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| ds04-27701-2e fujitsu semiconductor data sheet assp for power management applications (secondary battery) dc/dc converter ic for charging MB3832A n description the MB3832A is a pulse width modulation (pwm) dc/dc converter ic, incorporating a current detector amplifier and error amplifiers (2 circuits) to control the output voltage and current independently. it is suitable for down- conversion. with an on-chip reference voltage generator, the MB3832A is best suited for use in applications such as lithium- ion battery (1-cell to 3-cell) chargers. n features ? high precision reference voltage source: 2.5 v 0.5% (+25 c) : 2.5 v 1.0% (C10 c to +85 c) ? high frequency operating capability: 500 khz max. ? wide operating supply voltage range: 3.6 v to 18 v ? on-chip current detector amplifier with wide in-phase input voltage range: 0 v to v cc ? on-chip standby function ? on-chip triangular waveform oscillator capable of operating in external synchronization ? on-chip, timer-latch short-circuit protection circuit ? internal totem-pole output stage supporting p-channel mos fets and pnp transistors n pac k ag e 20-pin plastic ssop (fpt-20p-m03)
2 MB3832A n pin assignment vref : 1 (top view) (fpt-20p-m03) rt : 2 ct : 3 sync : 4 cscp : 5 fb1 : 6 - in1 : 7 + in1 : 8 - inc : 9 + inc : 10 20 : ve 19 : out 18 : v cc 17 : ctl 16 : dtc 15 : fb2 14 : - in2 13 : + in2 12 : cout 11 : gnd 3 MB3832A n pin description i: input pin, o: output pin pin no. pin name i/o descriptions 1 vref o reference voltage output pin 2 rt connection pin for triangular wave frequency setting resistor 3 ct connection pin for triangular wave frequency setting capacitor 4 sync i external synchronous signal input pin 5cscp connection pin for time constant setting capacitor for timer-latch short- circuit protection circuit 6 fbi o error amplifier 1 output pin 7 Cin1 i error amplifier 1 inverted input pin 8 +in1 i error amplifier 1 non-inverted input pin 9 Cinc i current detector amplifier inverted input pin 10 +inc i current detector amplifier non-inverted input pin 11 gnd ground pin 12 cout o current detector amplifier output pin 13 +in2 i error amplifier 2 non-inverted input pin 14 Cin2 i error amplifier 2 inverted input pin 15 fb2 o error amplifier 2 output pin 16 dtc i connection pin for dead time/soft start time setting resistor/capacitor 17 ctl i power supply control input pin h level: active state l level: standby state 18 v cc power supply pin 19 out o totem-pole output pin 20 ve connector pin for output sink current setting resistor 4 MB3832A n block diagram - + - + - + - - + - + + + + - 15 14 13 6 7 8 16 5 4 20 19 18 2 3 1 11 12 9 10 17 fb2 - in2 - in1 + in1 dtc cscp 1 m a bias sr latch uvlo osc ref ctl sync rt ct vref bias 1.9 v 1 v 1.3 v v cc gnd 2.5 v ctl ve out v cc 2.1 v 1.1 v scp comp. dtc comp. fb1 out current amp. error amp.2 error amp.1 pwm comp. 25 100 k w + inc - inc cout + in2 5 MB3832A n absolute maximum ratings * : when mounted on a 10 cm-square dual-sided epoxy base board warning: semiconductor devices can be permanently damaged by application of stress (voltage, current, temperature, etc.) in excess of absolute maximum ratings. do not exceed these ratings. n recommended operating conditions warning: the recommended operating conditions are required in order to ensure the normal operation of the semiconductor device. all of the devices electrical characteristics are warranted when the device is operated within these ranges. always use semiconductor devices within their recommended operating condition ranges. operation outside these ranges may adversely affect reliability and could result in device failure. no warranty is made with respect to uses, operating conditions, or combinations not represented on the data sheet. users considering application outside the listed conditions are advised to contact their fujitsu representatives beforehand. parameter symbol condition rating unit min. max. power supply voltage v cc 20v control input voltage v ctl 20v output current i o out pin, dc 50 ma peak