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TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 1 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com features � rgb and clear color sensing and proximity detection in a single device � color light sensing with ir-blocking filter ? programmable analog gain and integration time ? 3,800,000:1 dynamic range ? very high sensitivity ? ideally suited for operation behind dark glass � proximity detection ? ambient light rejection ? programmable integration time ? current sink driver for external ir led � maskable light and proximity interrupt ? programmable upper and lower thresholds with persistence filter � power management ? low power ? 2.5-� a sleep state ? 65-� a wait state withprogrammable wait state time from 2.4 ms to > 7 seconds � i 2 c fast mode compatible interface ? data rates up to 400 kbit/s ? input voltage levels compatible with v dd or 1.8 v bus � register set and pin compatible with the tcs3x71 series � small 2 mm 2.4 mm dual flat no-lead (fn) package applications � rgb led backlight control � ambient light color temperature sensing � cell phone touch screen disable � mechanical switch replacement � industrial process control � medical diagnostics end products and market segments � hdtvs, mobile handsets, tablets, and portable media payers � medical and commercial instrumentation � toys � solid state and general lighting description the TCS3772 device family provides red, green, blue, and clear (rgbc) light sensing and, when coupled with an external ir led, proximity detection. these devices detect light intensity under a variety of lighting conditions and through a variety of attenuation materials, including dark glass. the proximity detection feature allows a large dynamic range of operation for accurate short distance detection, such as in a cell phone, for detecting when the user positions the phone close to their ear. an internal state machine provides the ability to put the device into a low power state in between proximity and rgbc measurements providing very low average power consumption. the color sensing feature is useful in applications such as led rgb backlight control, solid state lighting, reflected led color sampler, or fluorescent light color temperature detection. with the addition of an ir blocking filter, the device is an excellent ambient light sensor, color temperature monitor, and general purpose color sensor. � � texas advanced optoelectronic solutions inc. 1001 klein road � suite 300 � plano, tx 75074 � (972) 673-0759 package drawing not to scale package fn dual flat no-lead (top view) 6 sda 5 int 4 ldr v dd 1 scl 2 gnd 3 ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 2 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com functional block diagram sda v dd int scl ldr wait control prox adc prox control prox data ir led constant current sink clear adc prox integration upper limit upper limit lower limit lower limit interrupt i 2 c interface gnd red adc green adc blue adc clear data red data green data blue data rgbc control blue green red clear detailed description the TCS3772 is a next-generation digital color light sensor device containing four integrating analog-to-digital converters ( adcs) that integrate currents from photodiodes. the device contains a 3 4 photodiode array used for color measurements and a 1 4 photodiode array used for proximity measurements. integration of all color sensing channels occurs simultaneously. upon completion of the conversion cycle, the conversion result is transferred to the corresponding data registers. the transfers are double-buffered to ensure that the integrity of the data is maintained. communication with the device is accomplished through a fast (up to 400 khz), two-wire i 2 c serial bus for easy connection to a microcontroller or embedded controller. the device provides a separate pin for level-style interrupts. the interrupt feature simplifies and improves system ef ficiency by eliminating the need to poll a sensor for a light intensity value. when interrupts are enabled, an interrupt is generated when the value of a clear channel or proximity conversion is greater than an upper threshold or less than a lower threshold. once the interrupt is asserted, it remains asserted until cleared by the controlling firmware. in addition, a programmable interrupt persistence filter allows the user to set the number of consecutive clear channel or proximity conversions outside of the threshold region that are necessary to trigger an interrupt. interrupt thresholds and persistence filter settings are configured independently for both clear and proximity. proximity detection requires only a single external ir led. an internal led driver can be configured to provide a constant current sink of 12.5 ma, 25 ma, 50 ma, or 100 ma of current. no external current limiting resistor is required. the number of proximity led pulses can be programmed from 1 to 255 pulses. each pulse has a 14- s period. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 3 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com terminal functions terminal type description name no. type description gnd 3 power supply ground. all voltages are referenced to gnd. int 5 o interrupt ? open drain (active low). ldr 4 o led driver for proximity emitter ? open drain. scl 2 i i 2 c serial clock input terminal ? clock signal for i 2 c serial data. sda 6 i/o i 2 c serial data i/o terminal ? serial data i/o for i 2 c . v dd 1 supply voltage. available options device address package ? leads interface description ordering number TCS37721 ? 0x39 fn?6 i 2 c vbus = v dd interface TCS37721fn TCS37723 ? 0x39 fn?6 i 2 c vbus = 1.8 v interface TCS37723fn TCS37725 ? 0x29 fn?6 i 2 c vbus = v dd interface TCS37725fn TCS37727 0x29 fn?6 i 2 c vbus = 1.8 v interface TCS37727fn ? contact taos for availability. absolute maximum ratings over operating free-air temperature range (unless otherwise noted) ? supply voltage, v dd (note 1) 3.8 v . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . input terminal voltage ?0.5 v to 3.8 v . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . output terminal voltage (except ldr) ?0.5 v to 3.8 v . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . output terminal voltage (ldr) ?0.5 v to 3.8 v . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . output terminal current (except ldr) ?1 ma to 20 ma . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . storage temperature range, t stg ?40 c to 85 c . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . esd tolerance, human body model 2000 v . