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| high efficiency for led b acklight, 1ch led driver ic BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 1 nov. 27 , 2 013 general descriptions bl010 0a is led driver ic for led backlight , and it can do dimming to 0.02 % by external pwm signal. this ic realize s a high efficiency by the boost convertor control that absorb s variability on v f . the product easily achieves high cost - performance led drive system with few external components and enhanced protection function s. features and benefit boost convertor current - mode type pwm control pwm frequency is 1 00 khz to 500khz maximum on duty is 90 % led current control pwm dimming a nalog dimming high contrast ratio is 1 / 5000 accuracy of reg ou tput voltage is 2 % protection functions error signal output overcurrent protection for boost circuit (ocp) -------------------------------- ----------------- pulse - by - pulse overcurrent protection for led output (led_ocp) -------------------------------- ----------------- pulse - by - pulse ov ervoltage protection (ovp) -------------- auto restart output open/short protection --------------- auto resta rt thermal shutdown (tsd) -------------------- a uto restart typical application circui t package soic14 not to scale ele ctrical characteristics ? absolute maximum vol tage of vcc pin is 20 v ? adjustable pwm frequency, 100 khz to 500 khz applications ? led backlights ? led lighting etc. v c c v r e f p w m e r f s e t r e g c o m p g n d d r v o c o v p s w i f b b l 0 1 0 0 a
bl 0100a BL0100A - ds rev. 1.1 sanken electric co.,ltd. 2 nov. 27 , 2 013 contents general descriptions -------------------------------- -------------------------------- ------- 1 1. absolute maximum ratings -------------------------------- ------------------------- 3 2. electrical characteristics -------------------------------- ----------------------------- 3 3. functional block diagram -------------------------------- --------------------------- 5 4. pin list table -------------------------------- -------------------------------- ----------- 5 5. typical application circuit -------------------------------- ------------------------- 6 6. package diagram -------------------------------- -------------------------------- ------ 7 7. marking diagram -------------------------------- -------------------------------- ----- 7 8. functional description -------------------------------- ------------------------------- 8 8.1 startup operation -------------------------------- ---------------------------- 8 8.2 constant current control operation -------------------------------- ---- 9 8.3 pwm dimming function -------------------------------- ------------------- 9 8.4 gate drive -------------------------------- -------------------------------- ------ 9 8.5 protection function -------------------------------- ------------------------- 10 8.6 error signal output function -------------------------------- ------------ 13 9. design notes -------------------------------- -------------------------------- ----------- 14 9.1 peripheral components -------------------------------- -------------------- 14 9.2 inductor design paramet ers -------------------------------- --------------- 14 9.3 pcd trace layout and component placement ----------------------- 14 10. reference design of power supply -------------------------------- --------------- 16 operating precautions -------------------------------- ------------------------ 18 important notes -------------------------------- -------------------------------- --- 19 bl 0100a BL0100A - ds rev. 1.1 sanken electric co.,ltd. 3 nov. 27 , 2 013 1. absolute m aximum r atings ? the polarity value for current specifies a sink as "+ , " and a source as "? , " referencing the ic. ? unless otherwise specified, t a is 25 c parameter symbol te st conditions pins rating unit reg pin source current i reg 2 ? ? ovp 3 ? ? pwm 4 ? ? fb s i n gl e p u l s e 5 s 12 ? ? fset 6 ? ? cc 8 ? ? sw 9 ? ? cc + 0 .3 v drv pin voltage v drv 10 ? ? cc + 0 .3 v oc pin voltage v oc 11 ? ? er 14 ? ? r e g v vref pin voltage v ref 1 ? ? op ? ? stg ? ? j ? 