output current i o out pin, duty 5% 600 ma allowable dissipation p d ta +25 c 540*mw storage temperature tstg C55 +125 c parameter symbol condition value unit min. typ. max. power supply voltage v cc 3.61618v reference voltage output current i or C10ma input voltage v in +in1, Cin1, +in2, Cin2 pin 0v cc C 0.9 v +inc, Cinc pin 0 v cc v control input voltage v ctl ctl pin 0 18 v sync input voltage v sync sync pin 0 v cc v output current i o out pin, dc 30 ma oscillatior frequency f osc 10 200 500 khz timing capacitance c t 100 390 2200 pf timing resistance r t 8.21251k w short detection capacitance c scp 0.11.0 m f operating temperature ta C30 +25 +85 c 6 MB3832A n electrical characteristics (v cc = 16 v, ta = +25 c) * : standard design value (continued) parameter symbol pin no. condition value unit min. typ. max. reference voltage block (ref) output voltage v ref 1 ta = +25 c 2.4875 2.50 2.5125 v ta = C10 c to +85 c 2.475 2.50 2.525 v ta = + 2 5 c to +85 c 2.480 2.50 2.520 v input stability line 1 v cc = 3.6 v to 18 v 1 10 mv load stability load 1 i ref = 0 ma to C1 ma 3 10 mv short circuit output current i os 1v ref = 0 v C36 C16 C7 ma under voltage lockout circuit block (uvlo) threshold voltage v th 16 v cc pin 2.8 3.1 v v tl 16 v cc pin 2.3 2.6 v hysteresis width v h 16 v cc pin 80 200 mv reset voltage v rst 19 v cc pin 1.7 2.1 v short detection block (scp comp, s-r latch) detection voltage v th 5 fb pin 2.0 2.1 2.2 v threshold voltage v th 5 cscp pin 0.65 0.70 0.75 v input standby voltage v stb 5 cscp pin 50 100 mv input latch voltage v i 5 cscp pin 50 100 mv input source current i cscp 5 cscp pin C1.4 C1.0 C0.6 m a triangular wave oscillator block (osc) oscillator frequency f osc 19 c t = 330 pf, r t = 12 k w 190 200 210 khz frequency input stability d f/f 19 v cc = 3.6 v to 18 v 1 5 % sync input condition v ih 19 input h level 2.0 v v il 19 input l level 0 0.8 v input current i sync 4v sync = 5 v 50 100 m a error amplifier (error amp.1, 2) input offset voltage v io 8, 7, 13, 14 v fb = 1.6 v C3 3 mv input bias current i b 8, 7, 13, 14 v fb = 1.6 v C200 C50 na common mode input voltage range v cm 8, 7, 13, 14 0v cc C 0.9 v common mode rejection ratio cmrr 6, 15 60 100 db voltage gain a v 6, 15 dc 60 100 db frequency bandwidth bw 6, 15 a v = 0 db 750* khz maximum output voltage width v om + 6, 15 2.5 2.7 v v om C 6, 15 0.8 1.0 v output source current i om C 6, 15 v fb = 1.6 v C120 C60 m a output sink current i om + 6, 15 v fb = 1.6 v 0.6 2.0 ma 7 MB3832A (v cc = 16 v, ta = +25 c) * : standard design value (continued) parameter symbol pin no. condition value unit min. typ. max. current detector amplifier block (current amp.) input offset voltage v io 10, 9 v +inc , v Cinc = 2.4 v to 12.6 v C2 2 mv input bias current i +inc 10 v +inc = 12.7 v, v Cinc = 12.6 v 1 2 m a i Cinc 9 v +inc = 0.1 v, v Cinc = 0 v C2 C1 m a output voltage v o1 12 v +inc = 12.7 v, v Cinc = 12.6 v 2.25 2.5 2.75 v v o2 12 v +inc = 12.8 v, v Cinc = 12.6 v 4.5 5.0 5.5 v v o3 12 v +inc = 0.1 v, v Cinc = 0 v 2.25 2.5 2.75 v v o4 12 v +inc = 0.2 v, v Cinc = 0 v 4.5 5.0 5.5 v common mode input voltage range v cm 10, 9 0 v cc v common mode rejection ratio cmrr 12 v +inc , v Cinc = 2.4 v to 12.6 v 60 90 db voltage gain a v 12 v Cinc = 12.6 v 22.5 25 27.5 v/v frequency bandwidth bw 12 a v = 0 db 500* khz output resistance r o 12 f = 10 khz 20* w maximum output voltage width v om + 12 v cc C 2.0 v cc C 1.6 v v om C 12 50 200 mv output source current i om C 12 v cout = 2.5 v C7 C2 ma output sink current i om + 12 v cout = 2.5 v 60 170 m a pwm comparator block (pwm comp.) threshold voltage v t0 19 duty cycle = 0 % 1.2 1.3 v v t100 19 duty cycle = 100 % 1.9 2.0 v input bias current i dtc 16 v dtc = 0.4 v C1.0 C0.2 m a latch mode input current i dtc 16 v dtc = 2.5 v 270 900 m a input latch voltage v dtc 16 i dtc = 100 m a 0.15 0.3 v on duty cycle dtr 19 v dtc = v ref /1.56 43 48 53 % 8 MB3832A (continued) (v cc = 16 v, ta = +25 c) parameter symbol pin no. condition value unit min. typ. max. output block (out) output on resistance r on 19 i o = C50 ma 5 8 w output sink