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d1912hkpc 20121204-s00003 no.a2162-1/11 ver1.0.1 * i 2 c bus is a trademark of philips corporation. specifications of any and all sanyo semiconductor co.,ltd. products described or contained herein stipulate the performance, characteristics, and functions of the described products in the independent state, and are not guarantees of the performance, characteristics, and functions of the described products as mounted in the customer ' s products or equipment. to verify symptoms and states that cannot be evaluated in an independent device, the customer should always evaluate and test devices mounted in the customer ' s products or equipment. any and all sanyo semiconductor co.,ltd. products described or contained herein are, with regard to "standard application", intended for the use as general electronics equipment. the products mentioned herein shall not be intended for use for any "special application" (medical equipment whose purpose is to sustain life, aerospace instrument, nuclear control device, burning appli ances, transportation machine, traffic signal system, safety equipment etc.) that shall require extremely high level of reliab ility and can directly threaten human lives in case of failure or malfunction of the product or may cause harm to human bodies, nor shall they grant any guarantee thereof. if you should intend to use our products for new introduction or other application different from current conditions on the usage of automotive device, communication device, office equipment, industrial equipment etc. , please consult with us about usage condition (temperature, operation time etc.) prior to the intended use. if there is no consultation or inquiry before the intended use, our customer shall be solely responsible for the use. LC717A10AJ overview the LC717A10AJ is a high-performance and low-cost cap acitance-digital-converter lsi for electrostatic capacitive touch sensor, especially focused on usability. it has 16 channels capacitance-sensor input. this makes it ideal for use in the products that need many switches. since the calibration function and the judgment of on/off are automatically performed in lsi internal, it can make development time more short. a detection result (on/off) fo r each input can be read out by the serial interface (i 2 c compatible bus or spi). also, measurement value of each input can be read out as 8-bit digital data . moreover, gain and other parameters can be adjusted using serial interface. features ? detection system: differential capacitance detection (mutual capacitance type) ? input capacitance resolution: can detect capacitance changes in the femto farad order ? measurement interval (16 differential input s): 30ms (typ) (at initial configuration), 6ms (typ) (at minimum interval configuration) ? external components for measurement: not required ? interface: i 2 c * compatible bus or spi selectable. ? current consumption: 570 a (typ) (v dd = 2.8v), 1.3ma (typ) (v dd = 5.5v) ? supply voltage: 2.6v to 5.5v ? detection operations: switch ? packages: ssop30 ordering number : ena2162 cmos lsi capacitance-digital-converter lsi for electrostatic capacitive touch sensors
LC717A10AJ no.a2162-2/11 specifications absolute maximum ratings at ta = +25 c parameter symbol ratings (v ss = 0v) unit remarks supply voltage v dd -0.3 to +6.5 v input voltage v in -0.3 to v dd +0.3 v *1 output voltage v out -0.3 to v dd +0.3 v *2 power dissipation pd max 160 mw ta = +105 c, mounted on a substrate *3 storage temperature tstg -55 to +125 c *1) apply to cin0 to 15, cref, crefadd, nrst, scl, sda, sa0, sa1, sck, si, ncs *2) apply to cdrv, sda, so, intout *3) single-layer glass epoxy board (76.1 114.3 1.6t mm) recommended operating conditions parameter symbol conditions min typ max unit remarks operating supply voltage v dd 2.6 5.5 v supply ripple + noise vpp 20 mv *1 operating temperature topr -40 25 105 c *1) we recommend connecting larg e and small capacitance between v dd and v ss . in this case, the small capacitance is equal to or more than 0.1 f, and layout nearby lsi. electrical characteristics at v ss = 0v, v dd = 2.6 to 5.5v, ta = -40 to +105 c * unless otherwise specified, the cdrv drive frequency is f cdrv = 143khz. * not tested at low temperature before shipment. parameter symbol conditions min typ max unit remarks capacitance detection resolution n 8 bit output noise rms n rms minimum gain setting 1.0 lsb *1 *3 input offset capacitance adjustment range coff range 8.0 pf *1 *3 input offset capacitance adjustment resolution coff reso 8 bit cin offset drift cin drift minimum gain setting 8 lsb *1 cin detection sensitivity cin sense minimum gain setting 0.04 0.12 lsb/ff *2 cin pin leak current i cin cin = hi-z 25 500 na cin allowable parasitic input capacitance cin sub cin against v ss 30 pf *1 *3 cdrv drive frequency f cdrv 100 143 186 khz cdrv pin leak current i cdrv cdrv = hi-z 25 500 na nrst minimum pulse width t nrst 1 s *1 power-on reset time t por 20 ms *1 power-on reset operation condition: hold time t porop 10 ms *1 power-on reset operation condition: input voltage v porop 0.1 v *1 power-on reset operation condition: power supply rise rate t vdd 0v to v dd 1 v/ms *1 continued to the next page.
