheet File OCR Text: |
ltc1096/ltc1096l ltc1098/ltc1098l 1 10968fc typical application description micropower sampling 8-bit serial i/o a/d converters the ltc ? 1096/ltc1096l/ltc1098/ltc1098l are micropower, 8-bit a/d converters that draw only 80a of supply current when converting. they automatically power down to 1na typical supply current whenever they are not performing conversions. they are packaged in 8-pin so packages and have both 3v (l) and 5v versions. these 8-bit, switched-capacitor, successive approximation adcs include sample-and-hold. the ltc1096/ltc1096l have a single differential analog input. the ltc1098/ltc1098l offer a software selectable 2-channel mux. on-chip serial ports allow ef? cient data transfer to a wide range of microprocessors and microcontrollers over three wires. this, coupled with micropower consumption, makes remote location possible and facilitates transmitting data through isolation barriers. these circuits can be used in ratiometric applications or with an external reference. the high impedance analog inputs and the ability to operate with reduced spans (be- low 1v full scale) allow direct connection to sensors and transducers in many applications, eliminating the need for gain stages. l , lt, ltc and ltm are registered trademarks of linear technology corporation. all other trademarks are the property of their respective owners. features applications n 80a maximum supply current n 1na typical supply current in shutdown n 5v operation (ltc1096/ltc1098) n 3v operation (ltc1096l/ltc1098l)(2.65v min) n sample-and-hold n 16s conversion time n 33khz sample rate n 0.5lsb total unadjusted error over temp n direct 3-wire interface to most mpu serial ports and all mpu parallel i/o ports n 8-pin so plastic package n battery-operated systems n remote data acquisition n battery monitoring n battery gas gauges n temperature measurement n isolated data acquisition supply current vs sample rate 10w, s8 package, 8-bit a/d samples at 200hz and runs off a 5v battery 5v 1f analog input 0v to 5v range Cingnd v cc clk d out v ref ltc1096 mpu (e.g., 8051) p1.4p1.3 p1.2 +in 10968 ta01 cs / shutdown sample frequency, f smpl (khz) 0.1 1 supply current, i cc (a) 10 100 1000 1 10 100 10968 ta02 t a = 25c v cc = v ref = 5v downloaded from: http:///
ltc1096/ltc1096l ltc1098/ltc1098l 2 10968fc absolute maximum ratings (notes 1 and 2) ltc1096 ltc1098 12 3 4 87 6 5 top view +inCin gnd v cc clkd out v ref n8 package 8-lead plastic dip cs / shutdown s8 package 8-lead plastic soic t jmax = 150c, ja = 130c/w (n8) t jmax = 150c, ja = 175c/w (s8) 12 3 4 87 6 5 top view ch0ch1 gnd v cc (v ref) clkd out d in n8 package 8-lead plastic dip cs / shutdown s8 package 8-lead plastic soic t jmax = 150c, ja = 130c/w (n8) t jmax = 150c, ja = 175c/w (s8) pin configuration order information lead free finish tape and reel part marking* package description temperature range ltc1096acn8#pbf ltc1096acn8#trpbf ltc1096acn8 8-lead plastic dip 0c to 70c ltc1096acs8#pbf ltc1096acs8#trpbf 1096a 8-lead plastic soic 0c to 70c ltc1096ain8#pbf ltc1096ain8#trpbf ltc1096ain8 8-lead plastic dip C40c to 85c ltc1096ais8#pbf ltc1096ais8#trpbf 1096ai 8-lead plastic soic C40c to 85c ltc1096cn8#pbf ltc1096cn8#trpbf ltc1096cn8 8-lead plastic dip 0c to 70c ltc1096cs8#pbf ltc1096cs8#trpbf 1096 8-lead plastic soic 0c to 70c ltc1096in8#pbf ltc1096in8#trpbf ltc1096in8 8-lead plastic dip C40c to 85c ltc1096is8#pbf ltc1096is8#trpbf 1096i 8-lead plastic soic C40c to 85c ltc1096lcs8#pbf ltc1096lcs8#trpbf 1096l 8-lead plastic soic 0c to 70c ltc1096lis8#pbf ltc1096lis8#trpbf 1096li 8-lead plastic soic C40c to 85c ltc1098acn8#pbf ltc1098acn8#trpbf ltc1098acn8 8-lead plastic dip 0c to 70c ltc1098acs8#pbf ltc1098acs8#trpbf 1098a 8-lead plastic soic 0c to 70c ltc1098cn8#pbf ltc1098cn8#trpbf ltc1098cn8 8-lead plastic dip 0c to 70c ltc1098cs8#pbf ltc1098cs8#trpbf 1098 8-lead plastic soic 0c to 70c ltc1098in8#pbf ltc1098in8#trpbf ltc1098in8 8-lead plastic dip C40c to 85c ltc1098is8#pbf ltc1098is8#trpbf 1098i 8-lead plastic soic C40c to 85c ltc1098lcs8#pbf ltc1098lcs8#trpbf 1098l 8-lead plastic soic 0c to 70c ltc1098lis8#pbf ltc1098lis8#trpbf 1098li 8-lead plastic soic C40c to 85c operating temperature ltc1096ac/ltc1096c/ltc1096lc/ ltc1098ac/ltc1098c/ltc1098lc .......... 0c to 70c ltc1096ai/ltc1096i/ltc1096li/ ltc1098ai/ltc1098i/ltc1098li ......... C40c to 85c lead temperature (soldering, 10 sec.) ................. 300c supply voltage (v cc ) to gnd ...................................12v voltage analog and reference ................ C0.3v to v cc + 0.3v digital inputs ........................................ C0.3v to 12v digital outputs ........................... C0.3v to v cc + 0.3v power dissipation ...............................................500mw storage temperature range ................... C65c to 150c (note 3) downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 3 10968fc recommended operating conditions ltc1096/ltc1098 symbol parameter conditions min typ max units v cc supply voltage ltc1096 ltc1098 3.03.0 96 vv v cc = 5v operation f clk clock frequency v cc = 5v 25 500 khz t cyc total cycle time ltc1096, f clk = 500khz ltc1098, f clk = 500khz 2929 ss t hdi hold time, d in after clk v cc = 5v 150 ns t su cs setup time cs before first clk (see operating sequence) v cc = 5v, ltc1096 v cc = 5v, ltc1098 500500 nsns t wakeup wake-up time cs before first clk after first clk (see figure 1 ltc1096 operating sequence) v cc = 5v, ltc1096 10 s wake-up time cs before msbf bit clk (see figure 2 ltc1098 operating sequence) v cc = 5v, ltc1098 10 s t sudi setup time, d in stable before clk v cc = 5v 400 ns t whclk clk high time v cc = 5v 0.8 s t wlclk clk low time v cc = 5v 0.8 s order information lead based finish tape and reel part marking* package description temperature range ltc1096acn8 ltc1096acn8#tr ltc1096acn8 8-lead plastic dip 0c to 70c ltc1096acs8 ltc1096acs8#tr 1096a 8-lead plastic soic 0c to 70c ltc1096ain8 ltc1096ain8#tr ltc1096ain8 8-lead plastic dip C40c to 85c ltc1096ais8 ltc1096ais8#tr 1096ai 8-lead plastic soic C40c to 85c ltc1096cn8 ltc1096cn8#tr ltc1096cn8 8-lead plastic dip 0c to 70c ltc1096cs8 ltc1096cs8#tr 1096 8-lead plastic soic 0c to 70c ltc1096in8 ltc1096in8#tr ltc1096in8 8-lead plastic dip C40c to 85c ltc1096is8 ltc1096is8#tr 1096i 8-lead plastic soic C40c to 85c ltc1096lcs8 ltc1096lcs8#tr 1096l 8-lead plastic soic 0c to 70c ltc1096lis8 ltc1096lis8#tr 1096li 8-lead plastic soic C40c to 85c ltc1098acn8 ltc1098acn8#tr ltc1098acn8 8-lead plastic dip 0c to 70c ltc1098acs8 ltc1098acs8#tr 1098a 8-lead plastic soic 0c to 70c ltc1098cn8 ltc1098cn8#tr ltc1098cn8 8-lead plastic dip 0c to 70c ltc1098cs8 ltc1098cs8#tr 1098 8-lead plastic soic 0c to 70c ltc1098in8 ltc1098in8#tr ltc1098in8 8-lead plastic dip C40c to 85c ltc1098is8 ltc1098is8#tr 1098i 8-lead plastic soic C40c to 85c ltc1098lcs8 ltc1098lcs8#tr 1098l 8-lead plastic soic 0c to 70c ltc1098lis8 ltc1098lis8#tr 1098li 8-lead plastic soic C40c to 85c consult ltc marketing for parts speci? ed with wider operating temperature ranges. *the temperature grade is identi? ed by a label on the shipping container. for more information on lead free part marking, go to: http://www.linear.com/leadfree/ this product is only offered in trays. for more information go to: http://www.linear.com/packaging/ downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 4 10968fc recommended operating conditions symbol parameter conditions min typ max units t wh cs cs high time between data transfer cycles v cc = 5v 1 s t wl cs cs low time during data transfer ltc1096, f clk = 500khz ltc1098, f clk = 500khz 2828 ss v cc = 3v operation f clk clock frequency v cc = 3v 25 250 khz t cyc total cycle time ltc1096, f clk = 250khz ltc1098, f clk = 250khz 5858 ss t hdi hold time, d in after clk v cc = 3v 450 ns t su cs setup time cs before first clk (see operating sequence) v cc = 3v, ltc1096 v cc = 3v, ltc1098 11 ss t wakeup wake-up time cs before first clk after first clk (see figure 1 ltc1096 operating sequence) v cc = 3v, ltc1096 10 s wake-up time cs before msbf bit clk (see figure 2 ltc1098 operating sequence) v cc = 3v, ltc1098 10 s t sudi setup time, d in stable before clk v cc = 3v 1 s t whclk clk high time v cc = 3v 1.6 s t wlclk clk low time v