o product structure : silicon monolithic integrated circuit o this product has no designed protection against radioactive ra ys 1/ 28 tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 14 ? 001 optocoupler - less isolated flyback converter bd7f100hfn - lb bd7f100efj - lb general description this product guarantees long time supply availability i n the industrial instrumentation market. bd7f100 is an optocoupler - less isolated flyback converter . an optocoupler or the tertiary winding feedback circuit which was needed to obtain a stable output voltage isolated by a transformer in the conventional application becomes unnecessary, thus, the number of parts is reduced drastically, producing a small - sized and high - reliability application isolated type power supply. furthermore, a highly by the use of the original adapted - type on - time control technology , it makes the external phase compensation parts become unnece ss ary, therefore a highly efficient isolated type power supply application can easily be produced. features ? guaranteed long time supply availability for industrial applications. ? no need for an optocoupler or a transformer tertiary winding. the output voltage can be set by two external resistors and the transformer turns ratio. ? uses original adapted type on - time control technology. high - speed load response is realized and external phase compensation parts are unnecessary. ? fixed switching frequency and low output ripple ? highly efficient light load mode available (pfm operation) ? shutdown / enable control ? built - in n - channel mosfet ? soft start function ? output load compensation function ? protection functions: vin under voltage lock - out (vin uvlo) over current protection (ocp) thermal shutdown protection (ts d) application ? industrial equipment isolated power supply key specifications ? supply voltage of operation : 3v to 40v ? sw terminal operating voltage : 50v (max) ? over current limit: 1.25a (typ) ? switching frequency: 400 khz (typ) ? reference voltage accuracy: 1.5% ? quiescent current: 0a (typ) ? operating current: 2ma (typ) ? junction temperature of operation: - 40 c to +125c packages w(typ) d(typ) h(max ) hson8 2.90mm x 3.00mm x 0.60mm ht so p - j8 4.90mm x 6.00mm x 1.00mm hson8 ht so p - j8 datashee t downloaded from: http:///
2/ 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 typical application circuit pin configuration pin descriptions pin no. pin name function 1 agnd analog system gnd 2 sdx/en shutdown/enable control 3 comp load current compensation of the output voltage set up 4 ref output voltage setup 5 fb output voltage setup 6 pgnd power system gnd 7 sw switching output 8 vin power supply (top view) v in sw fb agnd ref pgnd sdx/en comp 7 8 6 5 3 4 2 1 fb sw vin v out+ v out- sdx/en comp agnd ref pgnd v in BD7F100HFN-LB downloaded from: http:///
3/ 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 block diagram fb sw driver adaptive on-time controller vref soft start comparator vin internal regulator sdx/en load compensation vin uvlo pgnd comp ref agnd n-channel mosfet shutdown ocp tsd enable vref current monitor description of blocks 1. internal regulator this is the regulator block for internal circuits. also includes a reference voltage generating block (vref). this block is in the shutdown state when the sdx/en terminal is below 0.9v (typ). 2. vin uvlo this is the input low - voltage - protection block. if the power supply input voltage, v in , falls to below 2.5v (typ), it will be detected and this bl ock will be in the protection state and the sw terminal becomes hi - z. when the power supply input voltage (v in ) rises to 2.65v (typ), it automatically recovers thorough the soft start. (hysteresis voltage: 0.15v (typ).) 3. soft start when the sdx/en terminal is in the enable state with more than 2 .0v (typ), this block prevents inrush current and overshoot in the rising of the output voltage by making the referen ce voltage of the comparator block rise slowly from 0v to vref voltage. the default soft start time, t ss , is designed to be 6ms (typ) internally. the min off time is 750ns (typ) when the output voltage is below 50 % of the set voltage. 4. comparator this is the block which compares the reference voltage vref w ith the ref terminal voltage which is the feedback voltage of the sw terminal voltage. since the feedback loop is structured by a comparator is establis hed, it has excellent response to load fluctuati on. 5. adaptive on - time controller this is the block corresponding to the original adapted typ e on - time control technology. switching frequency is fixed at 400khz (typ) under pwm control when t he load is stable. under on - time control, when the load varies, fast load response is enable d by changing the switching frequency. during light load, the highly efficient pfm will operate and the self - power dissipation is suppressed by decreasing the switching frequency. 6. driver this is the block which drives the built - in n - channel mosfet. downloaded from: http:///
4/ 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 description of blocks - continued 7. load compensation this is the block which compensates the output voltage re gulation by vf characteristic fluctuation of the secondary sid e output diode according to the load current. the current which flows into the built - in n - channel mosfet is monitored, and the current according to the compensation quantity and the time constant which are determined by the external resistor and the capacitor of the comp terminal is drawn from the ref terminal. the output voltage rises and is re ctified when feedback current which flows into the external resistor of the ref terminal decreases and the ref terminal voltage fa lls. 8. tsd this is the temperature protection block. if the chips junction temperature, tj, inside the ic is abov e 175c (typ), it will be detected and this block will be in the protection state and the sw terminal becomes hi - z. if tj falls to below 150c (typ), it will return automatically through soft start. 