current i o 19 r e = 33 w 18 30 42 ma output voltage v oh 19 i o = C300 ma 12.5 14 v v ol 19 i o = 300 ma 1.2 1.8 v control-off output resistance r out1 19 v ctl = 0 v, v ref = 2.5 v, i o = C50 ma 5 8 w r out2 19 v ctl = 0 v, v ref = 0 v, i o = C10 m a 70 100 130 k w control block (ctl) ctl input condition v on 1 ic is active state 2.0 18 v v off 1 ic is standby state 0 0.8 v input current i ih 17 v ctl = 5 v 100 200 m a i il 17 v ctl = 0 v C1 0 m a general standby current i ccs 18 v ctl = 0 v 10 m a power supply current i cc 18 output h 4.6 7.0 ma 9 MB3832A n typical characteristics (continued) 5 4 3 2 1 0 0 5 10 15 20 ctl = v cc ta = + 25 c i ref = 0 ma reference voltage vs. power supply voltage characteristics reference voltage vs. v ref load current characteristics 5 4 3 2 1 0 010203040 v cc = 16 v ctl = 5 v ta = + 25 c power supply voltage v cc (v) reference voltage v ref (v) reference voltage d v ref (%) reference voltage v ref (v) control current i ctl ( m a) reference voltage v ref (v) v ref load current i ref (ma) reference voltage vs. temperature characteristics reference voltage vs. control voltage characteristics control current vs. control voltage characteristics 2.0 1.5 1.0 0.5 0.0 - 0.5 - 1.0 - 1.5 - 2.0 - 40 - 20 0 20 40 60 80 100 v cc = 16 v ctl = 5 v 5 4 3 2 1 0 0 5 10 15 20 v cc = 16 v ta = + 25 c i ref = 0 ma 500 400 300 200 100 0 0 5 10 15 20 v cc = 16 v ta = + 25 c control voltage v ctl (v) control voltage v ctl (v) temperature ta ( c) 10 MB3832A (continued) 1 m 100 k 10 k 1 k 1 k 10 k 100 k c t = 100 pf c t = 390 pf c t = 2200 pf v cc = 16 v ctl = 5 v 1 m 100 k 100 p 10 k 10 n 10 p 1 k 1 n v cc = 16 v ctl = 5 v r t = 12 k w 3.0 2.0 1.0 0.0 - 1.0 - 2.0 - 3.0 0 2 4 6 8 101214161820 ctl = v cc r t = 12 k w , c t = 390 pf 220 215 210 205 200 195 190 185 180 - 40 - 20 0 20 40 60 80 100 r t = 12 k w , c t = 390 pf v cc = 16 v ctl = 5 v 2.5 2.0 1.5 1.0 0.5 1 k 10 k 100 k 1 m 10 m v cc = 16 v ctl = 5 v triangular wave oscillation frequency vs. r t resistance characteristics triangular wave oscillation frequency regulation vs. power supply voltage characteristics triangular wave maximum/minimum voltages vs. triangular wave oscillation frequency characteristics triangular wave oscillation frequency vs. c t capacitance characteristics triangular wave oscillation frequency vs. temperature characteristics triangular wave oscillation frequency f osc (hz) triangular wave oscillation frequency regulation d f osc (%) triangular wave upper and down voltage (v) triangular wave oscillation frequency f osc (hz) triangular wave oscillation frequency f osc (khz) r t resistance ( w ) power supply voltage v cc (v) triangular wave oscillation frequency f osc (hz) upper lower c t capacitance (f) temperature ta ( c) 11 MB3832A (continued) 40 30 20 10 0 100 a v 10 k 1 k 1 m 10 m 100 k - 10 - 20 - 30 - 40 v cc = 16 v ctl = 5 v t a = + 25 c f 180 135 90 45 0 - 45 - 90 - 135 - 180 8 6 5 v 11 k w 11 k w 240 k w 2.4 k w (13) (15) 2.5 v 1 m f - + 7 (14) in out err amp.1 (err amp.2) 3.0 2.8 2.6 2.4 2.2 2.0 0481216 v cc = 16 v v + inc = v - inc + 0.1 v t a = + 25 c 50 40 30 20 10 0 - 10 - 20 - 30 - 40 - 50 100 1 k 10 k 100 k 1 m 10 m 180 135 90 45 0 - 45 - 90 - 135 - 180 a v f + - + - 10 9 12 12.6 v 0.1 v 2 12.5 out current amp. in error amp. gain, phase vs. frequency characteristics current detector amp. gain, phase vs. frequency characteristics current detector amp. output voltage vs. input voltage characteristics gain av (db) gain av (db) output voltage v cout (v) frequency f (hz) frequency f (hz) inverting input voltage (v) phase f (deg.) phase f (deg.) 12 MB3832A (continued) allowable dissipation vs. ambient temperature characteristics allowable dissipation p d (mw) ambient temperature ta ( c) 600 540 500 400 300 200 100 0 - 40 - 20 0 20 40 60 80 100 120 13 MB3832A n functional description 1. switching regulator functions (1) reference voltage circuit (ref) the reference voltage generator uses the voltage supplied from the v cc pin (pin 18) to generate a temperature- compensated, stable voltage (about 2.50 v) as the reference supply