cc = 3v 1.6 s t wh cs cs high time between data transfer cycles v cc = 3v 2 s t wl cs cs low time during data transfer ltc1096, f clk = 250khz ltc1098, f clk = 250khz 5656 ss ltc1096/ltc1098 symbol parameter conditions min typ max units v cc supply voltage 2.65 4.0 v f clk clock frequency v cc = 2.65v 25 250 khz t cyc total cycle time ltc1096l, f clk = 250khz ltc1098l, f clk = 250khz 5858 ss t hdi hold time, d in after clk v cc = 2.65v 450 ns t su cs setup time cs before first clk (see operating sequence) v cc = 2.65v, ltc1096l v cc = 2.65v, ltc1098l 11 ss t wakeup wake-up time cs before first clk after first clk (see figure 1 ltc1096l operating sequence) v cc = 2.65v, ltc1096l 10 s wake-up time cs before msbf bit clk (see figure 2 ltc1098l operating sequence) v cc = 2.65v, ltc1098l 10 s t sudi setup time, d in stable before clk v cc = 2.65v 1 s t whclk clk high time v cc = 2.65v 1.6 s t wlclk clk low time v cc = 2.65v 1.6 s t wh cs cs high time between data transfer cycles v cc = 2.65v 2 s t wl cs cs low time during data transfer ltc1096l, f clk = 250khz ltc1098l, f clk = 250khz 5656 ss ltc1096l/ltc1098l downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 5 10968fc converter and multiplexer characteristics ltc1096/ltc1098 the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 5v, v ref = 5v, f clk = 500khz, unless otherwise noted. parameter conditions ltc1096a/ltc1098a ltc1096/ltc1098 units min typ max min typ max resolution (no missing code) l 8 8 bits offset error l 0.5 0.5 lsb linearity error (note 4) l 0.5 0.5 lsb full scale error l 0.5 1.0 lsb total unadjusted error (note 5) v ref = 5.000v l 0.5 1.0 lsb analog input range (notes 6, 7) C0.05v to v cc + 0.05v v ref input range (notes 6, 7) 4.5 v cc 6v 6v < v cc 9v, ltc1096 C0.05v to v cc + 0.05v C0.05v to 6v vv analog input leakage current (note 8) l 1.0 1.0 a ltc1096/ltc1098 the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 3v, v ref = 2.5v, f clk = 250khz, unless otherwise noted. parameter conditions ltc1096a/ltc1098a ltc1096/ltc1098 units min typ max min typ max resolution (no missing code) l 8 8 bits offset error l 0.75 1.0 lsb linearity error (notes 4, 9) l 0.5 1.0 lsb full-scale error l 1.0 1.0 lsb total unadjusted error (notes 5, 9) v ref = 2.500v l 1.0 1.5 lsb analog input range (notes 6, 7) C0.05v to v cc + 0.05v v ref input range (notes 6, 7, 9) 3v v cc 6v C0.05v to v cc + 0.05v v analog input leakage current (notes 8, 9) l 1.0 1.0 a ltc1096l/ltc1098l the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 2.65v, v ref = 2.5v, f clk = 250khz, unless otherwise noted. parameter conditions ltc1096a/ltc1098a units min typ max resolution (no missing code) l 8 bits offset error l 1.0 lsb linearity error (note 4) l 1.0 lsb full-scale error l 1.0 lsb total unadjusted error (note 5) v ref = 2.5v l 1.5 lsb analog input range (notes 6, 7) C0.05v to v cc + 0.05v v ref input range (note 6) 2.65v v cc 4.0v C0.05v to v cc + 0.05v v analog input leakage current (note 8) l 1.0 a downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 6 10968fc digital and dc electrical characteristics ltc1096/ltc1098 the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 5v, v ref = 5v, unless otherwise noted. symbol parameter conditions min typ max units v ih high level input voltage v cc = 5.25v l 2.0 v v il low level input voltage v cc = 4.75v l 0.8 v i ih high level input current v in = v cc l 2.5 a i il low level input current v in = 0v l C2.5 a v oh high level output voltage v cc = 4.75v, i o = 10a v cc = 4.75v, i o = 360a ll 4.52.4 4.744.72 vv v ol low level output voltage v cc = 4.75v, i o = 1.6ma l 0.4 v i oz hi-z output leakage cs v ih l 3.0 a i source output source current v out = 0v C25 ma i sink output sink current v out = v cc 45 ma i ref reference current cs = v cc t cyc 200s, f clk 50khz t cyc = 29s, f clk = 500khz ll l 0.001 3.500 35.000 2.5 7.5 50.0 aa a i cc supply current cs = v cc l 0.001 3.0 a ltc1096, t cyc 200s, f clk 50khz ltc1096, t cyc = 29s, f clk = 500khz ll 40 120 80 180 aa ltc1098, t cyc 200s, f clk 50khz ltc1098, t cyc = 29s, f clk = 500khz ll 44 155 88 230 aa ltc1096/ltc1098 the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 3v, v ref = 2.5v, unless otherwise noted. symbol parameter conditions min typ max units v ih high level input voltage v cc = 3.6v l 1.9 v v il low level input voltage v cc = 3v l 0.45 v i ih high level input current (note 9) v in = v cc l 2.5 a i il low level input current (note 9) v in = 0v l C2.5 a v oh high level output voltage v cc = 3v, i o = 10a v cc = 3v, i o = 360a ll 2.32.1 2.692.64 vv v ol low level output voltage v cc = 3v, i o = 400a l 0.3 v i oz hi-z output leakage (note 9) cs v ih l 3.0 a i source output source current (note 9) v out = 0v C10 ma i sink output sink current (note 9) v out = v cc 15 ma i ref reference current (note 9) cs = v cc t cyc 200s, f clk 50khz t cyc = 58s, f clk = 250khz ll l 0.001 3.500 35.000 2.5 7.5 50.0 aa a i cc supply current (note 9) cs = v cc l 0.001 3.0 a ltc1096, t cyc 200s, f clk 50khz ltc1096, t cyc = 58s, f clk = 250khz ll 40 120 80 180 aa ltc1098, t cyc 200s, f clk 50khz ltc1098, t cyc = 58s, f clk = 250khz ll 44 155 88 230 aa downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 7 10968fc digital and dc electrical characteristics ltc1096l/ltc1098l the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 2.65v, v ref = 2.5v, f clk = 250khz, unless otherwise noted. symbol parameter conditions min typ max units v ih high level input voltage v cc = 3.6v l 1.9 v v il low level input voltage v cc = 2.65v l 0.45 v i ih high level input current v in = v cc l 2.5 a i il low level input current v in = 0v l C2.5 a v oh high level output voltage v cc = 2.65v, i o = 10a v cc = 2.65v, i o = 360a ll 2.32.1 2.642.50 vv v ol low level output voltage v cc = 2.65v, i o = 400a l 0.3 v i oz hi-z output leakage cs high l 3.0 a i source output source current v out = 0v C10 ma i sink output sink current v out = v cc 15 ma i ref reference current cs = v cc t cyc 200s, f clk 50khz t cyc = 58s, f clk = 250khz ll l 0.001 3.500 35.000 2.5 7.5 50.0 aa a i cc supply current cs = v cc l 0.001 3.0 a ltc1096l, t cyc 200s, f clk 50khz ltc1096l, t cyc = 58s, f clk = 250khz ll 40 120 80 180 aa ltc1098l, t cyc 200s, f clk 50khz ltc1098l, t cyc = 58s, f clk = 250khz ll 44 155 88 230 aa symbol parameter conditions min typ max units t smpl analog input sample time see operating sequence 1.5 clk cycles f smpl(max) maximum sampling frequency l 33 khz t conv conversion time see operating sequence 8 clk cycles t ddo delay time, clk to d out data valid see test circuits l 200 450 ns t dis delay time, cs to d out hi-z see test circuits l 170 450 ns t en delay time, clk to d out enable see test circuits l 60 250 ns t hdo time output data remains valid after clk c load = 100pf 180 ns t f d out fall time see test circuits l 70 250 ns t r d out rise time see test circuits l 25 100 ns c in input capacitance analog inputs on channel analog inputs off channel 25 5 pfpf digital input 5 pf ac characteristics ltc1096/ltc1098 the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 5v, v ref = 5v, f clk = 500khz, unless otherwise noted. downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 8 10968fc note 1: stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. exposure to any absolute maximum rating condition for extended periods may affect device reliability and lifetime. note 2: all voltage values are with respect to gnd. note 3: for the 8-lead pdip, consult the factory. note 4: linearity error is speci? ed between the actual and points of the a/d transfer curve. note 5: total unadjusted error includes offset, full scale, linearity, multiplexer and hold step errors.note 6: two on-chip diodes are tied to each reference and analog input which will conduct for reference or analog input voltages one diode drop below gnd or one diode drop above v cc . this spec allows 50mv forward bias of either diode. this means that as long as the reference or symbol parameter conditions min typ max units t smpl analog input sample time see operating sequence 1.5 clk cycles f smpl(max) maximum sampling frequency l 16.5 khz t conv conversion time see operating sequence 8 clk cycles t ddo delay time, clk to d out data valid see test circuits (note 9) l 500 1000 ns t dis delay time, cs to d out hi-z see test circuits (note 9) l 220 800 ns t en delay time, clk to d out enable see test circuits (note 9) l 160 480 ns t hdo time output data remains valid after clk c load = 100pf 400 ns t f d out fall time see test circuits (note 9) l 70 250 ns t r d out rise time see test circuits (note 9) l 50 150 ns c in input capacitance analog inputs on channel analog inputs off channel 25 5 pfpf digital input 5 pf ac characteristics ltc1096/ltc1098 the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 3v, v ref = 2.5v, f clk = 250khz, unless otherwise noted. symbol parameter conditions min typ max units t smpl analog input sample time see operating sequence 1.5 clk cycles f smpl(max) maximum sampling frequency l 16.5 khz t conv conversion time see operating sequence 8 clk cycles t ddo delay time, clk to d out data valid see test circuits l 500 1000 ns t dis delay time, cs to d out hi-z see test circuits l 220 800 ns t en delay time, clk to d out enable see test circuits l 160 480 ns t hdo time output data remains valid after clk c load = 100pf 400 ns t f d out fall time see test circuits l 70 250 ns t r d out rise time see test circuits l 50 200 ns c in input capacitance analog inputs on channel analog inputs off channel 25 5 pfpf digital input 5 pf ltc1096l/ltc1098l the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. v cc = 2.65v, v ref = 2.5v, f clk = 250khz, unless otherwise noted. analog input does not exceed the supply voltage by more than 50mv, the output code will be correct. to achieve an absolute 0v to 5v input voltage range will therefore require a minimum supply voltage of 4.950v over initial tolerance, temperature variations and loading. for 5.5v < v cc 9v, reference and analog input range cannot exceed 5.55v. if reference and analog input range are greater than 5.55v, the output code will not be guaranteed to be correct. note 7: the supply voltage range for the ltc1096l/ltc1098l is from 2.65v to 4v. the supply voltage range for the ltc1096 is from 3v to 9v, but the supply voltage range for the ltc1098 is only from 3v to 6v. note 8: channel leakage current is measured after the channel selection. note 9: these speci? cations are either correlated from 5v speci? cations or guaranteed by design. downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 9 10968fc typical performance characteristics change in offset vs reference voltage ltc1096 change in offset vs supply voltage change in linearity vs reference voltage ltc1096 change in linearity vs supply voltage change in gain vs supply voltage change in gain vs reference voltage ltc1096 supply current vs clock rate for active and shutdown modes supply current vs supply voltage active and shutdown modes supply current vs sample frequency ltc1096 frequency (khz) 1 0 supply current, i cc (a) 150 200 250 10 100 1000 10968 g01 100 50 t a = 25c cs = 0v v cc = 9v v cc = 5v cs = v cc 10 0.002 supply voltage,v cc (v) 0 0 supply current, i cc (a) 20 60 80 100 2 4 59 10968 g02 40 13 6 7 8 t a = 25c v ref = 2.5v active mode cs = 0 shutdown mode cs = v cc 0.001 sample frequency, f smpl (khz) 0.1 1 supply current, i cc (a) 10 100 1000 1 10 100 10968 g03 t a = 25c v cc = v ref = 5v reference voltage (v) 0 magnitude of offset change (lsb = 1/256 s v ref ) 0 0.25 4 10968 g 04 ?0.25?0.50 1 2 3 5 0.50 t a = 25c v cc = 5v f clk = 500khz supply voltage, v cc (v) 0 magnitude of offset change (lsb) 0.1 0.3 0.5 8 10968 g05 C0.1 C0.3 C0.5 2 4 6 10 0 0.2 0.4 C0.2 C0.4 19 3 5 7 t a = 25c v ref = 2.5v f clk = 100khz reference voltage (v) 0 change in linearity (lsb) 0 0.25 4 10968 g06 C0.25 Co.50 1 2 3 5 0.50 t a = 25c v cc = 5v f clk = 500khz supply voltage, v cc (v) 0 change in linearty (lsb) 0.1 0.3 0.5 8 10968 g07 C0.1 C0.3 C0.5 2 4 6 10 0 0.2 0.4 C0.2 C0.4 19 3 5 7 t a = 25c v ref = 2.5v f clk = 100khz supply voltage, v cc (v) 0 change in gain (lsb) 0.1 0.3 0.5 8 10968 g08 C0.1 C0.3 C0.5 2 4 6 10 0 0.2 0.4 C0.2 C0.4 19 3 5 7 t a = 25c v ref = 2.5v f clk = 100khz voltage reference (v) 0 change in gain (lsb) 0 0.25 4 10968 g09 C0.25 Co.50 1 2 3 5 0.50 t a = 25c v cc = 5v f clk = 500khz downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 10 10968fc typical performance characteristics wake-up time vs supply voltage minimum wake-up time vs source resistance input channel leakage current vs temperature minimum clock frequency for 0.1lsb error ? vs temperature enobs vs frequency fft plot maximum clock frequency vs source resistance maximum clock frequency vs supply voltage digital input logic threshold vs supply voltage * maximum clk frequency represents the clock frequency at which a 0.1lsb shift in the error at any code transition from its 0.75mhz value is ? rst detected. ? as the clk frequency is decreased from 500khz, minimum clk frequency (error 0.1lsb) represents the frequency at which a 0.1lsb shift in any code transition from its 500khz value is ? rst detected. r source C (k) 1 0 maximum clock frequency* (mhz) 0.25 0.50 1 10 100 10968 g10 0.75 + input C input r source C v in t a = 25c v cc = v ref = 5v supply voltage (v) 0 0 maximum clock frequency (mhz) 0.25 0.5 0.75 1.0 1.25 1.5 2468 10968 g11 10 t a = 25c v ref = 2.5v supply voltage, v cc (v) 0 logic thresh0ld (v) 3 4 5 8 10968 g12 2 1 0 2 4 6 10 t a = 25c supply voltage, v cc (v) 0 wake-up time (s) 3 4 8 10968 g13 2 1 0 2 4 6 10 t a = 25c v ref = 2.5v r source (k) 1 0 minimum wake-up time (s) 2.5 5.0 10 10 100 10968 g14 7.5 t a = 25c v ref = 5v + C v in r source + temperature (c) C60 leakage current (na) 10 100 1000 100 10968 g15 1 0.1 0.01 C20 20 60 140 C40 0 40 80 120 v ref = 5v v cc = 5v on channel off channel temperature (c) C60 minimum clock frequency (khz) 120 160 200 100 10968 g16 6040 0 C20 20 60 140 C40 0 40 80 120 v ref = 5v v cc = 5v 180140 100 80 20 frequency (khz) 1 0 enobs 2 4 6 8 10 10 100 10968 g17 97 5 3 1 t a = 25c v cc = v ref = 5v f smpl = 31.25khz frequency (khz) 0 C100 amplitude (db) C90 C70 C60 C50 0 C30 2 4 10968 g18 C80 C20 C10 C40 6 8 10 12 14 16 t a = 25c v cc = v ref = 5v f smpl = 31.25khz f in = 5.8khz downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 11 10968fc pin functions ltc1096/ltc1096l cs /shdn (pin 1): chip select input. a logic low on this input enables the ltc1096/ltc1096l. a logic high on this input disables the ltc1096/ltc1096l and disconnects the power to the ltc1096/ltc1096l. in + (pin 2): analog input. this input must be free of noise with respect to gnd.in C (pin 3): analog input. this input must be free of noise with respect to gnd.gnd (pin 4): analog ground. gnd should be tied directly to an analog ground plane.v ref (pin 5): reference input. the reference input de? nes the span of the a/d converter and must be kept free of noise with respect to gnd. d out (pin 6): digital data output. the a/d conversion result is shifted out of this output.clk (pin 7): shift clock. this clock synchronizes the se- rial data transfer. v cc (pin 8): power supply voltage. this pin provides power to the a/d converter. it must be free of noise and ripple by bypassing directly to the analog ground plane. ltc1098/ltc1098l cs /shdn (pin 1): chip select input. a logic low on this input enables the ltc1098/ltc1098l. a logic high on this input disables the ltc1098/ltc1098l and disconnects the power to the ltc1098/ltc1098l. ch0 (pin 2): analog input. this input must be free of noise with respect to gnd.ch1 (pin 3): analog input. this input must be free of noise with respect to gnd.gnd (pin 4): analog ground. gnd should be tied directly to an analog ground plane.d in (pin 5): digital data input. the multiplexer address is shifted into this pin.d out (pin 6): digital data output. the a/d conversion result is shifted out of this output.clk (pin 7): shift clock. this clock synchronizes the se- rial data transfer. v cc (v ref )(pin 8): power supply voltage. this pin provides power and de? nes the span of the a/d converter. it must be free of noise and ripple by bypassing directly to the analog ground plane. downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 12 10968fc block diagram ltc1096/ltc1096l C + c sample bias and shutdown circuit serial port v cc (v cc /v ref ) cs clk d out in + (ch0) in C (ch1) micropower comparator capacitive dac sar v ref gnd pin names in parenthesesrefer to the ltc1098/ltc1098l (d in ) 10968 bd test circuits on and off channel leakage current load circuit for t ddo , t r and t f d out 1.4v 3k 100pf test point 10968 tc02 5v a a i off i on polarity offchannel on channel 10968 tc01 ?? ? ? downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 13 10968fc test circuits load circuit for t dis and t en voltage waveforms for d out delay time, t ddo voltage waveforms for d out rise and fall times, t r , t f voltage waveforms for t dis clk d out v il t ddo v oh v ol 10968 tc03 d out t r t f 10968 tc04 v oh v ol d out 3k 100pf test point 5v t dis waveform 2, t en t dis waveform 1 10968 tc05 d out waveform 1 (see note 1) 2.0v t dis 90% 10% d out waveform 2 (see note 2) cs note 1: waveform 1 is for an output with internal conditions suchthat the output is high unless disabled by the output control. note 2: waveform 2 is for an output with internal conditions such that the output is low unless disabled by the output control. 