View T6B70BFNG_8800501.PDF datasheet online --- IC-ON-LINE

Datasheet File OCR Text:

T6B70BFNG 2008-05-15 1 toshiba cmos digital integrat ed ci rcuit silicon monolithic T6B70BFNG interface ic for hot water dispensers the T6B70BFNG is designed to be used mainly as an interface ic for communication between hot water dispensers and the corresponding controller unit, and comes equipped with a two channel 4-bit d/a converter, pseudo sine wave generator and an external analog signal detection circuit. features ? built-in two channel 4-bit d/a converter (opposite polarities) ? built-in pseudo sine wave generator (external clock 1/16 frequency divider) ? built-in external analog signal detection/non-detection circuit ? built-in two channel analog switch block diagram pin assignment diagram weight: 0.07 g (typ.) oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 1 2 3 4 5 6 7 8 16 15 14 13 12 11 10 9 T6B70BFNG cycle measurement counter oscin 16 frequency divider unit pseudo sine wave generator waveform initialization block 4-bit d/a converter modulation control circuit zero crossing waveform shaping circuit amp input circuit reset circuit detection/non-detection judgment circuit output buffer 1 2 3 4 14 15 11 10 5 oscout fout /sctl sw1in sw1out sw2in sw2out /reset sout + 13 sout ? 12 v dd 16 a mpin 7 a mpout 6 v ss 8 /dout 9 4-bit d/a converter 0c 180c
T6B70BFNG 2008-05-15 2 pin functions pin no. symbol input/output function 1 oscin input pins connected to oscillation 2 oscout output pins connected to oscillation 3 fout output output pin for oscillation waveform shaping circuit 4 /sctl input modulation control signal input pin 5 /reset input reset signal input pin 6 ampout output amplifier signal output pin 7 ampin input amplifier signal input pin 8 v ss ? device ground pin (0 v) 9 /dout output output pin for amplifier input signal detector 10 sw2out output output pin on analog sw2 side 11 sw2in input input pin on analog sw2 side 12 sout ? output pseudo sine wave (opposite polarity of sout + output) output pin 13 sout + output pseudo sine wave output pin 14 sw1in input input pin on analog sw1 side 15 sw1out output output pin on analog sw1 side 16 v dd ? device power supply pin ( + 5 v) the equivalent circuit diagrams provid ed in the above table are given to facilitate understanding in designing the external circuitry but are not intended to accurately represent the internal circuitry.
T6B70BFNG 2008-05-15 3 functions 1. pseudo sine wave generator and 4-bit d/a converters (transmission block) the pseudo sine wave signal with fosc/16 frequency is output from the pseudo sine wave output pins (sout+ and sout ? ). the output polarity of sout + and sout ? are the opposite. the transmission block (pseudo sine wave generator and 4-bit d/a converter are as shown below (sout + pin side): the data of the pseudo sine wave genera tor is output in the following sequence: 0 1 3 6 9 c e f f e c 9 6 3 1 0 (hexadecimal) therefore, when there is no load, th e pseudo sine waveform of the posi tive and negative output is like a staircase (as illustrated above). an analog switch is built-in so that the driver output buffer connects to the transmission line only during transmission. however, an emitter follower circuit is extern ally connected to the driver output buffer. the phase difference between the positive and negative output is within 180 5 (to account for fluctuation in the pseudo sine wave output phase). pseudo sine wave generator r r msb r r r r r r lsb r r r 2r sout + pin v ss f osc rst sout + sout ? f f e e c c 9 9 6 6 3 3 1 1 0 0 250 khz fsin @f osc = 4 mhz
T6B70BFNG 2008-05-15 4 2. amplifier input circuit and signal detection/non-detection circuit (reception block) the modulation signal input block is equipped with high and a low comparator to detect only when the external sine wave signal?s amplitude is above the defi ned threshold. in this way, signals with amplitudes lower than the specified threshold (e.g., noise signals) are prevented from being mistakenly detected as sine waves. the detection frequency range (frequency window) is de termined by the divider ratio 1/17 to 1/15 of f osc . detection/non-detection confirmation conditions are such that when the signals within the specified frequency range are detected (or not detected) in successi on, the signals are controlled. it takes about 9 to 15 waves (based on f osc 1/16 frequency) to make detection/non-detection confirmation in this manner. vh vl input sensitivity v pp reception detected amp in input sine waveform reception non-detected reception non-detected reception non-detected vh vl vbias held at high vbias < vl vbias > vh vh > vbias > vl vh > vbias > vl ampout output timing (/reset = l) ampout held at low ampout truth table va vb ampout vbias > vh l h l vh > vbias > vl h h hold vbias < vl h l h 7 ampin pin r1 r2 r3 r4 v ss reference voltage v dd vh + ? vbias reference voltage vl high comparator va low comparator vb r s q q + ? cycle measurement counter detection /non-detection judgment circuit 9 /dout pin 6 ampout pin v dd v ss apu apu reset