9. ocp this is the over - current protection block. if the peak current during the on - time of the built - in n - channel mosfet reaches 1.25a (typ), it will be detected and the n - channel mosfet is turned off. if output voltage goes to 50% or less of the setting volta ge, the peak detection current of ocp will be controlled by 0.625a (typ).the min off time is 1.5s (typ) when the ocp is opera ted under the condition where the output voltage is 50% o f the set voltage. absolute maximum ratings (ta = 25 c) parameter symbol rating unit bd7f100hfn - lb bd 7f100efj - lb vin input power voltage (note 1) v in 45 v sw terminal voltage v sw 60 v sdx/en terminal voltage v sdx/en v in v fb terminal voltage v fb v in - 0.3v to v in v ref terminal voltage v ref 7 v comp terminal voltage v comp 7 v power dissipation pd 1.75 (note 2) 3.75 (note 3) w storage temperature range tstg - 55 to +150 c maximum junction temperature tjmax 150 c (note 1) not to exceed power dissipation ( pd ). (note 2) reduced by 14.0mw/ c for temperatures above 25 c (when mounted on a one - layer glass - epoxy board with 70mm 70mm 1.6mm dimension, 65% copper foil density) (note 3) reduced by 30.0mw/ c for temperatures above 25 c (when mounted on four - layer glass - epoxy board with 70mm 70mm 1.6mm dimension.) caution: operating the ic over the absolute maximum ratings may damage the i c. the damage can either be a short circuit between pins or an open circuit between pins and the internal circuitry. therefore, it is important to conside r circuit protection measures, such as adding a fuse, in case the ic is oper ated over the absolute maximum ratings. recommended operating conditions parameter symbol limit unit min typ max vin input power voltage v in 3 24 40 v sw terminal voltage v sw - - 50 v junction temperature (note4) tj - 40 - +125 c (note 4) life time is derated at junction temperature greater than 125 c . downloaded from: http:///
5/ 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 electrical characteristics (unless otherwise specified ta = 25c, v in = 24v, and v sdx/en = 2.5v.) parameter symbol limit unit conditions min typ max power supply quiescent current i st - 0 10 a v sdx/en = 0v operating current i cc - 2 4 ma v sdx/en = 2.5v v ref = 2v (at pfm operation) uvlo detection voltage v uvlo 2.3 2.5 2.7 v v in falling uvlo hysteresis voltage v uv lo_hys 0.1 0.15 0.2 v sdx/en control shutdown voltage v sdx 0.3 0.9 1.5 v enab le voltage v en 1.9 2.0 2.1 v v sdx/en rising enab le hysteresis voltage v en_hys 0.15 0.2 0.25 v sdx/en in put current i sdx/en - 0 1 a v sdx/en =2v re ference voltage reference voltage v ref 0.768 0.78 0.792 v switch characteristics on - resistance r on - 0.5 - between sw - pgnd terminals over current limit i limit 1 1.25 1.5 a switching frequency f sw - 400 - khz at pwm operatio n (duty=40%) minimum on time t on_min - 350 - ns minimum off time t off_min - 300 - ns maximum off time t off_max - 20 - s soft start time t ss - 6 - ms 0v to (v ref 90%) downloaded from: http:///
6/ 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 typical performance curves 0 1 2 3 4 5 6 7 8 0 5 10 15 20 25 30 35 40 45 50 maximum output power (w) vin voltage (v) restriction by the current limit 1a (min) restriction by the sw terminal voltage 50v (max) maximum output power is restricted in general by a curren t limit and the maximum operating voltage of sw terminal. furthermore, it also changes with the characteristics of external parts (transformer, schottky barrier diode, snubber circuit, etc.). maximum output power [w] vin voltage [v] figure 1. maximum output power vs vin voltage downloaded from: http:///
7/ 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 typical performance curves figure 3. operating current vs vin voltage figure 2. quiescent current vs vin voltage 0 0.5 1 1.5 2 2.5 0 10 20 30 40 operating current [ma] vin voltage [v] ref=2v comp=0v 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 0 10 20 30 40 quiescent current [ a] vin voltage [v] sdx/en=0v 0 5 10 15 20 25 30 35 40 0 5 10 15 20 25 30 35 40 sdx/en input current [ a] sdx/en voltage [v] figure 4. sdx/en in pu t current vs sdx/en voltage 0 50 100 150 200 250 300 350 400 450 500 20 25 30 35 40 45 50 switching frequency [khz] duty [%] figure 5. switching frequency vs duty downloaded from: http:///
8/ 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 typical performance curves figure 9. load transient response (24v input, 5v output, with lo ad compensation, and i out = 300m a < - > 1 a) figure 6. efficiency vs load current (24v input, 5v output) 0 10 20 30 40 50 60 70 80 90 100 0 200 400 600 800 1000 efficiency [%] load current [ma] 4.5 4.55 4.6 4.65 4.7 4.75 4.8 4.85 4.9 4.95 5 -50 0 50 100 150 output voltage [v] ambient temperature [ c] i out =1a no load compensation figure 7. output voltage vs load current (24v input, 5v output) 4.75 4.8 4.85 4.9 4.95 5 5.05 5.1 5.15 5.2 5.25 0 200 400 600 800 1000 output voltage [v] load current [ma] with load compensation r comp =43k no load compensation figure 8. output voltage vs ambient temperature (24v input, 5v output) i out : 500ma/d iv v out : 500mv/d iv time : 1ms/d iv downloaded from: http:///
9/ 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 typical performance curves v in : 20v/d iv figure 10 . start up waveforms (sdx/en control) (24v input, 5v output , sdx/en=0v - >2.5v) v in : 20v/d iv sdx/en : 2 v/d iv v out : 2 v/d iv sw : 20v/d iv figure 11. shutdown waveforms (sdx/en control) (24v input, 5v output, sdx/en=2.5v - >0v) time : 4ms/d iv v in : 20v/d iv sdx/en : 2 v/d iv v out : 2 v/d iv sw : 20v/d iv time : 4ms/d iv figure 13. shutdown waveforms (vin control) (24v input, 5v output , vin=24v - >0v, r 1 =1m, r 2 =120k) figure 12 . start up waveforms (vin control) (24v input, 0v output , vin=0v - >24v, r 1 =1m, r 2 =120k) sdx/en : 2 v/d iv v out : 2 v/d iv sw : 20v/d iv v in : 20v/d iv sdx/en : 2 v/d iv v out : 2 v/d iv sw : 20v/d iv time : 4ms/d iv time : 4ms/d iv downloaded from: http:///
10 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 typical performance curves figure 15. output voltage vs load current (24v input, 15v output) figure 16. output voltage vs ambient temperature (24v input, 15v output) 14.5 14.6 14.7 14.8 14.9 15 15.1 15.2 15.3 15.4 15.5 -50 0 50 100 150 output voltage [v] ambient temperature [ c] i out =330ma ( total) no load compensation 14.5 14.6 14.7 14.8 14.9 15 15.1 15.2 15.3 15.4 15.5 0 100 200 300 400 output voltage [v] load current [ma] with load compensation r comp =9.1k no load compensation figure 14. efficiency vs load current (24v input, 15v output) 0 10 20 30 40 50 60 70 80 90 100 0 100 200 300 400 efficiency [%] load current [ma] downloaded from: http:///
