tcr2bf series, tcr2be series 2011-06-06 1 toshiba cmos linear integrat ed ci rcuit silicon monolithic tcr2bf series tcr2be series 200 ma cmos low drop-out regulator with auto-discharge the tcr2bf series and tcr2be series are cmos general-purpose single-output voltage regulators with an on/off control input, featuring low dropout voltage and low quiescent bias current. these voltage regulators can be enabled and disabled via the control pin. these voltage regulators are available in fixed output voltages between 1.0 v and 5.0 v in smv pa ckage, 1.0 to 3.6v in esv package, and capable of driving up to 200 ma. they feature overcurrent protection and auto-discharge function. the tcr2bf series and tcr2be series are offered in the compact smv (sot-25)(sc-74a) and esv (sot-553) and allow the use of small ceramic input and output capacitors. thus, these devices are ideal for portable applic ations that require high-density board assembly such as cellular phones. features ? wide fixed output voltage line up tcr2bf series (smv package) : v out = 1.0 to 5.0 v tcr2be series (esv package) : v out = 1.0 to 3.6 v ? low output noise voltage ( v no = 50 v rms (typ.) at 2.8 v-output, i out = 10 ma, 10 hz < = f < = 100 khz) ? low quiescent bias current ( i b = 75 a (max) at i out = 0 ma ) ? low stand-by current ( i b(off) = 0.1 a (typ.) at stand-by mode ) ? high ripple rejection ( r.r. = 70 db (typ.) at i out = 10 ma, f =1khz ) ? overcurrent protection ? auto-discharge ? pull-down connection at control ? ceramic capacitors can be used ( c in = 0.1 f, c out =1.0 f ) ? small package, smv (sot-25) (sc-74a) and esv (sot-553) pin assignment (top view) smv (sot-25)(sc-74a) esv (sot-553) weight: smv (sot-25)(sc-74a) : 16 mg (typ.) esv (sot-553) : 3.0 mg (typ.) smv esv v out control gnd nc v in 13 2 4 5 v out control gnd nc v in 1 3 2 4 5
tcr2bf series, tcr2be series 2011-06-06 2 list of products number, output voltage, and marking product no. product no. smv(sot-25) esv(sot-553) v out (v)(typ.) marking smv(sot-25) esv(sot-553) v out (v)(typ.) marking tcr2bf10 tcr2be10 1.0 1m0 tcr2bf29* tcr2be29* 2.9 2m9 tcr2bf105* tcr2be105* 1.05 1ma tcr2bf295* tcr2be295* 2.95 2me tcr2bf11* tcr2be11* 1.1 1m1 tcr2bf30 tcr2be30 3.0 3m0 tcr2bf115 tcr2be115 1.15 1mb tcr2bf31 tcr2be31 3.1 3m1 tcr2bf12 tcr2be12 1.2 1m2 tcr2bf32 tcr2be32 3.2 3m2 tcr2bf125 tcr2be125 1.25 1mc tcr2bf33 tcr2be33 3.3 3m3 tcr2bf13* tcr2be13* 1.3 1m3 tcr2bf34* tcr2be34* 3.4 3m4 tcr2bf14* tcr2be14* 1.4 1m4 tcr2bf35* tcr2be35* 3.5 3m5 tcr2bf15 tcr2be15 1.5 1m5 tcr2bf36 tcr2be36 3.6 3m6 tcr2bf16* tcr2be16* 1.6 1m6 tcr2bf37* D 3.7 3m7 tcr2bf17* tcr2be17* 1.7 1m7 tcr2bf38* D 3.8 3m8 tcr2bf175* tcr2be175* 1.75 1mf tcr2bf39* D 3.9 3m9 tcr2bf18 tcr2be18 1.8 1m8 tcr2bf40 D 4.0 4m0 tcr2bf19* tcr2be19* 1.9 1m9 tcr2bf41* D 4.1 4m1 tcr2bf20* tcr2be20* 2.0 2m0 tcr2bf42* D 4.2 4m2 tcr2bf21* tcr2be21* 2.1 2m1 tcr2bf43* D 4.3 4m3 tcr2bf22* tcr2be22* 2.2 2m2 tcr2bf44* D 4.4 4m4 tcr2bf23* tcr2be23* 2.3 2m3 tcr2bf45 D 4.5 4m5 tcr2bf24* tcr2be24* 2.4 2m4 tcr2bf46* D 4.6 4m6 tcr2bf25 tcr2be25 2.5 2m5 tcr2bf47* D 4.7 4m7 tcr2bf26* tcr2be26* 2.6 2m6 tcr2bf48* D 4.8 4m8 tcr2bf27 tcr2be27 2.7 2m7 tcr2bf49* D 4.9 4m9 tcr2bf28 tcr2be28 2.8 2m8 TCR2BF50 D 5.0 5m0 tcr2bf285* tcr2be285* 2.85 2md please contact your local toshiba representative if you are interested in products with * sign marking (top view) example: tcr2bf33 (3.3 v output) example: tcr2be33 (3.3 v output) 3 m 3 3 m 3