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ? stresses beyond those listed under ?absolute maximum ratings? may cause permanent damage to the device. these are stress ratings only, a nd functional operation of the device at these or any other conditions beyond those indicated under ?recommended operating conditions? is not implied. exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. note 1: all voltages are with respect to gnd. recommended operating conditions min nom max unit supply voltage, v dd (TCS37721 & TCS37725) (i 2 c v bus = v dd ) 2.7 3 3.6 v supply voltage, v dd (TCS37723 & TCS37727) (i 2 c v bus = 1.8 v) 2.7 3 3.3 v operating free-air temperature, t a ?30 70 c ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 4 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com operating characteristics, v dd = 3 v, t a = 25 c (unless otherwise noted) parameter test conditions min typ max unit active ? ldr pulses off 235 330 i dd supply current wait state 65 a i dd supply current sleep state ? no i 2 c activity 2.5 10 a v int sda output low voltage 3 ma sink current 0 0.4 v v ol int, sda output low voltage 6 ma sink current 0 0.6 v i leak leakage current, sda, scl, int pins ?5 5 a i leak leakage current, ldr pin ?5 5 a v scl sda input high voltage TCS37721 & TCS37725 0.7 v dd v v ih scl, sda input high voltage TCS37723 & TCS37727 1.25 v v scl sda input low voltage TCS37721 & TCS37725 0.3 v dd v v il scl, sda input low voltage TCS37723 & TCS37727 0.54 v optical characteristics, v dd = 3 v, t a = 25 c, again = 16 , atime = 0xf6 (unless otherwise noted) (note 1) parameter test red channel green channel blue channel clear channel unit parameter test conditions min typ max min typ max min typ max min typ max unit d = 465 nm note 2 0% 15% 10% 42% 65% 88% 11.0 13.8 16.6 r e irradiance responsivity d = 525 nm note 3 4% 25% 60% 85% 10% 45% 13.2 16.6 20.0 counts/ w/ cm 2 responsivity d = 615 nm note 4 80% 110% 0% 14% 5% 24% 15.6 19.5 23.4 cm 2 notes: 1. the percentage shown represents the ratio of the respective red, green, or blue channel value to the clear channel valu e. 2. the 465 nm input irradiance is supplied by an i ngan light-emitting diode with the following characteristics: dominant wavelength d = 465 nm, spectral halfwidth ? ? = 22 nm. 3. the 525 nm input irradiance is supplied by an i ngan light-emitting diode with the following characteristics: dominant wavelength d = 525 nm, spectral halfwidth ? ? = 35 nm. 4. the 615 nm input irradiance is supplied by a al i ngap light-emitting diode with the following characteristics: dominant wavelength d = 615 nm, spectral halfwidth ? ? = 15 nm. rgbc characteristics, vdd = 3 v, ta = 25 c, again = 16 , aen = 1 (unless otherwise noted) parameter test conditions min typ max unit dark adc count value e e = 0, again = 60 , atime = 0xd6 (100 ms) 0 1 5 counts adc integration time step size atime = 0xff 2.27 2.4 2.56 ms adc number of integration steps (note 5) 1 256 steps adc counts per step (note 5) 0 1024 counts adc count value (note 5) atime = 0xc0 (153.6 ms) 0 65535 counts gi li lti t 1 i 4 3.8 4 4.2 gain scalin g , relative to 1 g ain 16 15 16 16 8 gain scaling , relative to 1 gain setting 16 15 16 16.8 se tti ng 60 58 60 63 note 5: parameter ensured by design and is not tested. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 5 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com proximity characteristics, v dd = 3 v, t a = 25 c, pen = 1 (unless otherwise noted) parameter test conditions min typ max unit i dd supply current ldr pulse on 3 ma adc conversion time step size ptime = 0xff 2.27 2.4 2.56 ms adc number of integration steps (note 1) 1 256 steps adc counts per step (note 1) ptime = 0xff 0 1023 counts adc count value p = 850 nm, e e = 770.1 w/cm 2 , ptime = 0xfb, ppulse = 1 (note 3) 1350 1900 counts adc output responsivity p = 850 nm, ptime = 0xff, ppulse = 1 (note 3) 0.175 0.211 0.247 counts/ w/cm 2 noise (notes 1 2 3) e 0 ptime 0xff ppulse 8 (note 6) 2 %fs noise (notes 1, 2, 3) e e = 0, ptime = 0xff, ppulse = 8 (note 6) 2% f s led pulse count (note 1) 0 255 pulses led pulse period 14.0 s led pulse width ? led on time 6.3 s pdrive = 0 80 106 132 led drive current i s ink sink current @ 1.6 v, pdrive = 1 50 ma led drive current i sink sink current @ 1 . 6 v , ldr pin pdrive = 2 25 ma pdrive = 3 12.5 maximum operating distance (notes 1, 4, 5) pdrive = 0 (100 ma), ppulse = 64 emitter: p = 850 nm, 20 half angle, and 60 mw/sr object: 16 20-inch, 90% reflective kodak gray card (white surface) optics: open view (no glass, no optical attenuation) 30 inches notes: 1. parameter is ensured by design or characterization and is not tested. 2. proximity noise is defined as one standard deviation of 600 samples. 3. proximity noise typically increases as ppulse 4. greater operating distances are achievable with appropriate optical system design considerations. see available t aos application notes for additional information. 5. maximum operating distance is dependent upon emitter and the reflective properties of the object?s surface. 6. proximity noise test was done using the following circuit: TCS3772 v dd 1 � f 22 � 15.0 � 1 34 v dd gnd ldr wait characteristics, v dd = 3 v, t a = 25 c, wen = 1 (unless otherwise noted) parameter test conditions channel min typ max unit wait step size wtime = 0xff 2.27 2.4 2.56 ms wait number of steps (note 7) 1 256 steps note 7: parameter ensured by design and is not tested. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 6 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com ac electrical characteristics, v dd = 3 v, t a = 25 c (unless otherwise noted) parameter ? test conditions min typ max unit f (scl) clock frequency (i 2 c only) 0 400 khz t (buf) bus free time between start and stop condition 1.3 s t (hdsta) hold time after (repeated) start condition. after this period, the first clock is generated. 