voltage for the ics internal circuitry. the reference voltage can be output, up to 1 ma, to an external device through the vref pin (pin 1). (2) triangular wave oscillator (osc) the triangular wave oscillator generates a triangular waveform with a timing capacitor and a timing resistor respectively connected to the ct pin (pin 3) and rt pin (pin 2). the triangular wave is input to the pwm comparator in the ic while it can also be supplied to an external device through the ct pin. in addition, the oscillator can be used for external synchronization, where it generates a triangular wave synchronous to the input signal from the sync pin (pin 4). (3) error amplifiers (error amp. 1, 2) the error amplifiers detect the output voltage from the switching regulator and outputs the pwm control signal. it supports a wide range of in-phase inputs from 0 v to v cc C 0.9 v. an arbitrary loop gain can be set by connecting a feedback resistor and capacitor from the fb1 pin (pin 6) [fb2 pin (pin 15)] to the Cin1 pin (pin 7) [Cin2 pin (pin 14)] of the error amplifier, enabling stable phase compensation to the system. (4) current detector amplifier (current amp.) the current detector amplifier provides 25 amplification of the voltage drop between the two ends of the output sensor resistor (rs) in the switching regulator, that occurs due to the flow of the charging current. at the same time, the amplifier converts the voltage to the gnd-reference voltage level and outputs it to the cout pin (pin 12). it can also control the charging current in combination with the error amplifier circuit. (5) power control circuit (ctl) the power control circuit can control turning on and off the power supply through the ctl pin (pin 17). (supply current in standby mode: about 0 m a) depending on the voltage level of the pwm comp. input pin, the out pin (pin 19) may become l level during discharging of the v ref voltage after the ctl pin is turned off with a capacitor connected to the v ref pin. the power control circuit contains a function for fixing the out output pin to the h level when ctl = l and vref = h, preventing inadvertent l level output after turning the ctl pin off. (6) pwm comparator circuit (pwm comp.) the pwm comparator circuit is a voltage-pulse width converter for controlling the output duty of the error amplifiers (error amp. 1, 2) depending on their output voltage. the pwm comparator circuit turns on the external output transistor during the interval in which the triangular wave voltage level is lower than the voltage level at both of the error amplifier output pins (fb1 pin (pin 6), fb2 pin (pin 15)) and the dtc pin (pin 16). (7) output circuit (out) the output circuit uses a totem-pole configuration, capable of driving an external p-channel mos fet and pnp transistor. it can also control the output sink current with a resistor connected between the ve pin (pin 20) and the gnd pin (pin 11). 2. protection functions (1) low input voltage malfunction preventive circuit (ulvo) the transient state or a momentary decrease in supply voltage, which occurs when the power supply is turned on, may cause errors in the control ic, resulting in breakdown or degradation of the system. the low input voltage malfunction preventive circuit detects the internal reference voltage level according to the supply voltage 14 MB3832A and turn off the external output transistor to make dead time 100%. the circuit restores voltage supply when the supply voltage reaches its threshold voltage. (2) timer-latch short-circuit protection circuit (scp comp., sr latch) the latch circuit detects the output voltage levels of the error amplifiers. when the output voltage levels of the two error amplifiers reach about 2.1 v at the same time, the timer circuit is actuated to start charging the external capacitor connected to the cscp pin (pin 5). if the error amplifier outputs are not restored to the normal voltage range before the capacitor voltage reaches about 0.7 v, the latch circuit is actuated to fix the output pins (out) at the h level. to reset the actuated protection