tcr2bf series, tcr2be series 2011-06-06 3 absolute maximum ratings (ta = 25c) characteristics symbol rating unit input voltage v in 6.0 v control voltage v ct -0.3 to 6.0 v output voltage v out -0.3 to v in + 0.3 v output current i out 200 ma 200 (note 1) smv 380 (note 2) 150 (note 1) power dissipation p d esv 320 (note 3) mw operation temperature range t opr ?40 to 85 c junction temperature t j 150 c storage temperature range t stg ?55 to150 c note: using continuously under heavy loads (e.g. the application of high temperature/current/voltage and the significant change in temperature, etc.) may cause this product to decrease in the reliability significantly even if the operating conditions (i.e. operating temper ature/current/voltage, etc. ) are within the absolute maximum ratings and the operating ranges. please design the appropriate reliability upon reviewing the toshiba semiconductor reliability handbook (?handling precautions?/?derating concept and methods?) and individual reliability data (i.e. reliability test report and estimated failure rate, etc). note 1: unit rating note 2: rating at mounting on a board (glass epoxy board dimension: 30 mm 30 mm, copper area: 50 mm 2 ) note 3: rating at mounting on a board (glass epoxy board dimension: 30 mm 30 mm, copper area: 20 mm 2 )
tcr2bf series, tcr2be series 2011-06-06 4 electrical characteristics ( unless otherwise specified , v in = v out + 1 v, i out = 50 ma, c in = 0.1 f, c out = 1.0 f, t j = 25c) characteristics symbol test condition min typ. max unit v out Q 1.4 v -30 ? +30 mv output voltage v out ? 1.5v Q v out -2 ? +2 % line regulation reg ? line v out + 0.5 v < = v in < = 6 v, i out = 1 ma ? 1 15 mv load regulation reg ? load 1 ma < = i out < = 150 ma ? 10 30 mv quiescent current i b i out = 0 ma ? 40 75 a stand-by current i b (off) v ct = 0 v ? 0.1 1.0 a dropout voltage v in -v out please refer to the dropout voltage table temperature coefficient t cvo ? 40c < = t opr < = 85c ? 100 ? ppm/c output noise voltage v no v in = v out + 1 v, i out = 10 ma, 10 hz < = f < = 100 khz, ta = 25c (note 4) ? 50 ? v rms v out : 1.0v 1.55 ? 6.0 v out : 1.05v to 1.1v v out + 0.50 v ? 6.0 v out : 1.15v to 1.2v 1.58 ? 6.0 v out : 1.25v 1.59 ? 6.0 v out : 1.3v 1.63 ? 6.0 v out : 1.4v 1.68 ? 6.0 v out : 1.5v to 1.75v v out + 0.25 v ? 6.0 v out : 1.8v to 2.4v v out + 0.20 v ? 6.0 input voltage v in ? v out : 2.5v to 5.0v v out + 0.15 v ? 6.0 v ripple rejection ratio r.r. v in = v out + 1 v, i out = 10 ma, f = 1 khz, v ripple = 500 mv p-p , ta = 25c ? 70 ? db control voltage (on) v ct (on) ? 1.1 ? 6.0 v control voltage (off) v ct (off) ? 0 ? 0.4 v note 4: the 2.8v output product.