0.6 s t (susta) repeated start condition setup time 0.6 s t (susto) stop condition setup time 0.6 s t (hddat) data hold time 0 s t (sudat) data setup time 100 ns t (low) scl clock low period 1.3 s t (high) scl clock high period 0.6 s t f clock/data fall time 300 ns t r clock/data rise time 300 ns c i input pin capacitance 10 pf ? specified by design and characterization; not production tested. parameter measurement information start condition stop condition p sda t (susto) t (sudat) t (hddat) t (buf) v ih v il scl t (susta) t (high) t (f) t (r) t (hdsta) t (low) v ih v il ps s figure 1. timing diagrams ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 7 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com typical characteristics figure 2 300 500 700 900 relative responsivity 1100 ? wavelength ? nm photodiode spectral responsivity rgbc 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 0 t a = 25 c normalized to clear @ 605 nm red green clear blue figure 3 300 500 700 900 relative responsivity 1100 ? wavelength ? nm photodiode spectral responsivity proximity 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 0 figure 4 normalized responsivity vs. angular displacement � ? angular displacement ? normalized responsivity 0 0.2 0.4 0.6 0.8 1.0 ?90 ?60 ?30 0 30 60 90 optical axis �� �� figure 5 normalized responsivity vs. angular displacement � ? angular displacement ? normalized responsivity 0 0.2 0.4 0.6 0.8 1.0 ?90 ?60 ?30 0 30 60 90 optical axis �� �� ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 8 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com typical characteristics 0 c 25 c figure 6 normalized i dd vs. v dd and temperature v dd ? v i dd normalized @ 3 v, 25 c 94% 96% 98% 100% 102% 104% 106% 108% 110% 92% 2.7 2.8 2.9 3 3.1 3.2 3.3 75 c 50 c 25 ma 12.5 ma figure 7 ldr voltage ? v ldr current ? ma typical ldr current vs. voltage 50 ma 100 ma 0 0.5 1 1.5 2 2.5 0 20 40 60 80 100 120 140 160 3 figure 8 responsivity temperature coefficient 400 600 800 1000 temperature coefficient ? ppm/ c 100 1000 10,000 500 700 900 ? wavelength ? nm ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 9 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com principles of operation system state machine the TCS3772 provides control of rgbc, proximity detection, and power management functionality through an internal state machine ( figure 9). a fter a power-on-reset, the device is in the sleep mode. as soon as the pon bit is set, the device will move to the start state. it will then continue through the prox, wait, and rgbc states. if these states are enabled, the device will execute each function. if the pon bit is set to 0, the state machine will continue until all conversions are completed and then go into a low power sleep mode. sleep start wait rgbc prox pon = 1 (r 0x00:b0) pon = 0 (r0x 00:b0) figure 9. simplified state diagram note: in this document, the nomenclature uses the bit field name in italics followed by the register number and bit number to allow the user to easily identify the register and bit that controls the function. for example, the power on (pon) is in register 0, bit 0. this is represented as pon (r0x00:b0). ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 10 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com rgbc operation the rgbc engine contains rgbc gai n control (again) and four integrating analog-to-digital converters (adc) for the rgbc photodiodes. the rgbc integration time (atime) impacts both the resolution and the sensitivity of the rgbc reading. integration of all four channels occurs simultaneously and upon completion of the conversion cycle, the results are transferred to the color data registers. this data is also referred to as channel count. the transfers are double-buffered to ensure that invalid data is not read during the transfer. after the transfer, the device automatically moves to the next state in accordance with the configured state machine. again(r 0x0f, b1:0) 1 , 4 , 16 , 60 gain cdatah(r 0x15), cdata(r 0x14) clear adc red adc green adc blue adc clear data red data green data blue data rgbc control blue green red clear rdatah(r 0x17), rdata(r 0x16) gdatah(r 0x19), gdata(r 0x18) bdatah(r 0x1b), bdata(r 0x1a) atime(r0x01) 2.4 ms to 700 ms figure 10. rgbc operation the registers for programming the integration and wait times are a 2?s compliment values. the actual time can be calculated as follows: atime = 256 ? integration time / 2.4 ms inversely, the time can be calculated from the register value as follows: integration time = 2.4 ms (256 ? atime) for example, if a 100-ms integration time is needed, the device needs to be programmed to: 256 ? (100 / 2.4) = 256 ? 42 = 214 = 0xd6 conversely, the programmed value of 0xc0 would correspond to: (256 ? 0xc0) 2.4 = 64 2.4 = 154 ms ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 11 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com proximity detection proximity detection is accomplished by measuring the amount of light energy, generally from an ir led, reflected off an object to determine its distance. the proximity light source, which is external to the TCS3772 device, is driven by the integrated proximity led current driver as shown in figure 6. prox integration prox control prox adc prox led current driver pdatah(r0x019) pdrive(r0x0f, b7:6) prox data external ir led ptime(r0x02) pvalid(r0x13, b1) v dd ppulse(r0x0e) background energy pdatal(r0x018) ldr object figure 11. proximity detection the led current driver, output on the ldr terminal, provides a regulated current sink that eliminates the need for an external current limiting resistor. pdrive sets the drive current to 100 ma, 50 ma, 25 ma. to drive an external light source with more than 100 ma or to minimize on-chip ground bounce, ldr can be used to drive an external p-type transistor, which, in turn, drives the light source. referring to the detailed state machine figure, the led current driver pulses the external ir led as shown in figure 12 during the prox accum state. figure 12 also illustrates that the led on pulse has a fixed width of 6.3 s and period of 14.0 s. so, in addition to setting the proximity drive current, 1 to 255 proximity pulses (ppulse) can be programmed. when deciding on the number of proximity pulses, keep in mind that the signal increases proportionally to ppulse, while noise increases by the square root of ppulse. led on led off ir led pulses background energy reflected ir led + background energy 14.0 � s 6.3 � s figure 12. proximity led current driver waveform figure 11 illustrates light rays emitting from an external ir led, reflecting off an object, and being absorbed by the proximity photodiode. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 12 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com referring again to figure 12, the reflected ir led and the background energy is integrated during the led on time, then during the led off time, the integrated background energy is subtracted from the led on time energy, leaving the external ir led energy to accumulate from pulse to pulse. after the progra mmed number of proximity pulses have been generated, the proximity adc converts and scales the proximity measurement to a 16-bit value, then stores the result in two 8-bit proximity data (pdatax) registers. adc scaling is controlled by the proximity adc conversion time (ptime) which is programmable from 1 to 256 2.4-ms time units. however, depending on the application, scaling the proximity data will equally scale any accumulated noise. therefore, in general, it is recommended to leave ptime at the default value of one 2.4-ms adc conversion time (0xff). once the first proximity cycle has completed, the proximity valid (pvalid) bit in the status register will be set and remain set until the proximity detection function is disabled (pen). for additional information on using the proximity detection function behind glass and for optical system design guidance, please see available taos application notes. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 13 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com interrupts the interrupt feature simplifies and improves system efficiency by eliminating the need to poll the sensor for light intensity or proximity values outside of a user-defined range. while the interrupt function is always enabled and it?s status is available in the status register (0x13), the output of the interrupt state can be enabled using the proximity interrupt enable (pien) or clear interrupt enable (aien) fields in the enable register (0x00). four 16-bit interrupt threshold registers allow the user to set limits below and above a desired light level and proximity range. an interrupt can be generated when the clear data (cdata) is less than the clear interrupt low threshold registers (ailtx) or greater than the clear interrupt high threshold registers (aihtx). likewise, an out-of-range proximity interrupt can be generated when the proximity data (pdata) falls below the proximity interrupt low threshold (piltx) or exceeds the proximity interrupt high threshold (pihtx). it is important to note that the thresholds are evaluated in sequence, first the low threshold, then the high threshold. as a result, if the low threshold is set above the high threshold, the high threshold is ignored and only the low threshold is evaluated. to further control when an interrupt occurs, the device provides a persistence filter. the persistence filter allows the user to specify the number of consecutive out-of-range clear or proximity occurrences before an interrupt is generated. the persistence register (0x0c) allows the user to set the clear persistence (apers) and the proximity persistence (ppers) values. see the persistence register for details on the persistence filter values. once the persistence filter generates an interrupt, it will continue until a special function interrupt clear command is received (see command register). prox adc prox data clear adc clear data prox integration clear upper limit upper limit lower limit lower limit prox persistence pilth(r 0x09), piltl(r0x 08) aihth(r0x 07), aihtl(r0x 06) clear persistence ailth(r 0x05), ailtl(r0x 04) pihth(r 0x0b), pihtl(r 0x0a) ppers(r 0x0c, b7:4) apers(r 0x0c, b3:0) figure 13. programmable interrupt ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 14 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com system timing the system state machine shown in figure 9 provides an overview of the states and state transitions that provide system control of the device. this section highlights the programmable features, which affect the state machine cycle time, and provides details to determine system level timing. when the proximity detection feature is enabled (pen), the state machine transitions through the prox accum, prox wait, and prox adc states. the prox wait time is a fixed 2.4 ms, whereas the prox accum time is determined by the number of proximity led pulses (ppulse) and the prox adc time is determined by the integration time (ptime). the formulas to determine the prox accum and prox adc times are given in the associated boxes in figure 14. if an interrupt is generated as a result of the proximity cycle, it will be asserted at the end of the prox adc state. when the power management feature is enabled (wen), the state machine will transition in turn to the wait state. the wait time is determined by wlong, which extends normal operation by 12 when asserted, and wtime. the formula to determine the wait time is given in the box associated with the wait state in figure 14. when the rgbc feature is enabled (aen), the state machine will transition through the rgbc init and rgbc adc states. the rgbc init state takes 2.4 ms, while the rgbc adc time is dependent on the integration time (atime). the formula to determine rgbc adc time is given in the associated box in figure 14. if an interrupt is generated as a result of the rgbc cycle, it will be asserted at the end of the rgbc adc. prox wait sleep idle wait prox accum rgbc adc rgbc init rgbc prox adc prox ppulse: 0 ~ 255 pulses time: 14.0 s/pulse range: 0 ~ 3.6 ms time: 2.4 ms ptime: 1 ~ 256 steps time: 2.4 ms/step range: 2.4 ms ~ 614 ms wtime: 1 ~ 256 steps wlong = 0 wlong = 1 time: 2.4 ms/step 28.8 ms/step range: 2.4 ms ~ 614 ms 28.8 ms ~ 7.37s time: 2.4 ms atime: 1 ~ 256 steps time: 2.4 ms/step range: 2.4 ms ~ 614 ms !wen & !aen aen !pon wen !aen !pen & wen & aen !wen & aen notes: 1. there is a 2.4 ms warm-up delay if pon is enabled. if pon is not enabled, the device will return to the sleep state as shown. 2. pon, pen, wen, and aen are fields in the enable register (0x00). !pen & !wen & aen pen i 2 c start (note 1) figure 14. detailed state diagram ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 15 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com power management power consumption can be managed with the wait state, because the wait state typically consumes only 65 a of i dd current. an example of the power management feature is given below. with the assumptions provided in the example, average i dd is estimated to be 186 a. table 1. power management system state machine state programmable parameter programmed value duration typical current prox accum ppulse 0x04 0.056 ms prox accum ? led on 0.025 ms (note 1) 109 ma prox accum ? led off 0.031 ms (note 2) 0.235 ma prox wait 2.40 ms 0.235 ma prox adc ptime 0xff 2.40 ms 0.235 ma wait wtime 0xee 43 1 ms 0 065 ma wait wlong 0 43.1 ms 0.065 ma als init 2.40 ms 0.235 ma als adc atime 0xee 43.1 ms 0.235 ma notes: 1. prox accum ? led on time = 6.3 s per pulse 4 pulses = 25.2 s = 0.025 ms 2. prox accum ? led off time = 7.7 s per pulse 4 pulses = 30.9 s = 0.031 ms average i dd current = ((0.025 109) + (0.031 0.235) + (2.40 0.235) + (43.1 0.065) + (43.1 0.263) + (2.40 0.235 2)) / 93 � 186 a keeping with the same programmed values as the example, table 2 shows how the average i dd