11 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 application examples ex ercise caution with the actual system since the characteristic ch anges with the board layout a nd the types of external parts mounted, and etc. table1. recommended transformers part number size (w l h) [mm] l p [ h] n p : n s v endor target applications v in [v] v out [ v] i out [ a] cep1311d - 2405051r 13.5 20.0 12.5 63 3 : 1 sumida electric 24 5 1 cep911b - 2405051r 10.0 10.0 11.5 63 3 : 1 sumida electric 24 5 0.8 cep1311d - 2415052r 13.5 20.0 12.5 50 1 : 1 : 1 sumida electric 24 15 0.165 cep911b - 0505051r 10.0 10.0 11.5 10 1 : 2 sumida electric 5 5 0.2 figure 19. 5v input, 5v output figure 17. 24v input, 5v output figure 18. 24v input, 15v output fb sw vin v out + 5v, 1a v out - sdx/en comp agnd ref pgnd v in 24v 10f r dummy 330 ? 47f 3.9k ? 63h 7h BD7F100HFN-LB 3 : 1 80.6k ? d 2 d 1 z 1 t 1 t 1 : sumida electric cep1311d-2405051r z 1 : rohm kdz18b d 1 : rohm 1ss400sm d 2 : rohm rb160m-40 1000pf 1k ? fb sw vin sdx/en comp agnd ref pgnd v in 24v 10f 10f 3.9k ? 50h BD7F100HFN-LB 1 : 1 : 1 76.8k ? v out + 15v,165ma com 50h 50h 10f r dummy 4.7k ? v out - -15v, -165ma r dummy 4.7k ? d 2 d 3 d 1 z 1 t 1 t 1 : sumida electric cep1311d-2415052r z 1 : rohm kdz18b d 1 : rohm 1ss400sm d 2 ,d 3 : rohm rb160m-90 470 ? 4700pf fb sw vin v out + 5v, 200ma v out - sdx/en comp agnd ref pgnd v in 5v 10f r dummy 1k ? 22f 3.9k ? 10h 40h d 1 BD7F100HFN-LB 1 : 2 13.3k ? d 2 z 1 t 1 : sumida electric cep911b-0505051r z 1 : rohm kdz5.6b d 1 : rohm 1ss400sm d 2 : rohm rb160m-40 t 1 1k ? 1000pf downloaded from: http:///
12 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 application information 1. outline operation this product is an isolated type flyback converter without an optocoupler . an optocoupler or a transformers tertiary winding feedback circuit which was needed to obtain a stable ou tput voltage isolated by a transformer in the conventional application becomes unnecessary, thus, the number of parts is reduced drasticall y, producing a small - sized and high - reliability application isolated type power supply. furthermore, a highly efficient isolated type power supply a pplication can easily be produced the use of the origina l adapted - type on - time control technology which eliminates the need for extern al phase compensation parts. the off time is determined by comparing the reference voltage inside the ic with the information which was obtained by the feedback of the secondary output voltage through primary flyback voltage. adapted - type on time control, (1) switching frequency is fixed at 400khz (typ) for pwm operation when t he load stabilizes. (2) during load current fluctuation, the on - time control will operate and the switching frequency will c hange, thus a high - speed load response is obtained. (3) during light load, high efficiency is obtained because the swi tching frequency decreases. 2. timing chart (1)start - up/shut - down output voltage gradually turns on through the soft start function when sdx/en terminal rises to above 2.0v(typ) (enable state) .when sdx/en terminal falls below 1.8v (typ), output voltage turns off (disable state). (note 1) in the control system of this ic, it has to be operated where duty is below 50%. when turning on/off the ic , control the sdx/en terminal as enable/disable under the condition wh ere v in fulfills below equation. ? ? ][ v f out s p in v v n n v ? ? ? where: v in is the vin input power voltage n p is the number of turns in the transformer primary side n s is the number of turns in the transformer secondary side v out is the output voltage v f is the forward voltage of the output diode in the secondary side if sdx/en terminal is connected to vin terminal, duty could be more than 50 % and unexpected output voltage might occur when turning on/off. please refer to 8. enable voltage on page 16 of the application information for the enable control with vin terminal. v in sdx/en (note1) (note1) v out 2v 1.8v v out 0.9 tss figure 20 . start - up/shut - down timing chart downloaded from: http:///
13 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 (2) vin under voltage lock - out (vin uvlo) when the input voltage (v in ) falls below 2.5v (typ), it will be detected, followed by sw terminal becomes hi - z then output turns off. when the input voltage (v in ) rises to above 2.65v (typ), it automatically recovers thorough the soft start. (hysteresis voltage: 0.15v (typ )) (3) thermal shutdown protection (tsd) when the internal chip (junction) temperature exceeds tj=175c (typ) ,it will be detected, followed by sw terminal be comes hi - z, then output turns off. when tj decreases below 150c (typ), it automatically recovers thr ough the soft start. note that the thermal shutdown circuit is designed to sh utdown the ic from thermal runaway under abnormal circumstanc es with the temperature exceeding tjmax = 150c. it is not design ed to protect or guarantee the application set. please refr ain from using this function as a protection design of the applic ation set. (4) over current protection (ocp) when the peak current reaches 1.25a (typ) during the built - in n - channel mosfet is on, it will be detected, followed sw terminal becomes hi - z, then n - channel mosfet turns off. it is detect ed per switching cycle, and output voltage decreases as on duty is limited. figure 22. tsd timing chart figure 21 . vin uvlo timing chart figure 23 . ocp timing cha rt v in v out sw vin uvlo on vin uvlo off 2.5v 2.65v tss v out 0.9 0v sw v out vin tj=175 tj tsd on tsd off tj=150 tss v out 0.9 v out i p (primary transformer current) normal i limit =1.25a sw normal over current i out (load current) downloaded from: http:///
14 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 3 output voltage sw terminal voltage is higher than input voltage (v in ) when the built - in n - channel mosfet is off. this primary flyback voltage (the gap between sw terminal voltage a nd v in ) contains the information of the secondary output voltage. sw terminal voltage can be calculated as follows: ? ? ][ v esr i v v n n v v s f out s p in sw ? ? ? ? ? ? where: v sw is the sw terminal voltage i s is the transformer current in the secondary side esr is the total impedance in the secondary side (transformer wirewound resistance of the secondary side, pcb impedance, and etc.) this primary flyback voltage is converted to the current i rfb by rfb resistor. as fb terminal voltage almost equals to vin voltage due to the differential circuit of vin, i rfb can be expressed by following equation: fb fb sw rfb r v v i ? ? ? ? ][ a fb s f out s p r esr i v v n n ? ? ? ? ? where: i rfb is the fb input current v fb is the fb terminal voltage r fb is the external resistance between the fb - sw terminals ref terminal voltage can be expressed as follows since i rfb flows into r ref resister. ? ? ][ v esr i v v n n r r v s f out s p fb ref ref ? ? ? ? ? ? where: v ref is the ref terminal voltage r ref is the external resistance between the refCagnd terminals (the ic is designed on the assumption that this value is 3.9k.) the ref terminal voltage is in put into the comparator and compared with the ic internal reference v oltage (0.78v(typ)) . since the loop gain of the whole system is high, the ref terminal vo ltage can be equal to the reference voltage in the ic. therefore, the output voltage v out and the ref terminal voltage v ref are as follows: ][ v esr i v v n n r r v s f ref p s ref fb out ? ? ? ? ? ? that is, the output voltage v out can be set by the primary and secondary side turns ratio o f the transformer, and the ratio of the resistances r fb and r ref . v f and esr cause an output voltage error. the feedback resistor r fb can be expressed as follows from the relative quation with v out : ? ? ][ esr i v v n n v r r s f out s p ref ref fb ? ? ? ? ? ? figure 24. control block diagram comparator v f v out v in v in adaptive on-time controller r comp i p n p /n s i comp 0.78v i s v ref v comp current monitor comp ref fb sw pgnd c comp 25k r ref i rfb r fb driver v in <60v <50v v sw time ? ? esr i v v n n s f out s p ? ? ? figure 25. primary flyback voltage = primary flyback voltage downloaded from: http:///
15 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 4 transformer (1) turns ratio turns ration is the parameter which determines the output v oltage, maximum output voltage, duty and sw terminal voltage.the duty of a flyback converter can be expressed by the f ollowing equation: ? ? ? ? f out s p in f out s p v v n n v v v n n duty ? ? ? ? ? ? feedback voltage is monitored by the sw terminal and du ty needs to be below 50% for the stable control. the minimu m duty will be 20% due to the limitation of the min on time and the turn s ratio needs to fulfill below conditions: f out in s p f out in v v v n n v v v 4 1 ? ? ? ? ? (2) primary side inductance flyback converter has the secondary pole from the primary in ductance and the secondary output capacitor. therefore, for operational stability, selection of the primary side induc tance value is important. in addition, as the primary inductance influences the maximum load, please follow below conditions: ? ? ][ _ _ _ h sw out_max f out 2 in p max out max out in min limit 2 2 in f i v v v duty 2 l i v v duty i duty t v 2 1 ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? where: l p is primary side inductance t is switching output cycle is efficiency i limit_min is minimum over current limit i out_max is maximum load current f sw is switching frequency (3) leakage inductance transformer leakage inductance causes sw terminal ringing when the built - in n - channel mosfet turns off. a snubber circuit is recommended in order to avoid the peak voltage of the ringing from exceeding the absolute maximum rating (60v). furthermore, after a voltage spike occurs , ringing is also caused. in order to prevent erroneous detection of the secondary output voltage, the ringing must be co nverged within 250ns (typ). when the built - in n - channel mosfet turns on, reverse spike voltage in the output diod e is generated. note that this spike voltage must not exceed the diode rating voltage. (4) winding resistance either primary or secondary winding resistance will reduc e overall power efficiency. moreover, secondary winding resistance lowers the output voltage. therefore, a transformer with sm aller winding resistance is recommended. (5) saturation current the current in the primary transformer will not be transferred to the se condary if the core is saturated due to the exceeded current. when the core is saturated, the inductance val ue decreases and the current drastically increases. the current in the transformer should not exceed its rated saturati on current. downloaded from: http:///
16 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 5 output capacitor selecting the secondary si de output capacitor value is important for a stable operation. please select the value which fulfils below condition. ][ . f 2 s p p 9 out duty n n l 1 10 6 1 c ? ?? ? ? ?? ? ? ? ? ? ? ? where: c out is output capacitor in addition, as secondary side output voltage rises through s oft start time (t ss ), please consider below equation when choosing an output capacitor. over current protection operates du e to the inrush current especially when the capacitance value is extremely large, thus, start - up failure might occur. ? ? ][ _ _ f out max out s p min limit ss out v i duty 1 n n i t 2 1 c ? ? ? ? ? ? ? ? ? ? ?? ? ? ?? ? ? ? ? ? where: t ss is soft start time 6 in put capacitor use ceramic capacitor for the input capacitor and place the input ca pacitor as close as possible to vin terminal. please refer to the pcb layout design guidelines on page 20 for the design as malfunctions might occur due to the la yout pattern or the position of the capacitor. as for the capacitance value of the input capacitor, the ripple v oltage of vin terminal needs to be below 4% of the input voltage. and, make sure that ripple voltage is suppressed when load c hanges or start up. 7 output diode since the forward voltage v f of the output diode becomes an error factor in the output voltag e, a schottky barrier diode of small v f is recommended. when selecting a diode, note that forward current must not exceed the rated values. and, when the built - in n - channel mosfet is on, the output diode or reverse voltage v r decrease is expressed by the following equation: ][ v out p s in r v n n v v ? ? ? furthermore, ringing occurs to the reverse voltage v r when built - in n - channel mosfet turns on. please prevent the peak voltage from exceeding the rated value of the output diode. 8 enable voltage this ic is shut downed when sdx/en voltage is below 0.9v (typ). if the voltage becomes above 2.0v (typ) when sdx/en terminal voltage i s rising, ic goes to enable state and starts up . (hysteresis voltage: 0.2v (typ )) enable control with vin terminal is done by dividing the vin terminal and gnd terminal with r 1 and r 2 resistors connecting to sdx/en terminal, as shown in figure 25. the enable voltage when v in is rising can be set with the following equation: ? ? ][ v 2 2 1 vin_enable r r r 2.0v v ? ? ? disable voltage when v in is falling can be set with the following equation: ? ? ][ v 2 2 1 e vin_disabl r r r 1.8v v ? ? ? since the control system of this ic needs to operate with 50% duty or less, set disable voltage which fulfils the following equation: ? ? ][ v f out s p e vin_disabl v v n n v ? ? ? pl ease note that the clamping element inside the ic will turn on and the inflow current occurs if the sdx/en terminal voltage rises above 5v. figure . 26 enable control with vin terminal vin sdx/en v in r 1 r 2 downloaded from: http:///