tcr2bf series, tcr2be series 2011-06-06 5 dropout voltage ( i out = 50 ma, c in = 0.1 f, c out = 1.0 f, t j = 25c) output voltage symbol min typ. max unit v out : 1.0v ? 350 550 v out : 1.05v ? 340 500 v out : 1.1v ? 310 500 v out : 1.15v ? 290 430 v out : 1.2v ? 260 380 v out : 1.25v ? 250 340 v out : 1.3v ? 230 330 v out : 1.4v ? 190 280 v out : 1.5v to 1.75v ? 160 250 v out : 1.8v to 2.4v ? 130 200 v out : 2.5v to 5.0v v in -v out ? 100 150 mv
tcr2bf series, tcr2be series 2011-06-06 6 application note 1. recommended application circuit the figure above shows the recommended configuration for using a low-dropout regulator. insert a capacitor at v out and v in pins for stable input/output operatio n. (ceramic capacitors can be used). 2. power dissipation power dissipation is measured on the board shown below. testing board of thermal resistance control pin connection operation high on low off open off ambient temperature ta (c) p d ? ta (smv) power dissipation p d (mw) ? 40 0 0 40 120 80 100 200 300 400 board dimension 30 mm x 30 mm, t = 0.8 mm copper area 50 mm 2 , mounted on glass epoxy board unit rating c ou t v in v ou t control gnd c in nc sm v �������������������� ������ es v nc control gnd v in c in c out v out ambient temperature ta (c) p d ? ta (esv) power dissipation p d (mw) ? 40 0 0 40 120 80 100 200 300 400 board dimension 30 mm x 30 mm, t = 0.8 mm copper area 20 mm 2 , mounted on glass epoxy board unit rating *board material: glass epoxy board dimension: 30 mm 30 mm copper area: 20 mm 2 , t = 0.8 mm *board material: glass epoxy board dimension: 30 mm 30 mm copper area: 50 mm 2 t = 0.8 mm v out gnd v in 1.0 f 0.1 f ? control nc �h smv �h esv v out gnd v in 1.0 f 0.1 f control nc
tcr2bf series, tcr2be series 2011-06-06 7 attention in use output capacitors ceramic capacitors can be used for these devices. however, because of the type of the capacitors, there might be unexpected thermal features. please consider application condition for selecting capacitors. and toshiba recommend the esr of ceramic capacitor is under 10 ? . mounting the long distance between ic and output capacitor might af fect phase assurance by impedance in wire and inductor. for stable power supply, output capacitor need to mount near ic as much as possible. also gnd pattern need to be large and make the wire impedance small as possible. permissible loss please have enough design patterns for expected maximum permissible loss. and under consideration of surrounding temperature, input voltage, and output current etc, we recommend proper dissipation ratings for maximum permissible loss; in general maximu m dissipation rating is 70 to 80 percent. overcurrent protection circuit overcurrent protection circuit is designed in these products, but this does not assure for the suppression of uprising device operation. if output pins and gnd pins are shorted out, these products might be break down. in use of these products, please read through and understand dissipation idea for absolute maximum ratings from the above mention or our ?semiconductor reliability hand book?. then use these products under absolute maximum ratings in any condition. furthermore, toshiba reco mmend inserting failsafe system into the design.