10968 tc06 downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 14 10968fc test circuits voltage waveforms for t en 12345 ltc1098/ltc1098l d in clk d out start t en b7 10968 tc08 cs v ol 10968 tc07 cs t wakeup ltc1096/ltc1096l 1 clk d out t en b7 v ol downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 15 10968fc cs 10968 ai ex clk null bit b7 t wakeup 10s t su t su t wakeup d out cs clk d out applications information overview the ltc1096/ltc1096l/ltc1098/ltc1098l are 8-bit micropower, switched-capacitor a/d converters. these sampling adcs typically draw 120a of supply current when sampling up to 33khz. supply current drops linearly as the sample rate is reduced (see supply current vs sample rate on the ? rst page of this data sheet). the adcs automatically power down when not performing conver- sion, drawing only leakage current. they are packaged in 8-pin so packages. the ltc1096l/ltc1098l operate on a single supply ranging from 2.65v to 4v. the ltc1096 operates on a single supply ranging from 3v to 9v while the ltc1098 operates from 3v to 6v supplies. the ltc1096/ltc1096l/ltc1098/ltc1098l comprise an 8-bit, switched-capacitor adc, a sample-and-hold and a serial port (see block diagram). although they share the same basic design, the ltc1096(l) and ltc1098(l) differ in some respects. the ltc1096(l) has a differential input and has an external reference input pin. it can measure signals ? oating on a dc common mode voltage and can operate with reduced spans down to 250mv. reducing the span allows it to achieve 1mv resolution. the ltc1098(l) has a 2-channel input multiplexer and can convert either channel with respect to ground or the difference between the two. serial interface the ltc1098(l) communicates with microprocessors and other external circuitry via a synchronous, half duplex, 4-wire serial interface while the ltc1096(l) uses a 3-wire interface (see operating sequence in figures 1 and 2). power down and wake-up time the ltc1096(l)/ltc1098(l) draw power when the cs pin is low and shut themselves down when that pin is high. in order to have a correct conversion result, a 10s wake-up time must be provided from cs falling to the ? rst falling clock (clk) after the ? rst rising clk for the ltc1096(l) and from cs falling to the msbf bit clk fall- ing for the ltc1098(l) (see operating sequence). if the ltc1096(l)/ltc1098(l) are running with clock frequency less than or equal to 100khz, the wake-up time is inher- ently provided. example two cases are shown at right to illustrate the relationship among wake-up time, setup time and clk frequency for the lt1096(l). in case 1 the clock frequency is 100khz. one clock cycle is 10s which can be the wake-up time, while half of that can be the setup time. in case 2 the clock frequency is 50khz, half of the clock cycle plus the setup time (=1s) can be the wake-up time. if the clk frequency is higher than 100khz, figure 1 shows the relationship between the wake-up time and setup time. case 2. timing diagram case 1. timing diagram downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 16 10968fc the wake-up time is inherently provided for the ltc1098(l) with setup time = 1s (see figure 2). data transfer the clk synchronizes the data transfer with each bit being transmitted on the falling clk edge and captured on the rising clk edge in both transmitting and receiving sys- tems. the ltc1098(l) ? rst receives input data and then transmits back the a/d conversion result (half duplex). because of the half duplex operation, d in and d out may be tied together allowing transmission over just three wires: cs , clk and data (d in /d out ). data transfer is initiated by a falling chip select ( cs ) signal. after cs falls the ltc1098(l) looks for a start bit. after the start bit is received, the 3-bit input word is shifted into the d in input which con? gures the ltc1098(l) and starts the conversion. after one null bit, the result of the conversion figure 1. ltc1096(l) operating sequence is output on the d out line. at the end of the data exchange cs should be brought high. this resets the ltc1098(l) in preparation for the next data exchange. the ltc1096(l) does not require a con? guration input word and has no d in pin. a falling cs initiates data trans- feras shown in the ltc1096(l) operating sequence. after cs falls, the ? rst clk pulse enables d out . after one null bit, the a/d conversion result is output on the d out line. bringing cs high resets the ltc1096(l) for the next data exchange. clk t cyc cs b7* b6 b5 b4 b3 b2 b1 b0 b1 b2 b3 b4 b5 b6 b7 nullbit hi-z d out 10968 f01 power down hi-z t su cs t wakeup t conv clk cs t cyc power down t wakeup b0 b1 b2 b3 b4 b5 b6 b7 hi-z d out t conv hi-z t su cs nullbit *after completing the data transfer, if further clocks are applied with cs low, the adc will output zeros indefinitely. (msb) (msb) applications information d in 1 d in 2 d out 1 d out 2 cs shift mux address in 1 null bit shift a/d conversionresult out 10968 ai01 downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 17 10968fc input data word the ltc1096(l) requires no d in word. it is permanently con? gured to have a single differential input. the conver- sion result, in which output on the d out line is msb-? rst sequence, followed by lsb sequence providing easy interface to msb- or lsb-? rst serial ports. the ltc1098(l) clocks data into the d in input on the ris- ing edge of the clock. the input data words are de? ned as follows: start bit the ? rst logical one clocked into the d in input after cs goes low is the start bit. the start bit initiates the data transfer. the ltc1098(l) will ignore all leading zeros which precede this logical one. after the start bit is received, the remaining bits of the input word will be clocked in. further inputs on the d in pin are then ignored until the next cs cycle. applications information clk cs t cyc power down t su cs t wakeup d in sgl/ diff msbf b0* b1 b2 b3 b4 b5 b6 b7 null bit hi-z d out t conv t smpl hi-z start odd/ sign don't care msb-first data (msbf = 0) msb-first data (msbf = 1) 10968 f02 clk cs t cyc power down t su cs t wakeup d in sgl/ diff msbf b0 b1 b2 b3 b4 b5 b6 b7 null bit hi-z d out t conv t smpl hi-z start odd/ sign don't care b7* b6 b5 b4 b3 b2 b1 *after completing the data transfer, if further clocks are applied with cs low, the adc will output zeros indefinitely. (msb)(msb) figure 2. ltc1098(l) operating sequence example: differential inputs (ch + , ch C ) sgl/ diff odd/ sign msbf start mux address msb-first / lsb-first 10968 ai02 downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 18 10968fc applications information multiplexer (mux) address the bits of the input word following the start bit assign the mux con? guration for the requested conversion. for a given channel selection, the converter will measure the voltage between the two channels indicated by the + and C signs in the selected row of the followintg tables. in single-ended mode, all input channels are measured with respect to gnd. msb-first/lsb-first (msbf) the output data of the ltc1098(l) is programmed for msb-? rst or lsb-? rst sequence using the msbf bit. when the msbf bit is a logical one, data will appear on the d out line in msb-? rst format. logical zeros will be ? lled in inde? nitely following the last data bit. when the msbf bit is a logical zero, lsb-? rst data will follow the normal msb-? rst data on the d out line. (see operating sequence) mux address sgl/ diff 11 0 0 odd/sign 01 0 1 channel # 0+ + C 1+ C + gnd CC single-ended mux mode differential mux mode 10968 ai03 output code 1 1 1 1 1 1 1 11 1 1 1 1 1 1 0 ?? ? 