current is affected by the wait state time, which is determined by wen, wtime, and wlong. note that the worst-case current occurs when the wait state is not enabled. table 2. average i dd current wen wtime wlong wait state average i dd current 0 n/a n/a 0 ms 289 a 1 0xff 0 2.40 ms 279 a 1 0xee 0 43.1 ms 186 a 1 0x00 0 613 ms 82 a 1 0x00 1 7.36 s 67 a ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 16 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com i 2 c protocol interface and control are accomplished through an i 2 c serial compatible interface (standard or fast mode) to a set of registers that provide access to device control functions and output data. the devices support the 7-bit i 2 c addressing protocol. the i 2 c standard provides for three types of bus transaction: read, write, and a combined protocol (figure 15). during a write operation, the first byte written is a command byte followed by data. in a combined protocol, the first byte written is the command byte followed by reading a series of bytes. if a read command is issued, the register address from the previous command will be used for data access. likewise, if the msb of the command is not set, the device will write a series of bytes at the address stored in the last valid command with a register address. the command byte contains either control information or a 5-bit register address. the control commands can also be used to clear interrupts. the i 2 c bus protocol was developed by philips (now nxp). for a complete description of the i 2 c protocol, please review the nxp i 2 c design specificati on at http ://www.i2c?bus.org/references/. a acknowledge (0) n not acknowledged (1) p stop condition r read (1) s start condition sr repeated start condition w write (0) ... continuation of protocol master-to-slave slave-to-master w 7 data byte slave address s 1 aa a 8 11 1 8 command code 1 p 1 ... i 2 c write protocol i 2 c read protocol i 2 c read protocol ? combined format r 7 data slave address s 1 aa a 8 11 1 8 data 1 p 1 ... w 7 slave address slave address s 1 ar a 8 11 1 7 11 command code sr 1 a data a a 81 8 data 1 p 1 ... figure 15. i 2 c protocols ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 17 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com register set the TCS3772 is controlled and monitored by data registers and a command register accessed through the serial interface. these registers provide for a variety of control functions and can be read to determine results of the adc conversions. the register set is summarized in table 3. table 3. register address address resister name r/w register function reset value ?? command w specifies register address 0x00 0x00 enable r/w enables states and interrupts 0x00 0x01 atime r/w rgbc time 0xff 0x02 ptime r/w proximity time 0xff 0x03 wtime r/w wait time 0xff 0x04 ailtl r/w clear interrupt low threshold low byte 0x00 0x05 ailth r/w clear interrupt low threshold high byte 0x00 0x06 aihtl r/w clear interrupt high threshold low byte 0x00 0x07 aihth r/w clear interrupt high threshold high byte 0x00 0x08 piltl r/w proximity interrupt low threshold low byte 0x00 0x09 pilth r/w proximity interrupt low threshold high byte 0x00 0x0a pihtl r/w proximity interrupt high threshold low byte 0x00 0x0b pihth r/w proximity interrupt high threshold high byte 0x00 0x0c pers r/w interrupt persistence filters 0x00 0x0d config r/w configuration 0x00 0x0e ppulse r/w proximity pulse count 0x00 0x0f control r/w gain control register 0x00 0x12 id r device id id 0x13 status r device status 0x00 0x14 cdata r clear adc data low byte 0x00 0x15 cdatah r clear adc data high byte 0x00 0x16 rdata r red adc data low byte 0x00 0x17 rdatah r red adc data high byte 0x00 0x18 gdata r green adc data low byte 0x00 0x19 gdatah r green adc data high byte 0x00 0x1a bdata r blue adc data low byte 0x00 0x1b bdatah r blue adc data high byte 0x00 0x1c pdata r proximity adc data low byte 0x00 0x1d pdatah r proximity adc data high byte 0x00 the mechanics of accessing a specific register depends on the specific protocol used. see the section on i 2 c protocols on the previous pages. in general, the command register is written first to specify the specific control/status register for following read/write operations. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 18 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com command register the command registers specifies the address of the target register for future write and read operations. table 4. command register 6 754 addr/sf 2 310 command cmd type reset 0x00 field bits description cmd 7 select command register. must write as 1 when addressing command register. type 6:5 selects type of transaction to follow in subsequent data transfers: field value integration time 00 repeated byte protocol transaction 01 auto-increment protocol transaction 10 reserved ? do not use 11 special function ? see description below byte protocol will repeatedly read the same register with each data access. block protocol will provide auto-increment function to read successive bytes. addr/sf 4:0 address field/special function field. depending on the transaction type, see above, this field either specifies a special function command or selects the specific control?status?register for following write and read transactions. the field values listed below apply only to special function commands: field value read value 00101 proximity interrupt clear 00110 clear channel interrupt clear 00111 proximity and clear interrupt clear other reserved ? do not write the als and proximity interrupt clear special functions clear any pending interrupt(s) and are self clearing. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 19 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com enable register (0x00) the enable register is used primarily to power the TCS3772 device on and off, and enable functions and interrupts as shown in table 5. table 5. enable register 6 754 pon 2 310 enable reserved resv aien reset 0x00 aen pien wen pen field bits description reserved 7:6 reserved. write as 0. pien 5 proximity interrupt enable. when asserted, permits proximity interrupts to be generated. aien 4 clear channel interrupt enable. when asserted, permits clear interrupts to be generated. wen 3 wait enable. this bit activates the wait feature. writing a 1 activates the wait timer. writing a 0 disables the wait timer. pen 2 proximity enable. this bit activates the proximity function. writing a 1 enables proximity. writing a 0 disables proximity. aen 1 rgbc enable. this bit actives the two-channel adc. writing a 1 activates rgbc. writing a 0 disables rgbc. pon 0 power on. this bit activates the internal oscillator to permit the timers and adc channels to operate. writing a 1 activates the oscillator. writing a 0 disables the oscillator. during reads and writes over the i 2 c interface, this bit is temporarily overridden and the oscillator is enabled, independent of the state of pon. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 20 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com rgbc time register (0x01) the rgbc timing register controls the internal integration time of the rgbc clear and ir channel adcs in 2.4-ms increments. upon power up, the rgbc time register is set to 0xff. table 6. rgbc time register field bits description atime 7:0 value integ_cycles time max count 0xff 1 2.4 ms 1024 0xf6 10 24 ms 10240 0xd6 42 101 ms 43008 0xad 64 154 ms 65535 0x00 256 614 ms 65535 proximity time register (0x02) the proximity timing register controls the integration time of the proximity adc in 2.4 ms increments. upon power up, the proximity time register is set to 0xff. it is recommended that this register be programmed to a value of 0xff (1 integration cycle). max prox count = ((256 ? ptime) 1024)) ? 1 up to a maximum of 65535 table 7. proximity time register field bits description ptime 7:0 value integ_cycles time max count 0xff 1 2.4 ms 1023 wait time register (0x03) wait time is set 2.4 ms increments unless the wlong bit is asserted in which case the wait times are 12 longer. wtime is programmed as a 2?s complement number. upon power up, the wait time register is set to 0xff. table 8. wait time register field bits description wtime 7:0 register value wait time time (wlong = 0) time (wlong = 1) 0xff 1 2.4 ms 0.029 sec 0xab 85 204 ms 2.45 sec 0x00 256 614 ms 7.4 sec note: the proximity wait time register should be configured before pen and/or aen is/are asserted. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 21 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com clear interrupt threshold registers (0x04 ? 0x07) the clear interrupt threshold registers provides the values to be used as the high and low trigger points for the comparison function for interrupt generation. if the value generated by the clear channel crosses below the lower threshold specified, or above the higher threshold, an interrupt is asserted on the interrupt pin. table 9. clear interrupt threshold registers register address bits description ailtl 0x04 7:0 clear channel low threshold lower byte ailth 0x05 7:0 clear channel low threshold upper byte aihtl 0x06 7:0 clear channel high threshold lower byte aihth 0x07 7:0 clear channel high threshold upper byte proximity interrupt threshold registers (0x08 ? 0x0b) the proximity interrupt threshold registers provide the values to be used as the high and low trigger points for the comparison function for interrupt generation. if the value generated by proximity channel crosses below the lower threshold specified, or above the higher threshold, an interrupt is signaled to the host processor. table 10. proximity interrupt threshold register s register address bits description piltl 0x08 7:0 proximity adc channel low threshold lower byte pilth 0x09 7:0 proximity adc channel low threshold upper byte pihtl 0x0a 7:0 proximity adc channel high threshold lower byte pihth 0x0b 7:0 proximity adc channel high threshold upper byte ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 22 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com persistence filter register (0x0c) the persistence filter register controls the filtering interrupt capabilities of the device. configurable filtering is provided to allow interrupts to be generated after each integration cycle or if the integration has produced a result that is outside of the values specified by the threshold register for some specified amount of time. separate filtering is provided for proximity and the clear channel. table 11. persistence filter register 6 754 apers 2 310 pers ppers reset 0x00 field bits description ppers 7:4 proximity interrupt persistence. controls rate of proximity interrupt to the host processor. field value interrupt persistence function 0000 every proximity cycle generates an interrupt 0001 1 proximity value out of range 0010 2 consecutive proximity values out of range ... ... 1111 15 consecutive proximity values out of range apers 3:0 clear interrupt persistence. controls rate of clear channel interrupt to the host processor. field value interrupt persistence function 0000 every rgbc cycle generates an interrupt 0001 1 clear channel value outside of threshold range 0010 2 clear channel consecutive values out of range 0011 3 clear channel consecutive values out of range 0100 5 clear channel consecutive values out of range 0101 10 clear channel consecutive values out of range 0110 15 clear channel consecutive values out of range 0111 20 clear channel consecutive values out of range 1000 25 clear channel consecutive values out of range 1001 30 clear channel consecutive values out of range 1010 35 clear channel consecutive values out of range 1011 40 clear channel consecutive values out of range 1100 45 clear channel consecutive values out of range 1101 50 clear channel consecutive values out of range 1110 55 clear channel consecutive values out of range 1111 60 clear channel consecutive values out of range ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 23 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com configuration register (0x0d) the configuration register sets the wait long time. table 12. configuration register 6 7542 310 config reserved wlong reset 0x00 reserved field bits description reserved 7:2 reserved. write as 0. wlong 1 wait long. when asserted, the wait cycles are increased by a factor 12 from that programmed in the wtime register. reserved 0 reserved. write as 0. proximity pulse count register (0x0e) the proximity pulse count register sets the number of proximity pulses that will be transmitted. table 13. proximity pulse count register 6 7542 310 ppulse ppulse reset 0x00 field bits description ppulse 7:0 proximity pulse count. specifies the number of proximity pulses to be generated. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 24 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com control register (0x0f) the control register provides eight bits of miscellaneous control to the analog block. table 14. control register 6 7542 310 control pdrive reset 0x00 reserved again field bits description pdrive 7:6 proximity led drive strength. field value led strength 00 100 ma 01 50 ma 10 25 ma 11 12.5 ma reserved 5:2 reserved. write bits as 0 again 1:0 rgbc gain control. field value rgbc gain value 00 1 gain 01 4 gain 10 16 gain 11 60 gain id register (0x12) the id register provides the value for the part number. the id register is a read-only register. table 15. id register 6 7542 310 id id reset id field bits description id 7:0 part number identification 0x40 = TCS37721 & TCS37725 id 7:0 part number identification 0x49 = TCS37723 & TCS37727 ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 25 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com status register (0x13) the status register provides the internal status of the device. this register is read only. table 16. status register 6 754 avalid 2 310 status reserved resv aint reset 0x00 reserved pint pvalid field bit description reserved 7:6 reserved. pint 5 proximity interrupt. aint 4 clear channel interrupt. reserved 3:2 reserved. pvalid 1 proximity valid. indicates that a proximity cycle has completed since pen was asserted. avalid 0 rgbc valid. indicates that the rgbc cycle has completed since aen was asserted. rgbc channel data registers (0x14 ? 0x1b) clear, red, green, and blue data is stored as 16-bit values. to ensure the data is read correctly, a two-byte read i 2 c transaction should be used with a read word protocol bit set in the command register. with this operation, when the lower byte register is read, the upper eight bits are stored into a shadow register, which is read by a subsequent read to the upper byte. the upper register will read the correct value even if additional adc integration cycles end between the reading of the lower and upper registers. table 17. adc channel data registers register address bits description cdata 0x14 7:0 clear data low byte cdatah 0x15 7:0 clear data high byte rdata 0x16 7:0 red data low byte rdatah 0x17 7:0 red data high byte gdata 0x18 7:0 green data low byte gdatah 0x19 7:0 green data high byte bdata 0x1a 7:0 blue data low byte bdatah 0x1b 7:0 blue data high byte proximity data registers (0x1c ? 0x1d) proximity data is stored as a 16-bit value. to ensure t he data is read correctly, a two-byte read i 2 c transaction should be used with a read word protocol bit set in the command register. with this operation, when the lower byte register is read, the upper eight bits are stored into a shadow register, which is read by a subsequent read to the upper byte. the upper register will read the correct value even if additional adc integration cycles end between the reading of the lower and upper registers. table 18. pdata register s register address bits description pdata 0x1c 7:0 proximity data low byte pdatah 0x1d 7:0 proximity data high byte ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 26 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com application information: hardware led driver pin with proximity detection in a proximity sensing system, the ir led can be pulsed by the TCS3772 with more than 100 ma of rapidly switching current, therefore, a few design considerations must be kept in mind to get the best performance. the key goal is to reduce the power supply noise coupled back into the device during the led pulses. the first recommendation is to use two power supplies; one for the device v dd and the other for the ir led. in many systems, there is a quiet analog supply and a noisy digital supply. by connecting the quiet supply to the v dd pin and the noisy supply to the led, the key goal can be meet. place a 1- f low-esr decoupling capacitor as close as possible to the v dd pin and another at the led anode, and a 22-f capacitor at the output of the led voltage regulator to supply the 100-ma current surge. TCS3772 int sda scl v dd ldr 1 � f voltage regulator voltage regulator 22 � f * cap value per regulator manufacturer recommendation ir led gnd v bus r p r p r pi c* 1 � f figure 16. proximity sensing using separate power supplies if it is not possible to provide two separate power supplies, the device can be operated from a single supply. a 22- resistor in series with the v dd supply line and a 1- f low esr capacitor effe ctively filter any power supply noise. the previous capacitor placement considerations apply. TCS3772 int sda scl v dd ldr 1 � f voltage regulator 22 � f ir led gnd v bus r p r p r pi 1 � f 22 � figure 17. proximity sensing using single power supply v bus in the above figures refers to the i 2 c bus voltage which is either v dd or 1.8 v. be sure to apply the specified i 2 c bus voltage shown in the available options table for the specific device being used. the i 2 c signals and the interrupt are open-drain outputs and require pull?up resistors. the pull-up resistor (r p ) value is a function of the i 2 c bus speed, the i 2 c bus voltage, and the capacitive load. the taos evm running at 400 kbps, uses 1.5-k resistors. a 10-k pull-up resistor (r pi ) can be used for the interrupt line. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 27 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com application information: hardware pcb pad layout suggested land pattern based on the ipc?7351b generic requirements for surface mount design and land pattern standard (2010) for the small outline no-lead (son) package is shown in figure 18. 0.35 6 2.70 1.20 0.65 0.65 1.20 top view notes: a. all linear dimensions are in millimeters. b. this drawing is subject to change without notice. figure 18. suggested fn package pcb layout ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 28 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com package information package fn dual flat no-lead 650 bsc top view side view bottom view lead fre e pb 300 50 2000 75 2400 75 pin 1 pin 1 end view 650 50 pin out top view 750 100 295 nominal 406 10 c l of solder contacts and photodiode array area (note b) c l of solder contacts of photodiode array area (note b) c l 125 nominal 6 sda 5 int 4 ldr v dd 1 scl 2 gnd 3 496 10 photodiode active area (note c) notes: a. all linear dimensions are in micrometers. b. the die is centered within the package within a tolerance of 75 m. c. double-half etch (dhe) is 97 20 m. non-dhe is 203 8 m. d. package top surface is molded with an electrically nonconductive clear plastic compound having an index of refraction of 1.55 . e. contact finish is copper alloy a194 with pre-plated nipdau lead finish. f. this package contains no lead (pb). g. this drawing is subject to change without notice. figure 19. package fn ? dual flat no-lead packaging configuration ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 29 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com carrier tape and reel information top view detail a 2.21 0.05 a o 0.254 0.02 5 max 4.00 8.00 3.50 0.05 1.50 4.00 2.00 0.05 + 0.30 ? 