T6B70BFNG 2008-05-15 5 3. transmission block function and timing when the modulation control input (/sctl) is in high-level, the pseudo sine wave output is held at 0 phase of the pseudo sine wave. when the modulation contro l input changes from high-level to low-level, the pseudo sine wave output (sout + ) initially outputs from -90 (sout ? outputs from + 90). the time required to turn on in this case is as follows: td (on) < 500 ns when modulation control input changes from low-level to high-level, the phase is fo rcibly held at 0 (the pseudo sine wave output is stopped), regardless of the phase of the pseudo sine wave output. the time required to turn off in this case is as follows: td (off) < 1 s 4. reception block function and timing once it is okay to receive the amplifier input signal , the time it takes for the /dout pin to changes from high to low (t (det)) is about 9 to 15 waves (based on f osc 1/16 frequency). this condition is only valid when the cyclic input signal within the range specified by the freque ncy window is detected (or not detected) in continuation. note 1: you are free to use any kind of communication prot ocol you wish, however be sure to configure a time of carrier wave 15 waves or more for both when there are and aren?t signals. /sctl td (on) td (off) sout + pseudo sine wave output (sout ? is the opposite polarity) amplifier input t (det) t (det) /dout
T6B70BFNG 2008-05-15 6 timing chart (sout + = sw1in, sw1out, sout ? = sw2in, sw2out) v dd /reset oscin (4 mhz) ampin (250 khz) v pp transmitting /dout /sctl td (on) td (off) sout + fsin tdet tdet fout x ampout v opp sout ? x x x x sw1in sw1out sw2in sw2out receiving
T6B70BFNG 2008-05-15 7 absolute maximum ratings (ta = 25 1.5c) characteristics symbol rating unit power supply voltage v dd ? 0.3 to 6.0 v input voltage vi ? 0.3 to v dd + 0.3 v input peak current iik ? 20 to 20 ma operating temperature t opr ? 20 to 80 c storage temperature t stg ? 55 to 125 c power dissipation p d (note 1) 0.82 w the absolute maximum ratings of a semiconductor de vice are a set of ratings that must not be exceeded, even for a moment. do not exceed any of these ratings. exceeding the rating(s) may cause device breakdown, damage or deterioration, and may result injury by explosion or combustion. note 1: power dissipation decreases approximately 8.2 mw per degree (centigrade).
T6B70BFNG 2008-05-15 8 electrical characteristics (unless otherwise specified, v dd = 5.0 v, v ss = 0 v, f osc = 4 mhz and ta = ? 20 to 80c) characteristics symbol te s t circuit test condition min typ. max unit v dd pin (pin 16) operating voltage v dd ? 4.5 5.0 5.5 v current consumption i dd 1 when there is no load; f osc = 4 mhz ? ? 10 ma oscin pin (pin 1) and oscout pin (pin 2) oscillation frequency fosc 2 1 4 10 mhz high level vihosc 3 0.7 v dd ? v dd input voltage low level vilosc 3 v ss ? 0.3 v dd v high level iihrosc 4 v in = 5 v, ta = 25c 3.2 6.58 13.2 input current low level iilrosc 4 v in = 0 v, ta = 25c ?3.2 ?6.58 ?13.2 a high level vohosc 3 ioh = ? 0.1 ma v dd ? 1 ? v dd output voltage low level volosc 4 iol = + 0.1 ma v ss ? v ss + 0.6 v /reset pin (5 pin) low to high input switching level vihrst 5 0.65 v dd ? v dd v high to low input switching level vilrst 5 v ss ? 0.35 v dd v high-level input current iihrst 6 v in = v dd ?10 ? 10 a pull-up resistance 1 iilrrst1 7 v in = v ss , ta = 25c 9 15 21 k pull-up resistance 2 iilrrst2 7 v in = v ss , ta = ? 20 to 80c 6.3 ? 27.3 k /sctl pin (pin 4) low to high input switching level vihsctl 8 0.65 v dd ? v dd v high to low input switching level vilsctl 8 v ss ? 0.35 v dd v high level iihsctl 9 v in = v dd ?1 ? 1 input current low level iilsctl 9 v in = v dd ?1 ? 1 a fout pin (pin 3) high level vohfout 10 ioh = ? 1.0 ma v dd ? 1 ? v dd output voltage low level volfout 11 iol = + 1.0 ma v ss ? v ss + 0.6 v /dout pin (pin 9) high level vohdout 12 ioh = ? 1.0 ma v dd ? 1.0 ? v dd output voltage low level voldout 13 iol = + 1.0 ma v ss ? v ss + 0.6 v non-reception to reception detection time tdet1 19 f osc = 4 mhz, ampin = 250 khz time it takes for /dout to change from high to low 40 ? 60 s reception to non-reception detection time tdet2 19 f osc = 4 mhz, ampin = 250 khz time it takes for /dout to change from low to high 36 ? 56 s note: the direction of current flow should be + (sink) when flowing into the ic and ? (drain) when flowing out of the ic.