circuit, turn the power supply on back. 15 MB3832A n method of setting for external synchronous oscillation for external synchronous oscillation, connect a timing capacitor (c t ), a timing resistor (r t ), and an external sync signal to the ct, rt, and sync pins, respectively. in this case, select the c t and r t so that the oscillation frequency is 5% to 10% lower than the frequency of the external synchronous signal excluding the setting error of the oscillation frequency. the duty cycle (t1/t) of the external sync signal must be set within a range from 10% to 90%. + - - + + - sq r sq r 3 4 sync c t 2i* 3i* 1.9 v c t v ref 1.3 v l level: on *: | = vrt/r t , vrt (pin voltage at pin 2) = 1.0 v (typical) 1.4 v latch2 latch1 t1 t 1.9 v v ct 1.3 v 0 v 5.0 v v sync 1.9 v v ct 1.3 v 0 v 5.0 v v sync tt 16 MB3832A n treatment of unused cscp pin when the timer-latch short-circuit protection circuit is not used, connect the cscp pin (pin 5) to the gnd at the shortest distance. 5 11 cscp gnd treatment of the cscp pin when not used 17 MB3832A n methods of setting the dead time and soft start 1. dead time when the device is set for step-up inverted output based on the flyback method, the output transistor is fixed to a full-on state (on duty = 100%) when the power supply is turned on. to prevent this problem, you may determine the voltage at the dtc pin (pin 16) from the v ref voltage so you can set the output transistors dead time (maximum on-duty period) as shown in figure a below. when the voltage at the dtc pin (pin 16) is higher than the triangular wave output voltage from the oscillator, the output transistor is turned off. the dead time calculation formula assuming that triangular wave amplitude 0.6 v and triangular wave minimum voltage 1.3 v is given below. duty (on) 100 [%], v dt = v ref when the dtc pin is not used, connect it directly to the vref pin. 2. soft start to prevent surge currents when the ic is turned on, you can set a soft start using the dtc pin (pin 16). you can also set a soft start along with the dead time by making connections as shown in figure d below. . . = . . = . . = 0.6 v v dt C 1.3 v r 1 + r 2 r 2 1 vref 16 dtc r 1 r 2 v dt 1 vref 16 dtc ? figure a setting the dead time ? figure b not setting the dead time 1 vref 16 dtc r dt c dt 1 vref 16 dtc r 1 r 2 cdt ? figure c setting a soft start ? figure d setting the dead time and a soft start 18 MB3832A n equivale circuit (ctl, sync pin) 17 4 ctl sync v cc 1.4 v ?ctl pin ?sync pin 19 MB3832A n application example (step-down scheme) - + - + + + - + - + - + - - + 18 10 15 14 13 6 7 8 16 5 12 19 20 17 11 1 3 2 9 4 out ve v cc ctl v cc gnd 68 m f gnd (for load) mtd20p03hdl: made by motorola inc. mbrs130lt3: made by motorola inc. 18 m h rs 0.033 w v o (12.6 v) mtd20p03hdl mbrs130 lt3 0.1 m f 0.1 m f 5.1 w 1 v 2.1 v 1.1 v latch uvlo osc ref bias ctl r bias s 5 v 2.5 v 1.3 v 1.9 v sync 0 v + inc - inc - in2 fb2 fb1 + in2 + in2 - in1 + in1 dtc cscp cout 25 current amp. error amp.2 error amp.1 pwm comp. dtc comp. scp comp. out 100 m f 2.2 m f 0.1 m f 0.033 m f 0.22 m f 1 m a 0.22 m f 100 k w 5.1 k w 33 k w vin 10 k w 12k w rt 390pf ct vref 10 k w gnd 10 k w 10 k w a* b* c* 3.9 k w 470 k w 5.1 k w 20.6 k w *: a: set the charging current to 3 a. b: set the charging current to 2 a. c: set the charging current to 1 a. charging current setting synchronous signal 20 MB3832A n reference data soft start operation waveforms 14 12 10 8 6 4 2 0 0 0.5 1 1.5 2 2.5 3 3.5 4 vin = 16 v ta = + 25 c v + in2 = v ref ( + in2 ? a) v + in2 = v ref * 2/3 ( + in2 ? b) v + in2 = v ref /3 ( + in2 ? c) output voltage vs. output current characteristics output voltage v o (v) output current i o (a) 20 15 10 5 0 10 5 0 0 40 80 120 160 200 t(ms) v o (v) ctl(v) vin = 16 v ctl = 5 v rl = 5 w (2.52 a) 100 90 0 % 10 21 MB3832A n usage precautions 1. printed circuit board ground lines should be set up with consideration for common impedance. 