SSM6L13TU 2010-07-10 1 0.3-0.05 6 1.70.1 2.10.1 1.30.1 1 2 0.65 0.65 3 2.00.1 0.16-0.05 5 4 0.70.05 +0.1 +0.06 1.source1 2.gate1 3.drain2 4.source2 5.gate2 6.drain1 toshiba field-effect transistor silicon p / n channel mos type SSM6L13TU power management switch applications high-speed switching applications ? 1.8-v drive ? n?ch , p?ch 2?in?1 ? low on?resistance: nch r ds(on) = 235 m ? (max) (@v gs = 1.8 v) ? r ds(on) = 178 m ? (max) (@v gs = 2.5 v) ? : pch r ds(on) = 460 m ? (max) (@v gs = ? 1.8 v) ? r ds(on) = 306 m ? (max) (@v gs = ? 2.5 v) q1 absolute maximum ratings (ta = 25 c) characteristic symbol rating unit drain-source voltage v ds 20 v gate-source voltage v gss 12 v dc i d 0.8 drain current pulse i dp 1.6 a q2 absolute maximum ratings (ta = 25 c) characteristic symbol rating unit drain-source voltage v ds ?20 v gate-source voltage v gss 8 v dc i d ?0.8 drain current pulse i dp ?1.6 a absolute maximum ratings (q1 , q2 common) (ta = 25 c) characteristic symbol rating unit power dissipation p d (note 1) 500 mw channel temperature t ch 150 c storage temperature range t stg ?55 to 150 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. 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: mounted on an fr4 board (total dissipation) (25.4 mm 25.4 mm 1.6 mm, cu pad: 645 mm 2 ) marking equivalent circuit (top view) unit: mm uf6 jedec D jeita D toshiba 2-2t1b weight: 7 mg (typ.) 6 kv 4 1 2 3 5 q1 q2 654 123
SSM6L13TU 2010-07-10 2 q1 electrical characteristics (ta = 25c) characteristic symbol test conditions min typ. max unit v (br) dss i d = 1 ma, v gs = 0 20 ? ? drain-source breakdown voltage v (br) dsx i d = 1 ma, v gs = ? 12 v 10 ? ? v drain cutoff current i dss v ds = 20 v, v gs = 0 ? ? 1 a gate leakage current i gss v gs = 12 v, v ds = 0 ? ? 1 a gate threshold voltage v th v ds = 3 v, i d = 1 ma 0.4 ? 1.0 v forward transfer admittance ? y fs ? v ds = 3 v, i d = 0.6 a (note 2) 2.3 3.75 ? s i d = 0.6 a, v gs = 4.0 v (note 2) ? 116 143 i d = 0.4 a, v gs = 2.5 v (note 2) ? 134 178 drain-source on-resistance r ds (on) i d = 0.2 a, v gs = 1.8 v (note 2) ? 160 235 m input capacitance c iss v ds = 10 v, v gs = 0, f = 1 mhz ? 268 ? pf output capacitance c oss v ds = 10 v, v gs = 0, f = 1 mhz ? 44 ? pf reverse transfer capacitance c rss v ds = 10 v, v gs = 0, f = 1 mhz ? 34 ? pf turn-on time t on ? 9 ? switching time turn-off time t off v dd = 10 v, i d = 0.25 a, v gs = 0 to 2.5 v, r g = 4.7 ? 16 ? ns drain-source forward voltage v dsf i d = ? 0.8 a, v gs = 0 v (note 2) ? ? 0.8 ? 1.15 v note 2 : pulse test q2 electrical characteristics (ta = 25c) characteristic symbol test conditions min typ. max unit v (br) dss i d = ? 1 ma, v gs = 0 ? 20 ? ? drain-source breakdown voltage v (br) dsx i d = ? 1 ma, v gs = + 8 v ? 12 ? ? v drain cutoff current i dss v ds = ? 20 v, v gs = 0 ? ? ? 10 a gate leakage current i gss v gs = 8 v, v ds = 0 ? ? 1 a gate threshold voltage v th v ds = ? 3 v, i d = ? 1 ma ? 0.3 ? ? 1.0 v forward transfer admittance ? y fs ? v ds = ? 3 v, i d = ? 0.6 a (note 2) 1.5 2.5 ? s i d = ? 0.6 a, v gs = ? 4.0 v (note 2) ? 175 234 i d = ? 0.4 a, v gs = ? 2.5 v (note 2) ? 230 306 drain-source on-resistance r ds (on) i d = ? 0.1 a, v gs = ? 1.8 v (note 2) ? 300 460 m input capacitance c iss v ds = ? 10 v, v gs = 0, f = 1 mhz ? 250 ? pf output capacitance c oss v ds = ? 10 v, v gs = 0, f = 1 mhz ? 45 ? pf reverse transfer capacitance c rss v ds = ? 10 v, v gs = 0, f = 1 mhz ? 35 ? pf turn-on time t on ? 12 ? switching time turn-off time t off v dd = ? 10 v, i d = ? 0.25 a, v gs = 0 to ? 2.5 v, r g = 4.7 ? 18 ? ns drain-source forward voltage v dsf i d = 0.8 a, v gs = 0 v (note 2) ? 0.85 1.2 v note 2: pulse test