0 0 0 0 0 0 0 10 0 0 0 0 0 0 0 input voltage v ref C 1lsb v ref C 2lsb ?? ? 1lsb 0v input voltage (v ref = 5.000v) 4.9805v4.9609v ?? ? 0.0195v 0v 10968 ai05 0v 1lsb v ref C2lsb v ref C1lsb v ref v in 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 11 1 1 1 1 1 1 0 ?? ? 10968 ai04 unipolar transfer curve the ltc1096(l)/ltc1098(l) are permanently con? gured for unipolar only. the input span and code assignment for this conversion type are shown in the following ? gures for a 5v reference. unipolar transfer curve ltc1098(l) channel selection unipolar output code operation with d in and d out tied together the ltc1098(l) can be operated with d in and d out tied together. this eliminates one of the lines required to com- municate to the microprocessor (mpu). data is transmit- ted in both directions on a single wire. the processor pin connected to this data line should be con? gurable as either an input or an output. the ltc1098(l) will take control of downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 19 10968fc applications information figure 3. ltc1098(l) operation with d in and d out tied together figure 4. automatic power shutdown between conversions allows power consumption to drop with sample rate figure 5. after a conversion, when the microprocessor drives cs high, the adc automatically shuts down until the next conversion. the supply current, which is very low during cconversions, drops to zero in shutdown the data line and drive it low on the 4th falling clk edge after the start bit is received (see figure 3). therefore the processor port line must be switched to an input before this happens, to avoid a con? ict. in the typical applications section, there is an example of interfacing the ltc1098(l) with d in and d out tied together to the intel 8051 mpu.achieving micropower performance with typical operating currents of 40a and automatic shutdown between conversions, the ltc1096/ltc1098 achieves extremely low power consumption over a wide range of sample rates (see figure 4). in systems that convert continuously, the ltc1096/ltc1098 will draw 1 2 3 4 cs clk data (d in /d out ) start sgl/diff odd/sign msbf b7 b6 ??? msbf bit latched by ltc1098(l) ltc1098(l) controls data line and sends a/d result back to mpu mpu controls data line and sends mux address to ltc1098(l) processor must release data line after 4th rising clk and before the 4th falling clk ltc1098(l) takes control of data line on 4th falling clk 10968 f03 its normal operating power continuously. figure 5 shows that the typical current varies from 40a at clock rates below 50khz to 100a at 500khz. several things must be taken into account to achieve such a low power consumption. sample rate, f sample (khz) 0.1 1 supply current, i cc (a) 10 100 1000 1 10 100 10968 f04 t a = 25c v cc = 5v clock frequency (hz) 20 supply current, i cc (a) 60 80 120 140 100 10k 100k 1m 10968 f05 0 1k 100 40 0.002 t a = 25c v cc = 5v active ( cs low) shutdown ( cs high) supply current vs clock rate for active and shutdown modes shutdownfigures 1 and 2 show the operating sequence of the ltc1096/ltc1098. the converter draws power when the cs pin is low and powers itself down when that pin is high. if the cs pin is not taken to ground when it is low and not taken to supply voltage when it is high, the input buffers downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 20 10968fc applications information of the converter will draw current. this current may be larger than the typical supply current. it is worthwhile to bring the cs pin all the way to ground when it is low and all the way to supply voltage when it is high to obtain the lowest supply current. when the cs pin is high (= supply voltage), the converter is in shutdown mode and draws only leakage current. the status of the d in and clk input have no effect on supply current during this time. there is no need to stop d in and clk with cs = high, except the mpu may bene? t. minimize cs low time in systems that have signi? cant time between conversions, lowest power drain will occur with the minimum cs low time. bringing cs low, waiting 10s for the wake-up time, transferring data as quickly as possible, and then bringing it back high will result in the lowest current drain. this minimizes the amount of time the device draws power. even though the device draws more power at high clock rates, the net power is less because the device is on for a shorter time. d out loading capacitive loading on the digital output can increase power consumption. a 100pf capacitor on the d out pin can more than double the 100a supply current drain at a 500khz clock frequency. an extra 100a or so of current goes into charging and discharging the load capacitor. the same goes for digital lines driven at a high frequency by any logic. the cxvxf currents must be evaluated and the troublesome ones minimized. lower supply voltage for lower supply voltages, ltc offers the ltc1096l/ ltc1098l. these pin compatible devices offer speci? ed performance to 2.65v min supply. operating on other than 5v supplies the ltc1096 operates from 3v to 9v supplies and the ltc1098 operates from 3v to 6v supplies. to operate the ltc1096/ltc1098 on other than 5v supplies, a few things must be kept in mind. wake-up time a 10s wake-up time must be provided for the adcs to convert correctly on a 5v supply. the wake-up time is typically less than 3s over the supply voltage range (see typical curve of wake-up time vs supply voltage). with 10s wake-up time provided over the supply range, the adcs will have adequate time to wake up and acquire input signals. input logic levels the input logic levels of cs , clk and d in are made to meet ttl on 5v supply. when the supply voltage varies, the input logic levels also change. for the ltc1096/ltc1098 to sample and convert correctly, the digital inputs have to meet logic low and high levels relative to the operating supply voltage (see typical curve of digital input logic threshold vs supply voltage). if achieving micropower consumption is desirable, the digital inputs must go rail- to-rail between supply voltage and ground (see achieving micropower performance section). clock frequency the maximum recommended clock frequency is 500khz for the ltc1096/ltc1098 running off a 5v supply. with the supply voltage changing, the maximum clock frequency for the devices also changes (see the typical curve of maximum clock rate vs supply voltage). if the maximum clock frequency is used, care must be taken to ensure that the device converts correctly. mixed supplies it is possible to have a microprocessor running off a 5v supply and communicate with the ltc1096/ltc1098 op- erating on 3v or 9v supplies. the requirement to achieve this is that the outputs of cs , clk and d in from the mpu have to be able to trip the equivalent inputs of the adcs and the output of d out from the adcs must be able to toggle the equivalent input of the mpu (see typical curve of digital input logic threshold vs supply voltage). with the ltc1096 operating on a 9v supply, the output of d out may go between 0v and 9v. the 9v output may damage the mpu running off a 5v supply. the way to get around this possibility is to have a resistor divider on d out downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 21 10968fc applications information figure 7. ltc1098(l) + and C input settling windows (figure 6) and connect the center point to the mpu input. it should be noted that to get full shutdown, the cs input of the ltc1096/ltc1098 must be driven to the v cc volt- age. this would require adding a level shift circuit to the cs signal in figure 6. figure 6. interfacing a 9v powered ltc1096 to a 5v system board layout considerations grounding and bypassing the ltc1096(l)/ltc1098(l) should be used with an analog ground plane and single point grounding techniques. the gnd pin should be tied directly to the ground