T6B70BFNG 2008-05-15 9 characteristics symbol te s t circuit test condition min typ. max unit ampin pin (pin 7) input dynamic range vampin 14 v ss ? v dd v pull-up resistance 1 iilrapu1 15 v in = v ss , ta = 25c 11.6 19.4 27.2 k pull-up resistance 2 iilrapu2 15 v in = v ss , ta = ? 20 to 80c 7 ? 38 k pull-down resistance 1 iihrapd1 16 v in = v dd , ta = 25c 5.9 9.8 13.7 k pull-down resistance 2 iihrapd2 16 v in = v dd , ta = ? 20 to 80c 3 ? 19.2 k amplifier input bias voltage vbias 17 no load (design target) 1.54 1.63 1.71 v amplifier input sensitivity vpp 18 no load, receivable amplitude range is 250 khz, when sine wave signal is applied. (design target) 0.3 ? 0.45 v detection frequency range deton 19 f osc = 4 mhz 236 ? 266 khz non-detection frequency (low frequency) detoff1 19 f osc = 4 mhz ? ? 236 khz non-detection frequency (high frequency) detoff2 19 f osc = 4 mhz 266 ? ? khz sw1in pin (pin 14) and sw1out pin (pin 15) analog switch input voltage vinasw1 ? v ss ? v dd v analog switch output voltage voutasw1 ? v ss ? v dd v off-leak current of analog switch 1 ioffasw1 20 /sctl = h, sw1in = v dd , sw1out = v ss ?1 ? 1 a on-resistance of analog switch 1 ronasw1 21 /sctl = l, sw1in = 5 v, sw1out = 0 v current measure 35 ? 105 sw2in pin (pin 11) and sw2out pin (pin 10) analog switch input voltage vinasw2 ? v ss ? v dd v analog switch output voltage voutasw2 ? v ss ? v dd v off-leak current of analog switch 2 ioffasw2 20 /sctl = h, sw2in = v dd , sw2out = v ss ?1 ? 1 a on-resistance of analog switch 2 ronasw2 21 /sctl = l, sw2in = 5 v, sw2out = 0 v current measure 35 ? 105 sout + pin (13 pin), sout ? pin (12 pin) output voltage vopp 22 maximum voltage value when there is no load 0.85 v dd ? v dd v pseudo sine wave output frequency fsin 23 f osc = 4 mhz ? 250 ? khz pseudo sine wave output start time tdon 23 /sctl = h l ? ? 500 ns pseudo sine wave output stop time tdoff 23 /sctl = l h ? ? 1 s equivalent output impedance routsin 24 no load 2.8 4 5.2 k note: the direction of current flow should be + (sink) when flowing into the ic and ? (drain) when flowing out of the ic.