2. take appropriate static electricity measures. ? containers for semiconductor materials should have anti-static protection or be made of conductive material. ? after mounting, printed circuit boards should be stored and shipped in conductive bags or containers. ? work platforms, tools, and instruments should be properly grounded. ? working personnel should be grounded with resistance of 250 k w to 1 m w between body and ground. n ordering information part number package remarks MB3832Apfv 20-pin plastic ssop (fpt-20p-m03) 22 MB3832A n package dimension 20-pin plastic ssop (fpt-20p-m03) c 1999 fujitsu limited f20012s-3c-5 6.50?.10(.256?004) * 4.40?.10 6.40?.20 (.252?008) (.173?004) * .049 ?004 +.008 ?.10 +0.20 1.25 (mounting height) 0.10(.004) 0.65(.026) 0.24?.08 (.009?003) 1 10 20 11 "a" 0.10?.10 (stand off) 0.17?.03 (.007?001) m 0.13(.005) (.004?004) details of "a" part 0~8� (.018/.030) 0.45/0.75 (.020?008) 0.50?.20 0.25(.010) lead no. index dimensions in mm (inches) *: these dimensions do not include resin protrusion. MB3832A fujitsu limited for further information please contact: japan fujitsu limited corporate global business support division electronic devices kawasaki plant, 4-1-1, kamikodanaka, nakahara-ku, kawasaki-shi, kanagawa 211-8588, japan tel: +81-44-754-3763 fax: +81-44-754-3329 http://www.fujitsu.co.jp/ north and south america fujitsu microelectronics, inc. 3545 north first street, san jose, ca 95134-1804, u.s.a. tel: +1-408-922-9000 fax: +1-408-922-9179 customer response center mon. - fri.: 7 am - 5 pm (pst) tel: +1-800-866-8608 fax: +1-408-922-9179 http://www.fujitsumicro.com/ europe fujitsu microelectronics europe gmbh am siebenstein 6-10, d-63303 dreieich-buchschlag, germany tel: +49-6103-690-0 fax: +49-6103-690-122 http://www.fujitsu-fme.com/ asia pacific fujitsu microelectronics asia pte. ltd. #05-08, 151 lorong chuan, new tech park, singapore 556741 tel: +65-281-0770 fax: +65-281-0220 http://www.fmap.com.sg/ korea fujitsu microelectronics korea ltd. 1702 kosmo tower, 1002 daechi-dong, kangnam-gu,seoul 135-280 korea tel: +82-2-3484-7100 fax: +82-2-3484-7111 f0004 ? fujitsu limited printed in japan all rights reserved. the contents of this document are subject to change without notice. customers are advised to consult with fujitsu sales representatives before ordering. the information and circuit diagrams in this document are presented as examples of semiconductor device applications, and are not intended to be incorporated in devices for actual use. also, fujitsu is unable to assume responsibility for infringement of any patent rights or other rights of third parties arising from the use of this information or circuit diagrams. the contents of this document may not be reproduced or copied without the permission of fujitsu limited. fujitsu semiconductor devices are intended for use in standard applications (computers, office automation and other office equipments, industrial, communications, and measurement equipments, personal or household devices, etc.). caution: customers considering the use of our products in special applications where failure or abnormal operation may directly affect human lives or cause physical injury or property damage, or where extremely high levels of reliability are demanded (such as aerospace systems, atomic energy controls, sea floor repeaters, vehicle operating controls, medical devices for life support, etc.) are requested to consult with fujitsu sales representatives before such use. the company will not be responsible for damages arising from such use without prior approval. any semiconductor devices have inherently a certain rate of failure. you must protect against injury, damage or loss from such failures by incorporating safety design measures into your facility and equipment such as redundancy, fire protection, and prevention of over-current levels and other abnormal operating conditions. if any products described in this document represent goods or technologies subject to certain restrictions on export under the foreign exchange and foreign trade control law of japan, the prior authorization by japanese government should be required for export of those products from japan. |
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