17 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 9 minimum load current to achieve a stable output voltage, the built - in n - channel mosfet senses and feeds back information on the o utput voltage on the secondary side (which was isolated by the transformer) by using the sw terminal voltage on the primary side (during off time). meaning, the output will not be regulated in any case unless the built - in n - channel mosfet is in the switching operation. during light load, the switching operation uses minimum on - time . the output voltage may rise when there is a small load current since it will supply the least amount of energy to the secondary side output. therefore, it is necessary to add a dummy resistor etc. to the output in order to secure minimum load current. the required minimum load current (i out_min ) can be expressed by: ][ 2 9 10 57 a ? ?? ? ? ?? ? ? ? ? ? ? out p in v l v . out_min i 10 switching frequency changing point during light load, high efficiency is achieved by changing t he switching frequency according to the load current. the load current equation where the switching frequency beg ins to fall from the fixed 400khz (typ) is expressed following equation: ? ? ][ 2 _ _ 400 2 1 a ?? ?? ? ?? ?? ? ? ? ? ? ? out p min on in fsw out v l t v khz i where t on_m in is the minimum on time figure 27 . switching frequency vs load current image fsw i out i out_min the changing point of f sw : i out_fsw 400khz(typ) 50khz(typ) downloaded from: http:///
18 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 11 load compensation the relational expression of v out shows that v f and esr are the factors leading to poor load regulation . for an application which these factors cause the problem, an ideal load regu lation can be obtain ed using load compensation function. load compensation mechanism is explained below. in the appl ication wherein output voltage accuracy in particular is no t required, load compensation function can be cancelled by short - circuiting the comp terminal to gnd. v out voltage drop is compensated corresponding to the average current of the primary transformer current i p. since i p and i s have a relationship as indicated in the following equation, t he load compensation value is determined by assuming i s from i p and then adjusted by using external cr of the comp terminal. the current of k ? i p is injected to the comp terminal from the current monitor block in the figure. 28 and then converted to v comp through r comp resistor externally attached to comp terminal. k here is the compression magnification and indicated as 1 /50k. the upper limit of v comp operating voltage is limited in the internal circuit. set r comp below 0.5v. ][ a s p s p i n n i ? ? 0.5v r i k v comp p comp ? ? ? ? steep changes in i comp may make the operation of the loop unstable. therefore, c comp is needed to stabilize v comp . recommended values of c comp are from 0. 01 f to 0.1f. by the addition of c comp , v comp becomes: p_ave comp comp i r k v ? ? ? ][ v t t 2 i i r k on p_max p_min comp ? ? ? ? ? ][ v 25k v i comp comp ? where: i p_ ave = average transformer primary side current r comp = external resistance for i comp adjustment t on = on - time of built - in n - channel mosfet how to decide the amount of load compensation and i comp setup by adjustment of r comp is explained next. the feedback current which originally flows into r ref is partially lost by i comp due to the load compensation function. as a result, in order to compensate this, the h level of v sw increases and recovers th e dropped output voltage. figure 28 . load compensation functional block diagram figure 29 . monitor of the amount of load compensation (continuous mode) v sw i p i p_min i p_max t t on i s comparator v f v out v in v in adaptive on-time controller r comp i p n p /n s i comp 0.78v i s v ref v comp current monitor comp ref fb sw pgnd c comp 25k r ref r fb driver downloaded from: http:///
19 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 while the load compensation function is not operating, v out , as described previously, will now be: ][ v esr i v v n n r r v s_ave f ref p s ref fb out ? ? ? ? ? ? where: i s_ave is the average transformer secondary side current when i comp occurs, the load compensation function operates and v out becomes the following eq uation. the voltage v out increases by i comp . ][ v esr i v r ) i r v ( n n v s_ave f fb comp ref ref p s out ? ? ? ? ? ? ? esr i r i r n n 25k i r k s_ave vf s_ave fb p s ave p comp ? ? ? ? ? ? ? ? _ in order to remove v f and esr by using i comp , the follow ing equation is needed. esr i v r n n i s_ave f fb p s comp ? ? ? ? ? next, linearity approximation of the change of v f to i s is carried out by r vf , and r comp which adjusts i comp from the expression mentioned earlier is calculated. esr i r i r n n 25k i r k s_ave vf s_ave fb p s p_ave comp ? ? ? ? ? ? ? ? esr r r n n 25k r k vf fb 2 p s comp ? ? ? ? ?? ? ? ?? ? ? ? ][ 2 s p fb vf comp n n r k esr r 25k r ? ?? ? ? ?? ? ? ? ? ? ? although the setting of the theoretical value of r comp was shown, r vf , esr, and r fb are dependent on the environment , such as used parts and the mounting board. therefore, when determining the actual value of r comp , monitor v out in the used load current range and adjust r comp accordingly. v out i out with load compensation no load compensation slope r vf +esr figure 30. load compensation image downloaded from: http:///
20 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 pcb layout design guidelines the dotted line is the image of the wiring in another layer. figure 31. application circuit block diagram pcb layout greatly affects the stable operation of the ic. depending on t he layout, the specs of the ic might not be secured or ic might not operate correctly. please take the following points into consideration when desi gning the pcb layout. 1. place input ceramic capacitors c in1 and c in2 as close as possible to vin terminal on the same pcb surface with ic. 2. shorten the thick line as short as possible with wide width pattern. 3. place r ref as close as possible to ref terminal. 4. place r fb as close as possible to fb terminal. 5. place transformer t 1 close to sw terminal and make the current loop indicate d as an arrow (primary side) short. i n addition, make the pattern of the sw node as thick and sho rt as possible. 6. place output diode d 2 close to sw terminal and make the current loop indicated as an a rrow (secondary side) short. 7. in case of multilayer board, do not place gnd layer or v out - node pattern in the internal layer that is just below the s w node pattern and d 2 anode pattern. 8. r comp and c comp are for load compensation function. short the comp terminal to th e gnd when the load compensation function is not used. 9. connect the exposed die pad to the gnd plane. v out + v out - v in c out d 2 d 1 z 1 t 1 c 1 r 3 r dummy r ref r comp c comp r 1 r 2 c in2 c in1 r fb 1.agnd 2.sdx/en 3.comp 4.ref 5.fb 6.pgnd 7.sw 8.vin downloaded from: http:///