T6B70BFNG 2008-05-15 10 test circuit (1) current consumption (2) oscillation frequency (3) high-level input voltage (4) high-level input current low-level input voltage low-level input current high-level output voltage low-level output voltage (5) low to high input switching level (6) high-level input current high to low input switching level oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 1 to 10 mhz pg 5 v f osc monitor 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset a mpout a mpin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 4 mhz pg a 5 v icc 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 vihosc vilosc oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout vohosc 5 v v ioh ? 0.1 ma oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 iihrosc iilrosc 5 v iol + 0.1 ma vin a v volout oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 5 v monitor monitor 4 mhz pg vihrst vilrst 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout a 5 v iihrst vin 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12
T6B70BFNG 2008-05-15 11 (7) pull-up resistance 1 (8) low to high input switching level pull-up resistance 2 high to low input switching level (9) high-level input current (10) high-level output voltage low-level input current (11) low-level output voltage (12) high-level output voltage oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout a iilrrst1 iilrrst2 5 v 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 4 mhz pg 5 v vihsctl vilsctl monitor monitor 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout a iihsctl iilsctl 5 v vin 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 5 v ioh ? 0.1 ma v vohfout 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 5 v iol + 1.0 ma v volfout 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 4 mhz pg 5 v vohdout v ioh ? 1.0 ma 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12
T6B70BFNG 2008-05-15 12 (13) low-level output voltage (14) input dynamic range (15) pull-up resistance 1 (16) pull-down resistance 1 pull-up resistance 2 pull-down resistance 2 (17) amplifier input bias voltage (18) amplifier input sensitivity oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 4 mhz pg 5 v iol +1.0ma voldout v 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 4 mhz pg 5 v monito r vampin 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 5 v iilrapu1 iilrapu2 a 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 5 v iihrapd1 iihrapd2 a vin 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 5 v vbias v oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 4 mhz pg 5 v monito r 250 khz sin wave vp-p 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12
T6B70BFNG 2008-05-15 13 (19) detection frequency range (20) off-leak current of analog switch 1 non-detection frequency (low frequency) off-leak current of analog switch 2 non-detection frequency (high frequency) non-reception to reception detection time reception to non-reception detection time (21) on-resistance of analog switch 1 (22) output voltage on-resistance of analog switch 2 (23) pseudo sine wave output frequency (24) equivalent output impedance pseudo sine wave output start time pseudo sine wave output stop time 200 to 300 khz pg deton detoff1 detoff2 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 4 mhz pg 5 v monitor tdet1 tdet2 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 5 v ioffasw1 5 v a ioffasw2 5 v a 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 5 v a ronasw1 a ronasw2 5 v 5 v 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 vopp 5 v 4 mhz pg v v vopp oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 5 v monitor monitor fsin degsout tdon tdoff 4 mhz pg 1 2 3 4 8 7 6 5 16 15 14 13 9 10 11 12 oscin oscout fout /sctl /reset ampout ampin v ss v dd sw1out sw1in sout+ sout? sw2in sw2out /dout 5 v 4 mhz pg a routsin a routsin 5 v 5 v
T6B70BFNG 2008-05-15 14 ic marking specification lot code 6b70bg weekly code
T6B70BFNG 2008-05-15 15 toshiba cmos ssop embossed taping - common specifications 1. applicable scope this specification defines the embossed taping packag e specifications and related items for toshiba flat package cmos ics. 2. specifications 2.1 tape form and dimensions unit: mm package code a0 b0 p1 t k t2 d1 ssop16-p-225-0.65b 6.8 0.1 5.5 0.1 8.0 0.1 0.3 0.1 2.15 0.3 2.45 max 1.65 0.1 note: the maximum value of k dimensions is adopted in the table though the one that the tape thickness was added to k dimensions becomes t2 dimensions. (the tape thickness is considered within the range of the allowance of k dimensions.) 2.2 seal tape dimensions unit: mm tape width tape thickness ssop16-p-225-0.65b 13.5 0.06 direction of feed composition explanation chart (example) top cover tape emboss carrier tape sending hole emboss equipment hole
T6B70BFNG 2008-05-15 16 2.3 reel form and dimensions unit: mm w dimension ssop16-p-225-0.65b 16.4 + 2.0 ? 0 (a) bar code label (see page 18) 2.4 insertion direction 2.5 tape minimum bending radius the strength of the seal tape shall not change even when an ic is in serted into the tape and the tape is bent 40 mm. in addition, the tape and inserted ic shall not change under the corresponding conditions. 2.6 seal tape peeling strength the seal tape shall maintain a peeling strength of 0.1 n (10 gf) when tape bonding surface is at 165 to 180 and being pulled at a speed of 300 mm per minute. however, the seal tape shall not fracture or break when it is being peeled. ( unit: mm ) (a) 13 0.5 330 2 80 2 t t = 3.0 max w 2.5 2 0.5 r1.0 21 0.8 pin 1 type l (el) direction of feed 165 to 180 300 mm/minute