plane. the v cc pin should be bypassed to the ground plane with a 1f tantalum with leads as short as possible. if power supply is clean, the ltc1096(l)/ltc1098(l) can also oper- ate with smaller 0.1f surface mount or ceramic bypass capacitors. all analog inputs should be referenced directly to the single point ground. digital inputs and outputs should be shielded from and/or routed away from the reference and analog circuitry. sample-and-hold both the ltc1096(l) and the ltc1098(l) provide a built-in sample-and-hold (s&h) function to acquire signals. the s&h of the ltc1096(l) acquires input signals from + input relative to C input during the t wakeup time (see figure 1). however, the s&h of the ltc1098(l) can sample input signals in the single-ended mode or in the differential inputs during the t smpl time (see figure 7). single-ended inputs the sample-and-hold of the ltc1098(l) allows conversion of rapidly varying signals. the input voltage is sampled during the t smpl time as shown in figure 7. the sampling interval begins as the bit preceding the msbf bit is shifted +inCin gnd v cc clk d out v ref 50k 50k 6v 4.7f mpu (e.g. 8051) 5v p1.4p1.3 p1.2 10968 f06 differential inputs common mode range 0v to 6v 9v ltc1096 9v optional level shift cs clk d in d out "+" input"C" input sample hold "+" input must settle during this time t smpl t conv cs sgl/ diff start msbf don't care 1st bit test "C" input must settle during this time b7 10968 f07 downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 22 10968fc in and continues until the falling clk edge after the msbf bit is received. on this falling edge, the s&h goes into hold mode and the conversion begins. differential inputs with differential inputs, the adc no longer converts just a single voltage but rather the difference between two volt- ages. in this case, the voltage on the selected + input is still sampled and held and therefore may be rapidly time varying just as in single-ended mode. however, the voltage on the selected C input must remain constant and be free of noise and ripple throughout the conver- sion time. otherwise, the differencing operation may not be performed accurately. the conversion time is 8 clk cycles. therefore, a change in the C input voltage during this interval can cause conversion errors. for a sinusoidal voltage on the C input this error would be: v error (max) = v peak ? 2 ? ? f(C) ? 8/f clk where f(C) is the frequency of the C input voltage, v peak is its peak amplitude and f clk is the frequency of the clk. in most cases v error will not be signi? cant. for a 60hz signal on the C input to generate a 1/4lsb error (5mv) with the converter running at clk = 500khz, its peak value would have to be 750mv. analog inputs because of the capacitive redistribution a/d conversion techniques used, the analog inputs of the ltc1096(l)/ ltc1098(l )have capacitive switching input current spikes. these current spikes settle quickly and do not cause a problem. however, if large source resistances are used or if slow settling op amps drive the inputs, care must be taken to ensure that the transients caused by the current spikes settle completely before the conversion begins. + input settling the input capacitor of the ltc1096(l) is switched onto + input during the wake-up time (see figure 1) and samples the input signal within that time. however, the input capacitor of the ltc1098(l) is switched onto + input during the sample phase (t smpl , see figure 7). the sample phase is 1.5 clk cycles before conversion starts. the voltage on the + input must settle completely within t wakeup or t smpl for the ltc1096(l) or the ltc1098(l) respectively. minimizing r source + and c1 will improve the input settling time. if a large + input source resistance must be used, the sample time can be increased by using a slower clk frequency. C input settling at the end of the t wakeup or t smpl , the input capacitor switches to the C input and conversion starts (see figures 1 and 7). during the conversion the + input voltage is effectively held by the sample-and-hold and will not affect the conversion result. however, it is criti- cal that the C input voltage settles completely during the ? rst clk cycle of the conversion time and be free of noise. minimizing r source C and c2 will improve settling time. if a large C input source resistance must be used, the time allowed for settling can be extended by using a slower clk frequency. input op amps when driving the analog inputs with an op amp it is im- portant that the op amp settle within the allowed time (see figure 7). again, the + and C input sampling times can be extended as described above to accommodate slower op amps. most op amps, including the lt1006 and lt1413 single supply op amps, can be made to settle well even with the minimum settling windows of 3s (+ input) which occur at the maximum clock rate of 500khz. source resistance the analog inputs of the ltc1096/ltc1098 look like a 25pf capacitor (c in ) in series with a 500 resistor (r on ) as shown in figure 8. c in gets switched between the selected + and C inputs once during each conversion cycle. figure 8. analog input equivalent circuit r on = 500 c in = 25pf ltc1096 ltc1098 + input r source + v in + c1 C input r source C v in C c2 10968 f08 applications information downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 23 10968fc capacitive current spike will be generated on the reference pin by the adc. these current spikes settle quickly and do not cause a problem. using a slower clk will allow more time for the reference to settle. even at the maximum clk rate of 500khz most references and op amps can be made to settle within the large external source resistors and capacitances will slow the settling of the inputs. it is important that the overall rc time constants be short enough to allow the analog inputs to completely settle within the allowed time. rc input filtering it is possible to ? lter the inputs with an rc network as shown in figure 9. for large values of c f (e.g., 1f), the capacitive input switching currents are averaged into a net dc current. therefore, a ? lter should be chosen with a small resistor and large capacitor to prevent dc drops across the resistor. the magnitude of the dc current is approximately i dc = 25pf(v in /t cyc ) and is roughly pro- portional to v in . when running at the minimum cycle time of 29s, the input current equals 4.3a at v in = 5v. in this case, a ? lter resistor of 390 will cause 0.1lsb of full- scale error. if a larger ? lter resistor must be used, errors can be eliminated by increasing the cycle time. figure 9. rc input filtering input leakage current input leakage currents can also create errors if the source resistance gets too large. for instance, the maximum input leakage speci? cation of 1a (at 125c) ? owing through a source resistance of 3.9k will cause a voltage drop of 3.9mv or 0.2lsb. this error will be much reduced at lower tem- peratures because leakage drops rapidly (see typical curve of input channel leakage current vs temperature). reference inputs the voltage on the reference input of the ltc1096 de? nes the voltage span of the a/d converter. the reference input transient capacitive switching currents due to the switched-capacitor conversion technique (see figure 10). during each bit test of the conversion (every clk cycle), a figure 10. reference input equivalent circuit 2s bit time.reduced reference operation the minimum reference voltage of the ltc1098 is limited to 3v because the v cc supply and reference are internally tied together. however, the ltc1096 can operate with reference voltages below 1v. the effective resolution of the ltc1096 can be increased by reducing the input span of the converter. the ltc1096 exhibits good linearity and gain over a wide range of ref- erence voltages (see typical curves of linearity and full scale error vs reference voltage). however, care must be taken when operating at low values of v ref because of the reduced lsb step size and the resulting higher accuracy requirement placed on the converter. the following factors must be considered when operating at low v ref values. 