LC717A10AJ no.a2162-3/11 continued from the previous page. parameter symbol conditions min typ max unit remarks v ih high input 0.8v dd pin input voltage v il low input 0.2v dd v *1 *4 v oh high output (i oh = +3ma) 0.8v dd pin output voltage v ol low output (i ol = -3ma) 0.2v dd v *5 sda pin output voltage v ol i 2 c sda low output (i ol = -3ma) 0.4 v pin leak current i leak 1 a *6 when initial setting and non-touch v dd = 2.8v 570 700 a *1 *3 i dd when initial setting and non-touch v dd = 5.5v 1.3 1.6 ma *1 *3 current consumption i stby during sleep process 1 a *3 *1) design guarantee values (not tested before shipment) *2) measurements conducted using the test mode in the lsi *3) ta = +25 c *4) apply to nrst, scl, sda, sa0, sa1, sck, si, ncs *5) apply to cdrv, so, intout *6) apply to nrst, scl, sda, sa0, sa1, sck, si, ncs
LC717A10AJ no.a2162-4/11 i 2 c compatible bus timing characteristics at v ss = 0, v dd = 2.6 to 5.5v, ta = -40 to +105 c *not tested at low temp erature before shipment parameter symbol pin name conditions min typ max unit remarks scl clock frequency f scl scl 400 khz start condition hold time t hd;sta scl sda 0.6 s scl clock low period t low scl 1.3 s scl clock high period t high scl 0.6 s repeated start condition setup time t su;sta scl sda 0.6 s *1 data hold time t hd;dat scl sda 00.9 s data setup time t su;dat scl sda 100 s *1 sda, scl rise/fall time t r / t f scl sda 300 s *1 stop condition setup time t su;sto scl sda 0.6 s stop-to-start bus release time t buf scl sda 1.3 s *1 * 1) design guarantee values (not tested before shipment) spi bus timing characteristics at v ss = 0, v dd = 2.6 to 5.5v, ta = -40 to +105 c *not tested at low temp erature before shipment parameter symbol pin name conditions min typ max unit remarks sck clock frequency f sck sck 5 mhz sck clock low time t low sck 90 ns *1 sck clock high time t high sck 90 ns *1 input signal rise/fall time t r / t f ncs sck si 300 ns *1 ncs setup time t su;ncs ncs sck 90 ns *1 sck clock setup time t su;sck ncs sck 90 ns *1 data setup time t su;si sck si 20 ns *1 data hold time t hd;si sck si 30 ns *1 ncs hold time t hd;ncs ncs sck 90 ns *1 sck clock hold time t hd;sck ncs sck 90 ns *1 ncs standby pulse width t cph ncs 90 ns *1 output high impedance time from ncs t chz ncs so 80 ns *1 output data determination time t v sck so 80 ns *1 output data hold time t hd;so sck so 0 ns *1 output low impedance time from sck clock t clz sck so 0 ns *1 * 1) design guarantee values (not tested before shipment)
LC717A10AJ no.a2162-5/11 power-on reset (por) when power is turned on, power-on reset is enabled inside th e lsi and its state is released after a certain power-on reset time, t por . power-on reset operation condition; power supply rise rate t vdd must be at least 1v/ms. since intout pin changes from ?high? to ?low? at the same time as the released of power-on reset, it is possible to verify the timing of release of power-on reset externally. during power-on reset, cin, cref and crefadd are unknown. fig.1 i 2 c compatible bus data timing fig.2 i 2 c compatible bus communication formats ? write format (data can be written into sequentially incremented addresses) start slave address write=l register address (n) ack ack data written to register address (n) ack data written to register address (n+1) ack stop slave slave slave slave fig.3 ? read format (data can be read from sequentially incremented addresses) start slave address write=l register address (n) ack ack data read from register address (n) ack restart slave address read=h ack data read from register address (n+1) ack data read from register address (n+2) nack stop slave slave slave master master master fig.4 sda scl start condition t hd;sta t low t hi g h t r repeated start condition stop condition 10% t f 90% 10% 10% 90% 90% t hd;dta t su;dta 10% 10% 10% 90% t su;sta 90% 90% t hd;sta 90% 10% 90% 10% 90% 10% t su;sto t buf start condition 90% por (lsi internal signal) release t p o r v dd reset t vdd intout v p o r o p cin, cref, crefadd unknown valid t p o r o p unknown unknown unknown reset release t p o r valid