T6B70BFNG 2008-05-15 17 2.7 leader and trailer sections of the tape empty cavities shall be created in leader and traile r sections of the tape in which ics shall not be inserted as specified below: seal tape carrier tape leader section minimum of 500 mm minimum of 400 mm trailer section minimum of 400 mm minimum of 400 mm 2.8 ic insertion failure ratio item tolerated ratio comments consecutive insertion failure none non-consecutive insertion failure 0.1 % or less (per reel) does not apply to the empty cavities in the leading and trailing sections of the tape. 3. standard packaging unit the standard packaging unit for one reel of tape shall be 2000 units. 4. labeling the reel shall be labeled with the following: 1) product name 2) quantity 3) lot no. start end seal tape carrier tape trailer section empty cavities in which ics shall not be inserted empty cavities in which ics shall not be inserted hub end leader section
T6B70BFNG 2008-05-15 18 5. boxing internal packing external packing bar code label (6) silica gel (5) polyethylene bag (after storing the reel in the bag with the mouth that in folded down the decompression heat-seal.) 350 mm (external dimension) (7) internal carton (10) quality assurance (qa) seal (8) bar code label 36 mm (external dimension) (9) plastic adhesive tape (transparent) 355 mm (external dimension) (13) bar code label (12) plastic adhesive tape (transparent) internal carton: 10 (in ten columns and one row) (11) external carton 390 mm (external dimension) 376 mm (external dimension) 384 mm (external dimension) T6B70BFNG( 330=2000 units) (2) cover tape (4) bar code label (3) reel (1) emboss tape (el) T6B70BFNG
T6B70BFNG 2008-05-15 19 6. issuing purchase orders when issuing ic purchase orders usin g the taping packaging information, be sure to include the product name, taping type, insertion direction and quantity as follows: example: 7. delivery and storage precautions tape reels should be delivered with enough care so as to prevent extreme vibration from impacting the product. tape reels should be kept out of direct sun light and be kept below 45c during delivery and storage so as to prevent wearing down the p eeling strength of seal ta pe and/or causing other deformities to the tape. T6B70BFNG ( e l ) 2000 pcs ? quantity ? insertion ? taping type ? ic part number
T6B70BFNG 2008-05-15 20 package dimensions weight: 0.07 g (typ.)
T6B70BFNG 2008-05-15 21 about solderability, following conditions were confirmed solderability (1) use of sn-37pb solder bath ? solder bath temperature = 230 ? dipping time = 5 seconds ? the number of times = once ? use of r-type flux (2) use of sn-3.0ag-0 .5cu solder bath ? solder bath temperature = 245 ? dipping time = 5 seconds ? the number of times = once ? use of r-type flux x the information contained herein is subject to change without notice. x toshiba is continually working to im prove the quality and reliability of its products. nevertheless, semiconductor devices in general can malfunction or fail due to their inhe rent electrical sensitivity and vulnerability to physical stress. it is the responsibility of t he buyer, when utilizing toshiba products, to comply with the standards of safety in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such toshiba products could cause loss of human life, bodily injury or damage to property. in developing your designs, please ensure that toshiba products are used within specified operating ranges as set forth in the most recent toshiba products specifications. also, plea se keep in mind the precautions and conditions set forth in the ?handling guide for semico nductor devices,? or ?toshiba semiconductor reliability handbook? etc.. x the toshiba products listed in this document are designed and manufactured for usage in hot water dispensers. do not use any of these products fo r any purposes other than hot water di spensers, unless otherwise agreed in writing by toshiba. x the products described in this document shall not be used or embedded to any down stream products of which manufacture, use and/or sale are prohibited und er any applicable laws and regulations. x the information contained herein is presented only as a gu ide for the applications of our products. no responsibility is assumed by toshiba for any infringements of patents or other rights of the third parti es which may result from its use. no license is granted by imp lication or otherwise under any patents or other rights of toshiba or the third parties. x please use this product in compliance with all applicable la ws and regulations that regulate the inclusion or use of controlled substances. toshiba assumes no liability for dam age or losses occurring as a result of noncompliance with applicable laws and regulations. x the products described in this document are subject to foreign exchange and foreign trade control laws. 070711eba restrictions on product use

▲Up To Search▲

Price & Availability of T6B70BFNG

	To Download T6B70BFNG Datasheet File
If you can't view the Datasheet, Please click here to try to view without PDF Reader .