21 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 reference layout pattern top layer middle layer bottom layer r fb r 3 c in 1 d 1 c 1 c in 2 c comp r comp r ref r 2 r 1 t 1 d 2 r dummy c out z 1 downloaded from: http:///
22 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 i/o equivalent circuits 2. sdx/en 3. comp 4. ref, 5. fb 7. sw sdx/en agnd 1m (typ) comp 10k (typ) internal regulator 10k (typ) agnd sw pgnd vin fb agnd 500 (typ) agnd 5k (typ) ref agnd 10k (typ) 10k (typ) agnd downloaded from: http:///
23 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 operational notes 1. reverse connection of power supply connecting the power supply in reverse polarity can damage the ic. take precautions against reverse polarity when connecting the power supply, such as mounting an extern al diode between the power supply and the ics power supply pin s. 2. power supply lines design the pcb layout pattern to provide low impedance supply lines. furthermore, connect a capacitor to ground at all power supply pins . consider the effect of temperature and aging on the capaci tance value when using electrolytic capacitors. 3. ground voltage ensure that no pins are at a voltage below that of the ground pin at any time, even during transient condition. 4. ground wiring pattern when using both small - signal and large - current ground traces, the two ground traces should be routed separately but connected to a single ground at the reference point of the application board to avoid fluctuations in the small - signal ground caused by large currents. also ensure that the groun d traces of external components do not cause variations on the ground voltage. the ground lines must be as short and thi ck as possible to reduce line impedance. 5. thermal consideration should by any chance the power dissipation rating be exc eeded the rise in temperature of the chip may result in deterioration of the properties of the chip. in case of exceeding thi s absolute maximum rating, increase the board size an d copper area to prevent exceeding the pd rating. 6. recommended operating conditions these conditions represent a range within which the expec ted characteristics of the ic can be approximately obtained . the electrical characteristics are guaranteed under th e conditions of each parameter. 7. inrush current when power is first supplied to the ic, it is possible that the internal logic may be unstable and inrush current may fl ow instantaneously due to the internal powering sequence a nd delays, especially if the ic has more than one powe r supply. therefore, give special consideration to power coup ling capacitance, power wiring, width of ground wiring, and routing of connections. 8. operation under strong electromagnetic field operating the ic in the presence of a strong electromagnetic field may cause the ic to malfunction. 9. testing on application boards when testing the ic on an application board, connecting a capacitor directly to a low - impedance output pin may subject the ic to stress. always discharge capacitors comple tely after each process or step. the ics power supply should always be turned off completely before connecting or removing it from the test setup during the inspection process. to prevent damage from static discharge, ground the ic during assembly and use similar precautions during transport and storage. 10. inter - pin short and mounting errors ensure that the direction and position are correct when mounti ng the ic on the pcb. incorrect mounting may result in damaging the ic. avoid nearby pins being shorted to each other especially to ground, power supply and output pin . inter - pin shorts could be due to many reasons such as metal particles, water droplets (in very humid environment) and unintentional solder bridge deposited in between pins during assembly to name a few. 11. unused input pins input pins of an ic are often connected to the gate of a mos tran sistor. the gate has extremely high impedance and extremely low capacitance. if left unconnected, the electric fi eld from the outside can easily charge it. the small charge acquired in this way is enough to produce a signi ficant effect on the conduction through the transistor and cause unexpected operation of the ic. so unless otherwise spe cified, unused input pins should be connected to the power supply or ground line. downloaded from: http:///
24 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 operational notes C continued 12. regarding the input pin of the ic this monolithic ic contains p+ isolation and p substrate lay ers between adjacent elements in order to keep them isolated. p - n junctions are formed at the intersection of the p layers wi th the n layers of other elements, creating a parasitic diode or transistor. for example (refer to figure below): when gnd > pin a and gnd > pin b, the p - n junction operates as a parasitic diode. when gnd > pin b, the p - n junction operates as a parasitic transistor. parasitic diodes inevitably occur in the structure of the ic. the operation of parasitic diodes can result in mutual interference among circuits, operational faults, or physica l damage. therefore, conditions that cause these diodes to operate, such as applying a voltage lower than the gnd vol tage to an input pin (and thus to the p substrate) should b e avoided. figure 32 . example of monolithic ic structure 13. ceramic capacitor when using a ceramic capacitor, determine the dielectric constant considering the change of capacitance with temperature and the decrease in nominal capacitance due to dc bias and others. 14. area of safe operation (aso) operate the ic such that the output voltage, output current, and power dissipation are all within the area of safe operation (aso). 