tcr2bf series, tcr2be series 2011-06-06 8 representative typical characteristics 1) output voltage vs. input voltage 2) output voltage vs. output current v out =1.0v output voltage v out (v) 0.9 1.0 1.1 v in = 2.0 v, c in = 0.1 f, c out = 1 f 0 60 100 200 output current i out (ma) 20 40 80 120 140 160 180 v out =1.8v output current i out (ma) output voltage v out (v) 1.7 1.8 1.9 v in = 2.8v, c in = 0.1 f, c out = 1 f 0 60 100 200 20 40 80 120 140 160 180 v out =1.0v input voltage v in (v) output voltage v out (v) 0 1 4 6 0 1.5 2.0 0.5 1.0 c in = 0.1 f, c out = 1 f 2 3 5 i out = 10ma i out = 50ma i out = 150ma input voltage v in (v) output voltage v out (v) 0 1 4 6 0 3.0 4.0 1.0 2.0 c in = 0.1 f, c out = 1 f 2 3 5 v out =1.8v i out = 10ma i out = 50ma i out = 150ma input voltage v in (v) output voltage v out (v) 0 1 4 6 0 3.0 4.0 1.0 2.0 c in = 0.1 f, c out = 1 f 2 3 5 v out =3.0v i out = 10ma i out = 50ma i out = 150ma
tcr2bf series, tcr2be series 2011-06-06 9 3) output voltage vs. ambient temperature v out =3.0v output current i out (ma) output voltage v out (v) 2.9 3.0 3.1 v in = 4.0v, c in = 0.1 f, c out = 1 f 0 60 100 200 20 40 80 120 140 160 180 v out =1.8v ? 50 1.7 ? 25 0 25 75 50 1.75 1.8 1.85 1.9 v in = 2.8 v, c in = 0.1 f, c out = 1 f i out = 50ma 100 ambient temperature t a (c) output voltage v out (v) v out =1.0v ? 50 0.9 ? 25 0 25 75 50 0.95 1.0 1.05 1.1 v in = 2.0 v, c in = 0.1 f, c out = 1 f i out = 50ma 100 ambient temperature t a (c) output voltage v out (v) ambient temperature t a (c) v out =3.0v ? 50 2.9 ? 25 0 25 75 50 2.95 3.0 3.05 3.1 v in = 4.0 v, c in = 0.1 f, c out = 1 f i out = 50ma 100 output voltage v out (v)
tcr2bf series, tcr2be series 2011-06-06 10 4) dropout voltage vs. output current 5) quiescent current vs. input voltage v out =1.8v dropout voltage v in - v out (mv) 0 100 200 300 400 0 40 100 200 output current i out (ma) 80 180 120 140 160 60 20 500 c in = 0.1 f, c out = 1 f v out =1.0v dropout voltage v in - v out (mv) 0 200 400 600 800 0 40 100 200 output current i out (ma) 80 180 120 140 160 60 20 1000 c in = 0.1 f, c out = 1 f v out =2.5v dropout voltage v in - v out (mv) 0 100 200 300 400 0 40 100 200 output current i out (ma) 80 180 120 140 160 60 20 500 c in = 0.1 f, c out = 1 f v out =1.0v quiescent current i b ( a) c in = 0.1 f, c out = 1 f i out = 0ma 60 120 0 1 4 6 2 3 5 input voltage v in (v) 0 20 40 80 100 v out =1.8v quiescent current i b ( a) c in = 0.1 f, c out = 1 f i out = 0ma 60 120 0 1 4 6 2 3 5 input voltage v in (v) 0 20 40 80 100
tcr2bf series, tcr2be series 2011-06-06 11 6) quiescent current vs.ambient temperature v out =1.0v quiescent current i b ( a) ambient temperature ta (c) ? 50 ? 25 0 25 100 75 50 0 50 100 v in = 2.0 v, c in = 0.1 f, c out = 1 f, i out = 0ma quiescent current i b ( a) v out =1.8v ambient temperature ta (c) ? 50 ? 25 0 25 100 75 50 0 50 100 v in = 2.8 v, c in = 0.1 f, c out = 1 f, i out = 0ma quiescent current i b ( a) v out =3.0v ambient temperature ta (c) ? 50 ? 25 0 25 100 75 50 0 50 100 v in = 4.0 v, c in = 0.1 f, c out = 1 f, i out = 0ma v out =3.0v quiescent current i b ( a) c in = 0.1 f, c out = 1 f i out = 0ma 90 180 0 1 4 6 2 3 5 input voltage v in (v) 0 30 60 120 150
tcr2bf series, tcr2be series 2011-06-06 12 7) overcurrent protection characteristics (overcurrent protection characteristic does not assure for the suppression of uprising device operation. we recommend proper di ssipation ratings for maximum permissible loss.) 8) ripple rejection ratio vs. frequency output current i out (ma) v out =3.0v output voltage v out (v) 0 5.0 0 100 400 600 v in = 4.0 v 200 300 500 1.0 v in = 6.0 v 4.0 3.0 2.0 pulse width = 1 ms v out =1.0v output voltage v out (v) 0 2.0 0 100 400 600 200 300 500 1.0 output current i out (ma) pulse width = 1 ms v in = 6.0 v v in =2.0v v out =1.8v output voltage v out (v) 0 2.5 0 100 400 600 v in = 2.8 v 200 300 500 1.0 v in = 6.0 v output current i out (ma) pulse width = 1 ms 0.5 1.5 2.0 v out =3.0v frequency f (hz) ripple rejection ratio (db) 0 10 100 1 k 10 k 100 k 300 k 10 20 30 40 50 60 70 80 v in = 4.0 v ,v ripple = 500 mv p ? p c in = none, c out = 1 f i out = 10 ma, ta = 25c 90