LC717A10AJ no.a2162-6/11 i 2 c compatible bus slave address selection of two kinds of addresses is possible through the sa0 and sa1 terminals. sa1 input sa0 input 7bit slave address binary notation 8bit slave address 00101100b (write) 0x2c low low 0x16 00101101b (read) 0x2d 00101110b (write) 0x2e low high 0x17 00101111b (read) 0x2f 00110000b (write) 0x30 high low 0x18 00110001b (read) 0x31 00110010b (write) 0x32 high high 0x19 00110011b (read) 0x33 spi data timing (spi mode 0 / mode 3) fig.5 spi communication formats (example of mode 0) ? write format (data can be written into sequentially incremented addresses with preserving ncs = l) ncs sck si so 76543 2 10 hi-z register address(n) data written to register address(n) data written to register address(n+1) write=l 76543 2 10 76543 2 10 fig.6 ? read format (data can be read from sequentially incremented addresses with preserving ncs = l) register address(n) data read from register address(n) data read from register address(n+1) 7 read=h 76543 2 10 hi-z ncs sck si so 76543 2 10 76543 2 10 fig.7 ncs sck si so t su;si valid hi-z t r t hd;si t su;sck t su;ncs t high t low t f t cph t hd;ncs t hd;sck t clz t hd;so t chz valid t v
LC717A10AJ no.a2162-7/11 package dimensions [LC717A10AJ] unit : mm (typ) 3421 pin assignment pin no. pin name pin no. pin name 1 v dd 16 cref 2 v ss 17 crefadd 3 non connect *1 18 cdrv 4 cin4 19 intout 5 cin5 20 sa1 6 cin6 21 scl/sck 7 cin7 22 sda/si 8 cin8 23 sa0/so 9 cin9 24 ncs 10 cin10 25 nrst 11 cin11 26 non connect *1 12 cin12 27 cin0 13 cin13 28 cin1 14 cin14 29 cin2 15 cin15 30 cin3 *1) connect to gnd when mounted sanyo : ssop30(225mil) 8.0 4.4 0.1 6.4 12 30 0.15 0.5 0.22 0.5 (0.5) 1.7 max (1.5)
LC717A10AJ no.a2162-8/11 block diagram cin0 v dd v ss intout cin1 cin2 cin3 cin4 cin5 cin6 cin7 cin8 cin9 cin10 cin11 cin12 cin13 cin14 cin15 cref crefadd cdrv nrst ncs scl/sck sda/si sa0/so sa1 mux mux 1st amp a/d converter 2nd amp control logic i 2 c/spi por oscillator LC717A10AJ is capacitance-digital-converter lsi capable of detecting changes in capacitance in the order of femto farads. it consists of an oscillation circu it that generates the system clock, a power -on reset circuit that resets the system when the power is turned on, a multiplexer that selects the input channels, a two-stage amplifier that detects the changes in the capacitance and outputs analog-amplitude values, a a/ d converter that converts the analog-amplitude values into digital data, an i 2 c compatible bus or a spi that enables serial comm unication with external devices and a control logic that controls the entire chip.
LC717A10AJ no.a2162-9/11 pin functions pin name i/o pin functions pin type cin0 i/o capacitance sensor input cin1 i/o capacitance sensor input cin2 i/o capacitance sensor input cin3 i/o capacitance sensor input cin4 i/o capacitance sensor input cin5 i/o capacitance sensor input cin6 i/o capacitance sensor input cin7 i/o capacitance sensor input cin8 i/o capacitance sensor input cin9 i/o capacitance sensor input cin10 i/o capacitance sensor input cin11 i/o capacitance sensor input cin12 i/o capacitance sensor input cin13 i/o capacitance sensor input cin14 i/o capacitance sensor input cin15 i/o capacitance sensor input cref i/o reference capacitance input crefadd i/o reference capacitance input for addition r amp v dd v ss buffer cdrv o output for capacitance sensors drive intout o interrupt output v dd v ss buffer scl/sck i clock input (i 2 c) / clock input (spi) ncs i interface selection / chip select inverting input (spi) nrst i external reset signal inverting input sa1 i slave address selection (i 2 c) v dd v ss r sda/si i/o data input and output (i 2 c) / data input (spi) v dd v ss r continued to the next page.