15. thermal shutdown circuit (tsd) this ic has a built - in thermal shutdown circuit that prevents heat damage to the ic. normal operation should always be within the ics power dissipation rating. if however the rati ng is exceeded for a continued period, the junction temperature (tj) will rise which will activate the tsd circuit that will turn off all output pins. when the tj falls below the tsd threshold, the circuits are automatically restored to normal o peration. note that the tsd circuit operates in a situation that exceeds the absolute maximum ratings and therefore, under no circumstances, should the tsd circuit be used in a set desi gn or for any purpose other than protecting the ic from heat damage. 16. over current protection circuit (ocp) this ic incorporates an integrated overcurrent protection circui t that is activated when the load is shorted. this protection circuit is effective in preventing damage due to sudden and unexpected incidents. however, the ic should not be used in applications characterized by continuous op eration or transitioning of the protection circuit. n n p + p n n p + p substrate gnd n p + n n p + n p p substrate gnd gnd parasitic elements pin a pin a pin b pin b b c e parasitic elements gnd parasitic elements c be transistor (npn) resistor n region close-by parasitic elements downloaded from: http:///
25 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 ordering information b d 7 f 1 0 0 h f n - l b t r part number package hfn:hson8 efj:ht so p - j8 product class lb: for industrial applications packing, forming specification tr: embossed tape and reel (hson8) e2 : embossed tape and reel (h t so p - j 8) marking diagr am s line up package orderable part number hson8 bd7f100hfn - lbtr htsop - j8 bd7f100efj - lbe2 hson8 (top view) 100 part number marking lot number 1pin mark d 7 f htsop - j8(top view) d 7 f 1 0 0 part number marking lot number 1pin mark downloaded from: http:///
26 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 physical dimension, tape and reel information package name hson8 downloaded from: http:///
27 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 physical dimension, tape and reel information package name htsop - j8 downloaded from: http:///
28 / 28 bd7f100hfn - lb bd7f100efj - lb tsz02201 - 0j1j0aj00910 - 1 - 2 ? 201 4 rohm co., ltd. all rights reserved. 29.jun.2016 rev.002 www.rohm.com tsz22111 ? 15 ? 001 revision history date revision changes 4.sep.2015 001 new production 29.jun.2016 002 p.8 typical performance curves figure.9 modification p.9 typical performance curves figure.11 modification p.14 output voltage feedback resistance r fb formula modification p.15 (2) primary side inductance l p addition p.22 i/o equivalent circuits 3.comp, 4.ref, 5.fb update downloaded from: http:///
notice-paa-e rev.003 ? 201 5 rohm co., ltd. all rights reserved. notice precaution on using rohm products 1. if you intend to use our products in devices requiring extreme ly high reliability (such as medical equipment (note 1) , aircraft/spacecraft, nuclear power controllers, etc.) and whose malfunction or failure may cause loss of human life , bodily injury or serious damage to property ( specific applications ), please consult with the rohm sales representative in advance. unless otherwise agreed in writin g by rohm in advance, rohm shall not be in any way responsible or liable for any damages, expenses or losses incurred by you or third parties arising from the use of any rohm s products for specific applications. (note1) medical equipment classification of the specific applic ations japan usa eu china class � class � class � b class � class �? class � 2. rohm designs and manufactures its products subject to stri ct quality control system. however, semiconductor products can fail or malfunction at a certain rate. please be sure to implement, at your own responsibilities, adeq uate safety measures including but not limited to fail-safe desig n against the physical injury, damage to any property, whic h a failure or malfunction of our products may cause. the followi ng are examples of safety measures: [a] installation of protection circuits or other protective devic es to improve system safety [b] installation of redundant circuits to reduce the impact of single or multiple circuit failure 3. our products are no t designed under any special or extraordinary environments or conditions, as exemplified below . accordingly, rohm shall not be in any way responsible or liable for any damages, expenses or losses arising from the use of any rohms products under any special or extraordinary environments or conditions. if you intend to use our products under any special or extraordinary environments or c onditions (as exemplified below), your independent verification and confirmation of product performance, reliabil ity, etc, prior to use, must be necessary: [a] use of our products in any types of liquid, including water, oils, chemicals, and organi c solvents [b] use of our products outdoors or in places where the products are exposed to direct sunlight or dust [c] use of our products in places where the products are e xposed to sea wind or corrosive gases, including cl 2 , h 2 s, nh 3 , so 2 , and no 2 [d] use of our products in places where the products are exposed t o static electricity or electromagnetic waves [e] use of our products in proximity to heat-producing component s, plastic cords, or other flammable items [f] sealing or coating our products with resin or other coating materials [g] use of our products without cleaning residue of flux (even if you use no-clean type fluxes, cleaning residue of flux is recommended); or washing our products by using water or water-soluble cleaning agents for cleaning residue after soldering [h] use of the products in places subject to dew condensation 4. the products are not subject to radiation-proof design. 5. please verify and confirm characteristics of the final or mou nted products in using the products. 6 . in particular, if a transient load (a large amount of load appl ied in a short period of time, such as pulse. is applied, confirmation of performance characteristics after on-board mou nting is strongly recommended. avoid applying power exceeding normal rated power; exceeding the power rating u nder steady-state loading condition may negatively affec t product performance and reliability. 7. de -rate power dissipation depending on ambient temperature. wh en used in sealed area, confirm that it is the use in the range that does not exceed the maximum junction temperature. 8 . confirm that operation temperature is within the specified range desc ribed in the product specification. 9 . rohm shall not be in any way responsible or liable for failure induced under deviant condition from what is defined in this document. precaution for mounting / circuit board design 1. when a highly active halogenous (chlorine, bromine, etc .) flux is used, the residue of flux may negatively affect prod uct performance and reliability. 2. in principle, the reflow soldering method must be used on a surface-mount products, the flow soldering method mus t be used on a through hole mount products. i f the flow soldering method is preferred on a surface-mount p roducts, please consult with th e rohm representative in advance. for details, please refer to rohm mounting specification downloaded from: http:///