tcr2bf series, tcr2be series 2011-06-06 13 9) control transient response (auto-discharge) v out =3.0v (turn on waveform) v in = 4.0 v, c in = 0.1 f, c out = 1 f i out = 50 ma control voltage v ct (on) (1v/div) output voltage v out (on) (1v/div) time t ( 100 s/div ) time t ( 100 s/div ) v out =1.8v (turn on waveform) v in = 2.8 v, c in = 0.1 f, c out = 1 f i out = 50 ma control voltage v ct (on) (1v/div) output voltage v out (on) (1v/div) v out =1.0v (turn on waveform) v in = 2.0 v, c in = 0.1 f, c out = 1 f i out = 50 ma control voltage v ct (on) (1v/div) output voltage v out (on) (1v/div) time t ( 100 s/div ) v out =1.0v (turn off waveform) control voltage v ct (off) (1v/div) output voltage v out (off) (1v/div) time t ( 50 s/div ) v in = 2.0 v, c in = 0.1 f, c out = 1 f i out = 1ma i out = 50ma v out =1.8v (turn off waveform) control voltage v ct (off) (1v/div) output voltage v out (off) (1v/div) time t ( 50 s/div ) v in = 2.8 v, c in = 0.1 f, c out = 1 f i out = 50ma i out = 1ma v out =3.0 v (turn off waveform) control voltage v ct (off) (1v/div) output voltage v out (off) (1v/div) time t ( 50 s/div ) v in = 4.0 v, c in = 0.1 f, c out = 1 f i out = 50ma i out = 1ma
tcr2bf series, tcr2be series 2011-06-06 14 10) load transient response v out =1.0v (i out = 30ma to 1ma) output current i out (20ma/div) output voltage S v out (50mv/div) time t ( 100 s/div ) v in = 2.0 v, c in = 0.1 f, c out = 1 f v out =1.0v (i out = 1ma to 30ma) output current i out (20ma/div) output voltage S v out (50mv/div) time t (100 s/div ) v in = 2.0 v, c in = 0.1 f, c out = 1 f v out =1.0v (i out = 100ma to 50ma) output voltage S v out (50mv/div) output current i out (50ma/div) time t ( 100 s/div ) v in = 2.0 v, c in = 0.1 f, c out = 1 f v out =1.0v (i out = 50ma to 100ma) output voltage S v out (50mv/div) output current i out (50ma/div) time t ( 100 s/div ) v in = 2.0 v, c in = 0.1 f, c out = 1 f v out =1.8v (i out = 1ma to 30ma) output voltage S v out (50mv/div) output current i out (20ma/div) time t ( 100 s/div ) v in = 2.8 v, c in = 0.1 f, c out = 1 f v out =1.8v (i out =30ma to 1ma) output current i out (20ma/div) output voltage S v out (50mv/div) time t ( 100 s/div ) v in = 2.8 v, c in = 0.1 f, c out = 1 f
tcr2bf series, tcr2be series 2011-06-06 15 v out =3.0v (i out = 1ma to 30ma) output voltage S v out (50mv/div) output current i out (20ma/div) time t ( 100 s/div ) v in = 4.0 v, c in = 0.1 f, c out = 1 f v out =3.0v (i out = 50ma to 100ma) output voltage S v out (50mv/div) output current i out (50ma/div) time t ( 100 s/div ) v in = 4.0 v, c in = 0.1 f, c out = 1 f v out =3.0v (i out = 100ma to 50ma) output current i out (50ma/div) output voltage S v out (50mv/div) time t ( 100 s/div ) v in = 4.0 v, c in = 0.1 f, c out = 1 f v out =1.8v (i out = 50ma to 100ma) output voltage S v out (50mv/div) output current i out (50ma/div) time t ( 100 s/div ) v in = 2.8 v, c in = 0.1 f, c out = 1 f v out =1.8v (i out = 100ma to 50ma) output voltage S v out (50mv/div) output current i out (50ma/div) time t ( 100 s/div ) v in = 2.8 v, c in = 0.1 f, c out = 1 f v out =3.0v (i out =30ma to 1ma) output current i out (20ma/div) output voltage S v out (50mv/div) time t ( 100 s/div ) v in = 4.0 v, c in = 0.1 f, c out = 1 f
tcr2bf series, tcr2be series 2011-06-06 16 package dimensions smv (sot-25)(sc-74a) unit: mm weight : 16 mg (typ.)