SSM6L13TU 2010-07-10 3 q1 switching time test circuit (a) test circuit (b) v in q2 switching time test circuit q1 precaution v th can be expressed as the voltage between gate and sour ce when the low operating current value is i d = 1 ma for this product. for normal switching operation, v gs (on) requires a higher voltage than v th, and v gs (off) requires a lower voltage than v th. (the relationship can be established as follows: v gs (off) < v th < v gs (on). ) take this into consideration when using the device. q2 precaution v th can be expressed as the voltage between gate and sour ce when the low operating current value is i d = ? 1 ma for this product. for normal switching operation, v gs (on) requires a higher voltage than v th, and v gs (off) requires a lower voltage than v th. (the relationship can be established as follows: v gs (off) < v th < v gs (on). ) take this into consideration when using the device. handling precaution when handling individual devices that are not yet mounted on a circuit board, make sure that the environment is protected against electrostatic discharge. operators should wear antistatic clothing , and containers and other objects that come into direct contact with devices should be made of antistatic materials. thermal resistance r th (ch-a) and power dissipation p d vary depending on board material, board area, board thickness and pad area. when using this device, please ta ke heat dissipation into consideration. (c) v out v dd = 10 v r g = 4.7 duty 1% v in : t r , t f < 5 ns common source ta = 25 c v dd out in 2.5 v 0 10 s r g t f t on 90 % 10 % 2.5 v 0 v 90 % 10 % t off t r v dd v ds ( on ) v dd = - 10 v r g = 4.7 duty 1 % v in : t r , t f < 5 ns common source ta = 25 c in 0 ? 2.5 v 10 s v dd out r g r l (c) v out t on 10 % 90 % ?2.5 v 0 v 90 % 10 % t off t r t f v ds ( on ) v dd (b) v in (a) test circuit
SSM6L13TU 2010-07-10 4 q1 data id - vgs 0.0001 0.001 0.01 0.1 1 10 012 `?`g?R vgs (v) ?? id (a) ta=85c 25c -25c `? vds=3v vth - ta 0 0.2 0.4 0.6 0.8 1 -60 -40 -20 0 20 40 60 80 100 120 140 160 ???ta() `??Rvth(v) `? id=1ma vds=3v id - vds 0 1 2 00.20.40.60.81 ???`g?R vds (v) ?? id (a) vgs=1.2v 1.5 1.8 2.5 4 10 `? ta=25 rds(on) - id 0 100 200 300 012 ?? id (a) ???`g? rds(on) (m) vgs=4 v 2.5v 1.8v ` ? ta=25 rds(on) - vgs 0 100 200 300 012345678910 `?`g?R vgs (v) ???`g? rds(on) (m) id=0.2a 0.6a 0.4a `? ta=25c rds(on) - ta 0 50 100 150 200 250 300 -60 -40 -20 0 20 40 60 80 100 120 140 160 ???ta() ???`g? rds(on)(m) vgs=4v,id=0.6a 2.5v,0.4a 1.8v,0.2a `? drain current i d (a) drain?source voltage v ds (v) drain current i d (a) gate?source voltage v gs (v) common source ta = 2 5 c pulse test common source v ds = 3 v pulse test drain?source on-resistance r ds (on) (m ? ) common source ta = 25 c pulse test gate?source voltage v gs (v) common source pulse test drain?source on-resistance r ds (on) (m ? ) ambient temperature ta (c) drain?source on-resistance r ds (on) (m ? ) drain current i d (a) ambient temperature ta (c) gate threshold voltage v th (v) common source ta = 25 c pulse test common source v ds = 3 v i d = 1 ma