1. offset2. noise 3. conversion speed (clk frequency) offset with reduced v ref the offset of the ltc1096 has a larger effect on the output code when the adc is operated with reduced reference voltage. the offset (which is typically a ? xed voltage) becomes a larger fraction of an lsb as the size of the lsb is reduced. the typical curve of unadjusted offset error vs reference voltage shows how offset in lsbs is applications information r filter v in c filter 10968 f09 ltc1098 + C i dc r on 5pf to 30pf ltc1096 ref + r out v ref every clk cycle 5 4 gnd 10968 f10 downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 24 10968fc applications information related to reference voltage for a typical value of v os . for example, a v os of 2mv which is 0.1lsb with a 5v reference becomes 0.5lsb with a 1v reference and 2.5lsbs with a 0.2v reference. if this offset is unacceptable, it can be corrected digitally by the receiving system or by offsetting the C input of the ltc1096. noise with reduced v ref the total input referred noise of the ltc1096 can be reduced to approximately 1mv peak-to-peak using a ground plane, good bypassing, good layout techniques and minimizing noise on the reference inputs. this noise is insigni? cant with a 5v reference but will become a larger fraction of an lsb as the size of the lsb is reduced. for operation with a 5v reference, the 1mv noise is only 0.05lsb peak-to-peak. in this case, the ltc1096 noise will contribute virtually no uncertainty to the output code. however, for reduced references, the noise may become a signi? cant fraction of an lsb and cause undesirable jit- ter in the output code. for example, with a 1v reference, this same 1mv noise is 0.25lsb peak-to-peak. this will reduce the range of input voltages over which a stable output code can be achieved by 1lsb. if the reference is further reduced to 200mv, the 1mv noise becomes equal to 1.25lsbs and a stable code may be dif? cult to achieve. in this case averaging readings may be necessary. this noise data was taken in a very clean setup. any setup- induced noise (noise or ripple on v cc , v ref or v in ) will add to the internal noise. the lower the reference voltage to be used, the more critical it becomes to have a clean, noise free setup. conversion speed with reduced v ref with reduced reference voltages the lsb step size is reduced and the ltc1096 internal comparator overdrive is reduced. therefore, it may be necessary to reduce the maximum clk frequency when low values of v ref are used.input divider it is ok to use an input divider on the reference input of the ltc1096 as long as the reference input can be made to settle within the bit time at which the clock is running. when using a larger value resistor divider on the reference input the C input should be matched with an equivalent resistance. bypassing reference input with divider bypassing the reference input with a divider is also pos- sible. however, care must be taken to make sure that the dc voltage on the reference input will not drop too much below the intended reference voltage. ac performance two commonly used ? gures of merit for specifying the dynamic performance of the adcs in digital signal pro- cessing applications are the signal-to-noise ratio (snr) and the effective number of bits (enobs). signal-to-noise ratio the signal-to-noise ratio (snr) is the ratio between the rms amplitude of the fundamental input frequency to the rms amplitude of all other frequency components at the a/d output. this includes distortion as well as noise products and for this reason it is sometimes referred to as signal-to-noise + distortion [s/(n + d)]. the output is band limited to frequencies from dc to one half the sampling frequency. figure 11 shows spectral content from dc to 15.625khz which is 1/2 the 31.25khz sampling rate. figure 11. this clean fft of an 11.8khz input shows remarkable performance for an adc that draws only 100a when sampling at the 31.25khz rate frequency (khz) 0 amplitude (db) C60 C30 C20 16 10968 f11 C70 C80 C120 4 8 12 C100 0 C10 C40C50 C90 C110 2 6 10 14 f sample = 31.25khz f in = 11.8khz downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 25 10968fc microprocessor interfaces the ltc1096(l)/ltc1098(l) can interface directly (without external hardware to most popular microprocessor (mpu) synchronous serial formats (see table 1). if an mpu without a dedicated serial port is used, then three or four of the mpus parallel port lines can be programmed to form the serial link to the ltc1096(l)/ltc1098(l). included here is one serial interface example and one example showing a parallel port programmed to form the serial interface. motorola spi (mc68hc05c4,cm68hc11) the mc68hc05c4 has been chosen as an example of an mpu with a dedicated serial port. this mpu transfer data msb-? rst and in 8-bit increments. with two 8-bit transfers, the a/d result is read into the mpu. the ? rst 8-bit transfer sends the d in word to the ltc1098(l) and clocks into the processor. the second 8-bit transfer clocks the a/d conversion result, b7 through b0, into the mpu. anding the ? rst mup received byte with 00hex clears the ? rst byte. notice how the position of the start bit in the ? rst mpu transmit word is used to position the a/d result right-justi? ed in two memory locations. applications information typical applications effective number of bitsthe effective number of bits (enobs) is a measurement of the resolution of an a/d and is directly related to the s/(n + d) by the equation: enob = [s/(n + d) C1.76]/6.02 where s/(n + d) is expressed in db. at the maximum sam- pling rate of 33khz the ltc1096 maintains 7.5 enobs or better to 40khz. above 40khz the enobs gradually decline, as shown in figure 12, due to increasing second harmonic distortion. the noise ? oor remains approximately 70db. figure 12. dynamic accuracy is maintained up to an input frequency of 40khz input frequency (khz) 0 effective number of bits (enobs) 3 4 5 10968 f12 2 1 0 20 40 6 7 8 f sample = 31.25khz table 1. microprocessor with hardware serial interfaces compatible with the ltc1096(l)/ltc1098(l) part number type of interface motorola mc6805s2,s3 mc68hc11 mc68hc05 spispi spi rca cdp68hc05 spi hitachi hd6305 hd63705 hd6301 hd63701 hd6303 hd64180 sci synchronoussci synchronous sci synchronous sci synchronous sci synchronous csi/o national semiconductorcop400 family cop800 family ns8050u hpc16000 family microwire?microwire/plus? microwire/plus microwire/plus texas instruments tms7002 tms7042 tms70c02 tms70c42 tms32011* tms32020 serial portserial port serial port serial port serial port serial port * requires external hardware microwire and microwire/plus are trademarks of national semiconductor corp. downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 26 10968fc typical applications mpu transmit word cs clk d out mpu received word d in 00 01 odd/ sign msbf x sgl/ diff xxxxxxxx start bit byte 1 byte 2 (dummy) x = don't care start sgl/ diff don't care b7 b6 b5 b4 b3 b2 b1 b0 odd/ sign msbf ?? ?? ???0 b7 b6 b5 b4 b3 b2 b1 b0 2nd transfer 1st transfer 10968 ta03 10968 ta04 clk d in cs analog inputs c0 sck d out misomosi mc68hc05c4 ltc1098 location a + 1 lsb location a byte 2 byte 1 10968 ta05 b7 b6 b5 b4 b3 b2 b1 b0 00 00 0000 data exchange between ltc1098(l) and mc68hc05c4 hardware and software interface to motorola mc68hc05c4 d out from ltc1098(l) stored in mc68hc05c4 label mnemonic comments start bclrn lda sta tst bpl lda sta and sta tst bpl bsetn lda sta bit 0 port c goes low ( cs goes low) load ltc1098(l) d in word into acc. load ltc1098(l) d in word into spi from acc. transfer begins. test status of spif loop to previous instruction if not done with transfer load contents of spi data register into acc. (d out msbs) start next spi cycle clear the ? rst d out word store in memory location a (msbs) test status of spif loop to previous instruction if not done with transfer set b0 of port c ( cs goes high) load contents of spi data register intoacc. (d out lsbs) store in memory location a + 1 (lsbs) downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 27 10968fc typical applications interfacing to the parallel port of theintel 8051 family the intel 8051 has been chosen to demonstrate the interface between the ltc1098(l) and parallel port mi- croprocessors. normally the cs , clk and d in signals would be generated