LC717A10AJ no.a2162-10/11 continued from the previous page. pin name i/o pin functions pin type sa0/so i/o slave address selection (i 2 c) / data output (spi) v dd v ss r buffer v dd power supply (2.6v to 5.5v) *1 v ss ground (earth) *1 *2 * 1) inserting a high-valued capacitor and a low-valued capacitor in parallel between v dd and v ss is recommended. in this case, the small-valued capacitor should be at least 0.1 f, and is mounted near the lsi. * 2) when v ss terminal is not grounded in battery-powered mobile equipment, detection sensitivity may be degraded. details of pin functions cin0 to cin15 these are the capacitance-sensor-input pins. these pins are used by connecting them to the touch switch pattern. cin and the cdrv wire patterns should be close to each ot her. by doing so, cdrv and cin patterns are capacitively coupled. therefore, lsi can de tect capacitance change near each pattern as 8bit digital data. however, if the shape of each pattern or the capacitively coupl ed value of cdrv is not appropriate, it may not be able to detect the capacitance change correctly. in this lsi, there is a two-stage amplifier that detects the changes in the capacitance and outputs analog-amplitude values. cin0 to cin15 are connected to th e inverting input of the 1st amplifier. during measurement process, channels other than the one being measured are all in ?low? condition. leave the unused terminals open. cref, crefadd these are the reference-capacitance-input pins. these are used by connecting to the wire pattern like cin pins or are used by connecting any capacitance between this pin and cdrv pin. in this lsi, there is a two-stage amplifier that detects the changes in the capacitance and outputs analog-amplitude values. cref is connected to the non-inverting input of the 1st amplifier. due to the parasitic capacitance generated in the wire connec tions of cin pins and their patterns, as well as the one generated between the wire patterns of cin and cdrv pins, cref may not detect capacitance change of each cin pin accurately. in this case, connect an appropriate capacitan ce between cref and cdrv to detect capacitance change accurately. however, if the difference between the parasitic capacitan ce of each cin pin is extremely large, it may not detect capacitance change of each cin pin correctly. crefadd can be used as additional terminal for cref. leave the crefadd open if not in used. cdrv it is the output pin for capacitance sensors drive. it output s the pulse voltage which is needed to detect capacitance at cin0 to cin15. cdrv and cin wire patterns should be close to each other so that they are capacitively coupled. intout it is the interrupt-output pin. it is used by connecting to a main microcomputer if necessary, and use as interrupt signal. (high active) leave the terminal open if not in used. scl/sck clock input (i 2 c) / clock input (spi) it is the clock input pin of the i 2 c compatible bus or the spi depending on the mode of operation.
LC717A10AJ no.a2162-11/11 ncs interface selection / chip-select-inverting input (spi) selection of i 2 c compatible bus mode or spi mode is through this terminal. after initialization, the lsi is automatically in i 2 c compatible bus mode. to continually use i 2 c compatible bus mode, fix ncs pin to ?high?. to switch to spi mode after lsi initialization, change the ncs input ?high? ?low?. the ncs pin is used as the chip- select-inverting input pin of spi, and spi m ode is kept until lsi is again initialized. nrst it is the external-reset-signal-inverting-input pin. when nrst pin is ?low?, lsi is in reset state. each pin (cin0 to 15, cref, crefadd) is ?hi-z? during reset state. sda/si data input and output (i 2 c) / data input (spi) it is the data input and output pin of the i 2 c compatible bus or the data input pin of the spi depending on the mode of operation. sa0/so slave address selection (i 2 c) / data output (spi) it is the slave address selection pin of the i 2 c compatible bus or the data output pin of the spi depending on the mode of operation. sa1 slave address selection (i 2 c) it is the slave address selection pin of the i 2 c compatible bus. when spi mode, connect to the sa1 pin to gnd. ps sanyo semiconductor co.,ltd. assumes no responsibility for equipment failures that result from using products at values that exceed, even momentarily, rated values (such as maximum ratings, operating condition ranges, or other parameters) listed in products specif ications of any and all sanyo semiconductor co.,ltd. products described or contained herein. regarding monolithic semiconductors, if you should intend to use this ic continuously under high temperature, high current, high voltage, or drastic temperature change, even if it is used within the range of absolute maximum ratings or operating conditions, there is a possibility of decrease reliability. please contact us for a confirmation. sanyo semiconductor co.,ltd. strives to supply high-quality high-reliability products, however, any and all semiconductor products fail or malfunction with some probability. it is possible that these probabilistic failures or malfunction could give rise to accidents or events that could endanger human lives, trouble that could give rise to smoke or fire, or accidents that could cause damage to other property. when designing equipment, adopt safety measures so that these kinds of accidents or events cannot occur. such measures include but are not limited to protective circuits and error prevention circuits for safe design, redundant design, and structural design. in the event that any or all sanyo semiconductor co.,ltd. products described or contained herein are controlled under any of applicable local export control laws and regulations, such products may require the export license from the authorities concerned in accordance with the above law. no part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, or any information storage or retrieval system, or otherwise, without the prior written consent of sanyo semiconductor co.,ltd. any and all information described or contained herein are subject to change without notice due to product/technology improvement, etc. when designing equ ipment, refer to the "delivery specification" for the sanyo semiconductor co.,ltd. product that you intend to use. upon using the technical information or products described herein, neither warranty nor license shall be granted with regard to intellectual property rights or any other rights of sanyo semiconductor co.,ltd. or any third party. sanyo semiconductor co.,ltd. shall not be liable for any claim or suits with regard to a third party's intellectual property rights which has resulted from the use of the technical information and products mentioned above. this catalog provides information as of december, 2012. specifications and information herein are subject to change without notice.

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