tcr2bf series, tcr2be series 2011-06-06 17 package dimensions esv (sot-553) unit: mm weight: 3.0 mg (typ.)
tcr2bf series, tcr2be series 2011-06-06 18 restrictions on product use ? toshiba corporation, and its subsidiaries and affiliates (collect ively ?toshiba?), reserve the right to make changes to the in formation in this document, and related hardware, software a nd systems (collectively ?product?) without notice. ? this document and any information herein may not be reproduc ed without prior written permission from toshiba. even with toshiba?s written permission, reproduc tion is permissible only if reproducti on is without alteration/omission. ? though toshiba works continually to improve product?s quality and reliability, product can malfunction or fail. customers are responsible for complying with safety standards and for prov iding adequate designs and safeguards for their hardware, software and systems which minimize risk and avoid situations in which a ma lfunction or failure of product could cause loss of human life, b odily injury or damage to property, including data loss or corruption. before customers use the product, create designs including the product, or incorporate the product into their own applications, cu stomers must also refer to and comply with (a) the latest versions of all relevant toshiba information, including without limitation, this document, the specifications, the data sheets and application notes for product and the precautions and condi tions set forth in the ?toshiba semiconductor reliability handbook? and (b) the instructions for the application with which the product will be us ed with or for. customers are solely responsible for all aspe cts of their own product design or applications, including but not limited to (a) determining the appropriateness of the use of this product in such design or applications; (b) eval uating and determining the applicability of any info rmation contained in this document, or in c harts, diagrams, programs, algorithms, sample application circuits, or any other referenced documents; and (c) validating all operatin g parameters for such designs and applications. toshiba assumes no liability for customers? product design or applications. ? product is intended for use in general el ectronics applications (e.g., computers, personal equipment, office equipment, measur ing equipment, industrial robots and home electroni cs appliances) or for specif ic applications as expre ssly stated in this document . product is neither intended nor warranted for use in equipment or systems that require extraordinarily high levels of quality a nd/or reliability and/or a malfunction or failure of which may cause loss of human life, bodily injury, serious property damage or se rious public impact (?unintended use?). unintended use includes, without limitation, equipment used in nuclear facilities, equipment used in the aerospace industry, medical equipment, equipment used for automobiles, trains, ships and other transportation, traffic s ignaling equipment, equipment used to control combustions or explosions, safety dev ices, elevators and escalato rs, devices related to el ectric power, and equipment used in finance-related fields. do not use product for unintended use unless specifically permitted in thi s document. ? do not disassemble, analyze, reverse-engineer, alter, modify, translate or copy product, whether in whole or in part. ? product shall not be used for or incorporated into any products or systems whose manufacture, use, or sale is prohibited under any applicable laws or regulations. ? the information contained herein is pres ented only as guidance for product use. no re sponsibility is assumed by toshiba for an y infringement of patents or any other intellectual property rights of third parties that may result from the use of product. no license to any intellectual property right is granted by this document, whether express or implied, by estoppel or otherwise. ? absent a written signed agreement, except as provid ed in the relevant terms and conditions of sale for product, and to the maximum extent allowable by law, toshiba (1) assumes no liability whatsoever, including without limitation, indirect, co nsequential, special, or incidental damages or loss, including without limitation, loss of profit s, loss of opportunities, business interruption and loss of data, and (2) disclaims any and all express or implied warranties and conditions related to sale, use of product, or information, including warranties or conditions of merchantability, fitness for a particular purpose, accuracy of information, or noninfringement. ? do not use or otherwise make available product or related so ftware or technology for any military purposes, including without limitation, for the design, development, use, stockpiling or m anufacturing of nuclear, chemical , or biological weapons or missi le technology products (mass destruction w eapons). product and related software and technology may be controlled under the japanese foreign exchange and foreign trade law and the u.s. expor t administration regulations. ex port and re-export of product or related software or technology are strictly prohibited exc ept in compliance with all applicable export laws and regulations. ? please contact your toshiba sales representative for details as to environmental matters such as the rohs compatibility of pro duct. please use product in compliance with all applicable laws and regula tions that regulate the inclusion or use of controlled subs tances, including without limitation, the eu rohs directive. toshiba assumes no liability for damages or losses occurring as a result o f noncompliance with applicable laws and regulations.
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