SSM6L13TU 2010-07-10 5 q1 data |yfs| - id 0.1 1.0 10.0 0.01 0.1 1 10 ?? id (a) ?_?? |yfs| (s) `? vds=3v ta=25 c - vds 10 100 1000 0.1 1 10 100 ???`g?R vds (v) c (pf) ciss coss crss `? vgs=0v f=1mhz ta=25 ta=85c 25c -25c t - id 1 10 100 1000 0.01 0.1 1 10 ?? id (a) ???rg t (ns) toff tr ton tf `? vdd=10v vgs=02.5v ta=25 idr - vds 0.001 0.01 0.1 1 10 -1 -0.8 -0.6 -0.4 -0.2 0 ???`g?R vds (v) ?? idr (a) s idr g d `? vgs=0v ta=25 ta=85c 25c -25c common source v ds = 3 v i d = 1 ma pulse test forward transfer admittance ? y fs ? (s) drain current i d (a) common source v gs = 0v ta = 2 5 c pulse test drain reverse current i dr (a) drain?source voltage v ds (v) capacitance c (pf) common source ta = 25 c f = 1 mhz v gs = 0 v drain-source voltage v ds (v) common source v dd = 10 v v gs = 0 to 2.5 v ta = 25 c switching time t (ns) drain current i d (a)
SSM6L13TU 2010-07-10 6 q2 data id - vgs -0.0001 -0.001 -0.01 -0.1 -1 -10 -0 -1 -2 `?`g?R vgs (v) ?? id (a) ta=85c 25c -25c `? vds=-3v vth - ta -0 -0.2 -0.4 -0.6 -0.8 -1 -60 -40 -20 0 20 40 60 80 100 120 140 160 ??? ta() `??Rvth(v) `? id=-1ma vds=-3v id - vds -0 -1 -2 -0.0 -0.2 -0.4 -0.6 -0.8 -1.0 ???`g?R vds (v) ?? id (a) vgs=-1 .2 v -1.5 -1.8 -2.5-4.0 -10 `? ta=25 rds(on) - id 0 50 100 150 200 250 300 350 400 -0 -1 -2 ?? id (a) ???`g? rds(on) (m) vgs=-4 v -2.5v -1.8v `? ta=25 rds(on) - vgs 0 100 200 300 400 500 -0 -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 `?`g?R vgs (v) ???` g? rds(on) (m) id=-0.1 a -0.6 a -0.4 a `? ta=25c rds(on) - ta 0 100 200 300 400 500 -60 -40 -20 0 20 40 60 80 100 120 140 160 ??? ta() ???` g? rds(on) (m) vgs=-4 v,id =-0 .6 a -2.5v,-0.4 a -1.8v,-0.1 a `? drain current i d (a) drain current i d (a) drain?source on-resistance r ds (on) (m ? ) drain?source on-resistance r ds (on) (m ? ) common source ta = 25 c pulse test common source v ds = -3 v pulse test drain?source voltage v ds (v) gate?source voltage v gs (v) gate?source voltage v gs (v) ambient temperature ta (c) common source ta = 25 c pulse test common source pulse test drain?source on-resistance r ds (on) (m ? ) ambient temperature ta (c) drain current i d (a) common source v ds = -3 v i d = -1 ma gate threshold voltage v th (v) 0 0 0 0 0 0 common source ta � 25c pulse test
SSM6L13TU 2010-07-10 7 q2 data |yfs | - id 0.1 1.0 10.0 -0.01 -0.1 -1 -10 ?? id (a) ?_?? |yfs| (s) `? vds=-3v ta=25 c - vds 10 100 1000 -0.1 -1 -10 -100 ???`g?R vds (v) c (pf) ciss coss crss `? vgs=0v f=1mhz ta=25 ta=85c 25c -25c t - id 1 10 100 1000 -0.01 -0.1 -1 -10 ?? id (a) ???rg t (ns) toff tr ton tf `? vdd=-10v vgs=0-2.5v ta=25 idr - vds 0.001 0.01 0.1 1 10 0 0.2 0.4 0.6 0.8 1 ???`g?R vds (v) ?? idr (a) `? vgs=0v ta=25 ta=85c 25c -25c pd - ta 0 200 400 600 800 1000 0 20 40 60 80 100 120 140 160 ?? ta() S?p? pd(mw) fr4g?r (25.4mm25.4mm1.6t) cu pad :645mm2 ?????g?r (25.4mm25.4mm0.8t) cu pad :645mm 2 1 10 100 1000 0.001 0.01 0.1 1 10 100 1000 single pulse a : mounted on ceramic board (25.4mm25.4mm0.8mm) cu pad :25.4mm25.4mm b : mounted on fr4 board (25.4mm25.4mm1.6mm) cu pad :25.4mm25.4mm c : mounted on fr4 board (25.4mm25.4mm1.6mm) cu pad :0.45mm0.8mm3 a b c ^?? r th (c /w) common source v ds = -3 v ta = 25c pulse test common source v dd = -10 v v gs = 0 to -2.5 v ta = 2 5 c r g = 4.7 �: drain current i d (a) forward transfer admittance � y fs � (s) drain current i d (a) switching time t (ns) drain reverse current i dr (a) drain?source voltage v ds (v) drain-source voltage v ds (v) capacitance c (pf) common source ta � 25 c f � 1 mhz v gs � 0 v ambient temperature ta (c) ppower dissipation p d (mw) rth - tw pulse width t w (s) * transient thermal impedance r th (c/w ) (1): mounted on fr4 board (25.4mm �u 25.4mm �u 1.6mm) cu pad : 645 mm 2 ) (2): mounted on ceramic board (25.4mm �u 25.4mm �u 0.8mm) cu pad : 645 mm 2 ) common source v gs =0v ta � 25c pulse test
SSM6L13TU 2010-07-10 8 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. ? a bsent 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. ? 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