0.10 1.75 b b aa 0.50 0.05 detail b 2.61 0.05 b o 5 max 0.83 0.05 k o notes: a. all linear dimensions are in millimeters. dimension tolerance is 0.10 mm unless otherwise noted. b. the dimensions on this drawing are for illustrative purposes only. dimensions of an actual carrier may vary slightly. c. symbols on drawing a o , b o , and k o are defined in ansi eia standard 481?b 2001. d. each reel is 178 millimeters in diameter and contains 3500 parts. e. taos packaging tape and reel conform to the requirements of eia standard 481?b. f. in accordance with eia standard, device pin 1 is located next to the sprocket holes in the tape. g. this drawing is subject to change without notice. figure 20. package fn carrier tape ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 30 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com soldering information the fn package has been tested and has demonstrated an ability to be reflow soldered to a pcb substrate. the solder reflow profile describes the expected maximum heat exposure of components during the solder reflow process of pr oduct on a pcb. temperature is measured on top of component. the components should be limited to a maximum of three passes through this solder reflow profile. table 19. solder reflow profile parameter reference TCS3772 average temperature gradient in preheating 2.5 c/sec soak time t soak 2 to 3 minutes time above 217 c (t1) t 1 max 60 sec time above 230 c (t2) t 2 max 50 sec time above t peak ?10 c (t3) t 3 max 10 sec peak temperature in reflow t peak 260 c temperature gradient in cooling max ?5 c/sec t 3 t 2 t 1 t soak t 3 t 2 t 1 t peak not to scale ? for reference only time (sec) temperature ( c) figure 21. solder reflow profile graph ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 31 the lumenology � company � � copyright � 2012, taos inc. www.taosinc.com storage information moisture sensitivity optical characteristics of the device can be adversely affected during the soldering process by the release and vaporization of moisture that has been previously absorbed into the package. to ensure the package contains the smallest amount of absorbed moisture possible, each device is baked prior to being dry packed for shipping. devices are dry packed in a sealed aluminized envelope called a moisture-barrier bag with silica gel to protect them from ambient moisture during shipping, handling, and storage before use. shelf life the calculated shelf life of the device in an unopened moisture barrier bag is 12 months from the date code on the bag when stored under the following conditions: shelf life: 12 months ambient t emperature: < 40 c relative humidity: < 90% rebaking of the devices will be required if the devices exceed the 12 month shelf life or the humidity indicator card shows that the devices were exposed to conditions beyond the allowable moisture region. floor life the fn package has been assigned a moisture sensitivity level of msl 3. as a result, the floor life of devices removed from the moisture barrier bag is 168 hours from the time the bag was opened, provided that the devices are stored under the following conditions: floor life: 168 hours ambient t emperature: < 30 c relative humidity: < 60% if the floor life or the temperature/humidity conditions have been exceeded, the devices must be rebaked prior to solder reflow or dry packing. rebaking instructions when the shelf life or floor life limits have been exceeded, rebake at 50 c for 12 hours. ams ag technical content still valid
TCS3772 color light-to-digital converter with proximity sensing taos145b ? september 2012 32 � � copyright � 2012, taos inc. the lumenology � company www.taosinc.com production data ? information in this document is current at publication date. products conform to specifications in accordance with the terms of texas advanced optoelectronic solutions, inc. standard warranty. production processing does not necessarily include testing of all parameters. lead-free (pb-free) and green statement pb-free (rohs) taos? terms lead-free or pb-free mean semiconductor products that are compatible with the current rohs requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. where designed to be soldered at high temperatures, taos pb-free products are suitable for use in specified lead-free processes. green (rohs & no sb/br) taos defines green to mean pb-free (rohs compatible), and free of bromine (br) and antimony (sb) based flame retardants (br or sb do not exceed 0.1% by weight in homogeneous material). important information and disclaimer the information provided in this statement represents taos? knowledge and belief as of the date that it is provided. taos bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. efforts are underway to better integrate information from third parties. taos has taken and continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals. taos and taos suppliers consider certain information to be proprietary, and thus cas numbers and other limited information may not be available for release. notice texas advanced optoelectronic solutions, inc. (t aos) reserves the right to make changes to the products contained in this document to improve performance or for any other purpose, or to discontinue them without notice. customers are advised to contact taos to obtain the latest product information before placing orders or designing taos products into systems. taos assumes no responsibility for the use of any products or circuits described in this document or customer product design, conveys no license, either expressed or implied, under any patent or other right, and makes no representation that the circuits are free of patent infringement. taos further makes no claim as to the suitability of its products for any particu lar purpose, nor does taos assume any liability arising out of the use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. texas advanced optoelectronic solutions, inc. products are not designed or intended for use in critical applications in which the failure or malfunction of the taos product may result in personal injury or death. use of t aos products in life support systems is expressly unauthorized and any such use by a customer is completely at the customer?s risk. lumenology, taos, the taos logo, and texas advanced optoelectronic solutions are registered trademarks of texas advanced optoelectronic solutions incorporated. ams ag technical content still valid
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