notice-paa-e rev.003 ? 201 5 rohm co., ltd. all rights reserved. precautions regarding application examples and external circuits 1. if change is made to the constant of an external circuit, p lease allow a sufficient margin considering variations o f the characteristics of the products and external components, inc luding transient characteristics, as well as static characteristics. 2. you agree that application notes, reference designs, and a ssociated data and information contain ed in this document are presented only as guidance for products use. therefore, i n case you use such information, you are solely responsible for it and you must exercise your own independ ent verification and judgment in the use of such information contained in this document. rohm shall not be in any way respon sible or liable for any damages, expenses or losses incurred by you or third parties arising from the use of such informat ion. precaution for electrostatic this product is electrostatic sensitive product, which may be damaged due to electrostatic discharge. please take p roper caution in your manufacturing process and storage so t hat voltage exceeding the products maximum rating will not be applied to products. please take special care under dry co ndition (e.g. grounding of human body / equipment / solder iro n, isolation from charged objects, setting of ionizer, friction prevention and temperature / humidity control). precaution for storage / transportation 1. product performance and soldered connections may deteriorate if the products are stored in the places where: [a] the products are exposed to sea winds or corrosive gases, in cluding cl2, h2s, nh3, so2, and no2 [b] the temperature or humidity exceeds those recommended by rohm [c] the products are exposed to direct sunshine or condensation [d] the products are exposed to high electrostatic 2. even under rohm recommended storage condition, solderabil ity of products out of recommended storage time period may be degraded. it is strongly recommended to confirm so lderability before using products of which storage time is exceeding the recommended storage time period. 3. store / transport cartons in the correct direction, which is indi cated on a carton with a symbol. otherwise bent leads may occur due to excessive stress applied when dropping of a carton. 4. use products within the specified time after opening a humi dity barrier bag. baking is required before using products of which storage time is exceeding the recommended storage tim e period. precaution for product label a two-dimensional barcode printed on rohm products label is f or rohm s internal use only. precaution for disposition when disposing products please dispose them properly usi ng an authorized industry waste company. precaution for foreign exchange and foreign trade act since concerned goods might be fallen under listed items of export control prescribed by foreign exchange and foreign trade act, please consult with rohm in case of export. precaution regarding intellectual property rights 1. all information and data including but not limited to appl ication example contained in this document is for reference only. rohm does not warrant that foregoing information or data will not infringe any intellectual property rights or any other rights of any third party regarding such information or data. 2. rohm shall not have any obligations where the claims, a ctions or demands arising from the combination of the products with other articles such as components, circuits, systems or ex ternal equipment (including software). 3. no license, expressly or implied, is granted hereby under any inte llectual property rights or other rights of rohm or any third parties with respect to the products or the information contai ned in this document. provided, however, that rohm will not assert its intellectual property rights or other rights a gainst you or your customers to the extent necessary to manufacture or sell products containing the products, subject to th e terms and conditions herein. other precaution 1. this document may not be reprinted or reproduced, in whole or in p art, without prior written consent of rohm. 2. the products may not be disassembled, converted, modified , reproduced or otherwise changed without prior written consent of rohm. 3. in no event shall you use in any way whatsoever the pr oducts and the related technical information contained in the products or this document for any military purposes, includi ng but not limited to, the development of mass-destruction weapons. 4. the proper names of companies or products described in this document are trademarks or registered trademarks of rohm, its affiliated companies or third parties. downloaded from: http:///
datasheet datasheet notice ? we rev.001 ? 2015 rohm co., ltd. all rights reserved. general precaution 1. before you use our pro ducts, you are requested to care fully read this document and fully understand its contents. rohm shall n ot be in an y way responsible or liabl e for fa ilure, malfunction or acci dent arising from the use of a ny rohms products against warning, caution or note contained in this document. 2. all information contained in this docume nt is current as of the issuing date and subj ec t to change without any prior notice. before purchasing or using rohms products, please confirm the la test information with a rohm sale s representative. 3. the information contained in this doc ument is provi ded on an as is basis and rohm does not warrant that all information contained in this document is accurate an d/or error-free. rohm shall not be in an y way responsible or liable for an y damages, expenses or losses incurred b y you or third parties resulting from inaccur acy or errors of or concerning such information. downloaded from: http:///
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