on three port lines and the d out signal read on a fourth port line. this works very well. however, we will demonstrate here an interface with the d in and d out of the ltc1098(l) tied together as described in the serial interface section. this saves one wire. the 8051 ? rst sends the start bit and mux address to the ltc1098(l) over the data line connected to p1.2. then p1.2 is recon? gured as an input (by writing to it a one) and the 8051 reads back the 8-bit a/d result over the same data line. d out from ltc1098(l) stored in 8051 ram cs clk d out d in ltc1098(l) analog inputs p1.4p1.3 p1.2 8051 mux address a/d result 10968 ta06 r2 10968 ta07 msb lsb b7 b6 b5 b4 b3 b2 b1 b0 1 cs clk data (d in /d out ) start odd/ sign msbf b7 msbf bit latched by ltc1098(l) ltc1098(l) sends a/d result back to 8051 p1.2 8051 p1.2 outputs data to ltc1098(l) 8051 p1.2 reconfigured as an input after the 4th rising clk and before the 4th falling clk ltc1098(l) takes control of data line on 4th falling clk 234 sgl/ diff b6 b5 b4 b3 b2 b1 b0 10968 ta08 label mnemonic operand comments loop 1 loop movsetb clr mov rlc clr mov setb djnz mov clr mov mov rlc setb clr djnz mov setb a, #ffhp1.4 p1.4 r4, #04 a p1.3 p1.2, c p1.3 r4, loop 1 p1, #04 p1.3 r4, #09 c, p1.2 a p1.3 p1.3 r4, loop r2, a p1.4 d in word for ltc1098(l) make sure cs is high cs goes low load counterrotate d in bit into carry clk goes lowoutput d in bit to ltc1098(l) clk goes highnext bit bit 2 becomes an input clk goes low load counter read data bit into carry rotate data bit into acc. clk goes high clk goes low next bit store msbs in r2 cs goes high downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 28 10968fc a quick look circuit for the ltc1096 users can get a quick look at the function and timing of the lt1096 by using the following simple circuit (figure 13). v ref is tied to v cc . v in is applied to the +in input and the C in input is tied to the ground. cs is driven at 1/16 the clock rate by the 74c161 and d out outputs the data. the output data from the d out pin can be viewed on an oscilloscope that is set up to trigger on the falling edge of cs (figure 14). note the lsb data is partially clocked out before cs goes high. figure 15. the ltc1096s high impedance input connects directly to this temperature sensor, eliminating signal conditioning circuitry in this 0c to 70c thermometer figure 14. scope trace the ltc1096 quick look circuit showing a/d output 10101010 (aa hex ) figure 13. quick look circuit for the ltc1096 figure 15 shows a temperature measurement system. the ltc1096 is connected directly to the low cost silicon temperature sensor. the voltage applied to the v ref pin adjusts the full scale of the a/d to the output range of the sensor. the zero point of the converter is matched to the zero output voltage of the sensor by the voltage on the ltc1096s negative input. clrclk a b c d p gnd v cc rcqa qb qc qd t load 74c161 v in to oscilloscope clock in 150khz max 10968 f13 v cc clk d out v ref ltc1096 csch0 ch1 gnd 4.7f 5v 5v + ltc1096 +inCin v ref cs clk d out v cc gnd to p 63.4k 0.01f 182k 0.01f lt1004-1.2 0.1f 3v 75k 678 13.5k lm134 10968 f15 vertical: 5v/div horizontal: 10s/div null bit cs clk d out msb (b7) lsb (b0) lsb data (b1) 10968 f14 downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 29 10968fc remote or isolated systemsfigure 16 shows a ? oating system that sends data to a grounded host system. the ? oating circuitry is isolated by two optoisolators and powered by a simple capacitor diode charge pump. the system has very low power requirements because the ltc1096 shuts down between conversions and the optoisolators draw power only when data is being transferred. the system consumes only 50a at a sample rate of 10hz (1ms on-time and 99ms off-time). this is easily within the current supplied by the charge pump running at 5mhz. if a truly isolated system is required, the systems low power simpli? es generating an isolated supply or powering the system from a battery. figure 16. power for this floating a/d system is provided by a simple capacitor diode charge pump. the two optoisolators draw no current between samples, turning on only to send the clock and receive data ltc1096 +inCin d out csclk v cc gnd v ref 75k lt1004-2.5 1k 20k 0.1f 1n5817 0.022f 47f 1n5817 1n5817 0.001f 2kv 5mhz 100k 300 10k 500k analoginput floating system clk data 100k 10968 f16 2n3904 + downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 30 10968fc package description n8 package 8-lead pdip (narrow .300 inch) (reference ltc dwg # 05-08-1510) n8 1002 .065 (1.651) typ .045 ? .065 (1.143 ? 1.651) .130 .005 (3.302 0.127) .020 (0.508) min .018 .003 (0.457 0.076) .120 (3.048) min 12 3 4 87 6 5 .255 .015* (6.477 0.381) .400* (10.160) max .008 ? .015 (0.203 ? 0.381) .300 ? .325 (7.620 ? 8.255) .325 +.035?.015 +0.889 ?0.381 8.255 () note:1. dimensions are inches millimeters *these dimensions do not include mold flash or protrusions. mold flash or protrusions shall not exceed .010 inch (0.254mm) .100 (2.54) bsc downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 31 10968fc information furnished by linear technology corporation is believed to be accurate and reliable. however, no responsibility is assumed for its use. linear technology corporation makes no representa- tion that the interconnection of its circuits as described herein will not infringe on existing patent rights. package description s8 package 8-lead plastic small outline (narrow .150 inch) (reference ltc dwg # 05-08-1610) .016 ? .050 (0.406 ? 1.270) .010 ? .020 (0.254 ? 0.508) 45 0 ? 8 typ .008 ? .010 (0.203 ? 0.254) so8 0303 .053 ? .069 (1.346 ? 1.752) .014 ? .019 (0.355 ? 0.483) typ .004 ? .010 (0.101 ? 0.254) .050 (1.270) bsc 1 2 3 4 .150 ? .157 (3.810 ? 3.988) note 3 8 7 6 5 .189 ? .197 (4.801 ? 5.004) note 3 .228 ? .244 (5.791 ? 6.197) .245 min .160 .005 recommended solder pad layout .045 .005 .050 bsc .030 .005 typ inches (millimeters) note:1. dimensions in 2. drawing not to scale3. these dimensions do not include mold flash or protrusions. mold flash or protrusions shall not exceed .006" (0.15mm) downloaded from: http:/// ltc1096/ltc1096l ltc1098/ltc1098l 32 10968fc linear technology corporation 1630 mccarthy blvd., milpitas, ca 95035-7417 (408) 432-1900 fax: (408) 434-0507 www.linear.com ? linear technology corporation 1994 lt 0708 rev c printed in usa related parts typical application part number description comments ltc1196/ltc1198 8-pin so, 1msps, 8-bit adcs low power, small size, low cost ltc1286/ltc1298 8-pin so, 5v micropower, 12-bit adcs 1- or 2-channel, auto shutdown ltc1285/ltc1298 8-pin so, 3v micropower, 12-bit adcs 1- or 2-channel, auto shutdown ltc1400 5v high speed,serial 12-bit adc 400ksps, complete with v ref , clk, sample-and-hold ltc1594/ltc1598 4- and 8-channel, 5v micropower, 12-bit adcs low power, small size, low cost ltc1594l/ltc1598l 4- and 8-channel, 3v micropower, 12-bit adcs low power, small size, low cost a/d conversion for 3v systems the ltc1096/ltc1098 are ideal for 3v systems. figure 17 shows a 3v to 6v battery current monitor that draws only 70a from the battery it monitors. the battery cur- rent is sensed with the 0.02 resistor and ampli? ed by the lt1178. the ltc1096 digitizes the ampli? er output and sends it to the microprocessor in serial format. the lt1004 provides the full-scale reference for the adc. the other half of the ltc1178 is used to provide low battery detection. the circuits 70a supply current is dominated by the op amps and the reference. the circuit can be located near the battery and data transmitted serially to the microprocessor. figure 17. this 0a to 2a battery current monitor draws only 70a from a 3v battery C + 750k 0.1f 0.02 for 2a full scale0.2 for 0.2a full scale 24.9k l o a d 1/2 lt1178 ltc1096 csgnd v cc clk d out v ref lt1004-1.2 73.2k 470k 20m 470k lo battery 0.1f + C 3v to 6v to p C + 1/2 lt1178 10968 f17 downloaded from: http:/// |
Price & Availability of LTC1096LIS8TR |
|
|
All Rights Reserved © IC-ON-LINE 2003 - 2022 |
[Add Bookmark] [Contact Us] [Link exchange] [Privacy policy] |
Mirror Sites : [www.datasheet.hk]
[www.maxim4u.com] [www.ic-on-line.cn]
[www.ic-on-line.com] [www.ic-on-line.net]
[www.alldatasheet.com.cn]
[www.gdcy.com]
[www.gdcy.net] |