2. electrical characteristics ? the polarity value for current specifies a sink as "+ , " and a source as "? , " referencing the ic. ? unless otherwise specified, t a is 25 c , v cc = 12 v parameter symbol test conditions pins min. typ. max. unit start / stop operation operation start voltage 1 v cc (on) 8 ? cc (o ff ) 8 ? cc (o n ) 8 ? ? cc (o ff ) v cc = 8 v 8 ? ? reg 2 ? oscillation pwm operation frequency 1 f pwm1 v fset = 2 v 10 ? pwm2 r22 = 4.7 k 10 ? max 10 ? min 10 ? comp(on) 13 ? comp(off) 13 ? vref / ifb pin vref pin minimum setting voltage v ref(min) v ref = 0 v 1 ? ref(max) v ref = 5 v 1 ? 1 v cc(on) > v cc(off) bl 0100a BL0100A - ds rev. 1.1 sanken electric co.,ltd. 4 nov. 27 , 2 013 parameter symbol test conditions pins min. typ. max. unit ifb pin voltage at auto restart operation v ifb ( ar ) v ref = 1 v 12 ? 7 0.45 0.50 0.5 5 v ifb pin voltage at comp charge switching v ifb(comp) v ref = 1 v 12 ? 7 0.55 0.60 0.65 v ifb pin overcurrent protection low threshold voltage v ifb ( ocl ) v ref = 1 v 12 ? 7 1.9 2.0 2.1 v ifb pin overcurrent protection release threshold voltage v ifb ( ocl - off ) v ref = 1 v 12 ? 7 1.5 1.6 1.7 v ifb pin overcurrent protection high threshold voltage v ifb ( och ) 12 ? 7 3.8 4.0 4.2 v ifb pin bias current i ifb(b) v ifb = 5 v 12 ? 7 ? ? 1 a current detection threshold voltage v ifb v ref = 1 v 12 ? 7 0.98 1.00 1.02 v comp pin comp pin maximum output voltage v comp ( max ) v ifb = 0.7 v 13 ? 7 4.8 5.0 ? v comp pin minimum output voltage v comp ( min ) v ifb = 2.0 v 13 ? 7 ? 0 0.2 v transconductance gm ? ? 640 ? s comp pin source current i c omp(src) v ifb = 0.7 v 13 ? 7 ? 77 ? 57 ? 37 a comp pin sink current i c omp(snk) v ifb = 1.5 v 13 ? 7 37 57 77 a comp pin charge current at startup i comp(s) v comp = 0 v 13 ? 7 ? 19 ? 11 ? 3 a comp pin reset current i c omp(r) 13 ? 7 200 360 520 a er pin er pin sink current during non - alarm i er v er = 1 v 14 ? 7 2.5 4.4 6.3 ma boost parts overcurrent protection (ocp) oc pin overcurrent protection threshold voltage v ocp v comp = 4.5 v 11 ? 7 0.57 0.60 0.63 v overvoltage protection (ovp) ovp pin overvoltage protection threshold voltage v o v p 3 ? 7 2.85 3.00 3.15 v ovp pin ovp release threshold voltage v ovp(off) 3 ? 7 2.60 2.75 2.90 v pwm pin pwm pin on threshold voltage v pwm(on) 4 ? 7 1.4 1.5 1.6 v pwm pin off threshold voltage v pwm(off) 4 ? 7 0.9 1.0 1.1 v pwm pin impedance r pwm 4 ? 7 100 200 300 k sw / drv pin sw pin source current i sw(src) 9 ? 7 ? ? 85 ? ma sw pin sink current i sw(snk) 9 ? 7 ? 220 ? ma drv pin source current i drv(src) 10 ? 7 ? ? 0.36 ? a drv pin sink current i drv(snk) 10 ? 7 ? 0.85 ? a thermal shutdown protection (tsd) thermal shutdown activating temperature t j(tsd) ? 125 ? ? c hysteresis temperature of tsd t j(tsd)hys ? ? 6 5 ? c thermal resistance thermal resistance from junction to a mbient j - a ? ? ? 120 c /w bl 0100a BL0100A - ds rev. 1.1 sanken electric co.,ltd. 5 nov. 27 , 2 013 3. functional block dia gram 4. pin list table number name function 1 vref detection voltage setting 2 reg internal regulator output 3 ovp overvoltage detection signal input 4 pwm d imming mosfet gate drive output 5 (n.c.) 6 fset boost mosfet drive frequency setting 7 gnd ground 8 vcc power s upply voltage input 9 sw pwm dimming drive output 10 drv boost mosfet gate drive output 11 oc curre nt mode control signal input and overcurrent protection signal input 12 ifb feedback signal input of current detection 13 comp phase compensation and soft - start setting 14 er error signal output vcc uvlo reg on / off pwm osc main logic tsd auto restart protection oc control slope compensation feedback control abnormal detector overvoltage detector pwm pulse detector reg sw drv er oc gnd comp fb vref ovp fset pwm vcc vcc vcc 7 2 9 10 14 11 1 3 6 4 8 12 13 drive drive 1 3 2 4 6 5 7 13 14 12 vref ovp reg pwm fset ( n . c .) gnd er ifb comp oc sw drv vcc 8 9 11 10 bl 0100a BL0100A - ds rev. 1.1 sanken electric co.,ltd. 6 nov. 27 , 2 013 5. typical application circuit figure 5 - 1 typical application circuit f 1 v c c 1 4 3 2 s w d r v o c g n d f s e t ( n . c . ) p w m u 1 b l 0 1 0 0 a 7 6 5 1 2 1 3 1 4 o v p r e g v r e f i f b c o m p 9 8 1 0 1 1 e r l 1 q 1 d 1 c 2 l e d _ o u t ( + ) l e d _ o u t ( ? ) q 2 c 1 3 c 1 2 c 1 1 d 3 c 9 c 1 0 v c c _ i n e r _ o u t o n / o f f p w m _ i n s _ g n d q 3 c 3 c 4 r 1 r 1 3 q 4 c 1 c 8 p _ i n p _ g n d c 5 c 7 r 2 r 3 r 4 r 5 r 6 r 7 r 8 r 9 r 1 0 r 1 1 r 1 2 r 1 4 r 1 5 r 1 6 r 1 7 r 1 8 r 1 9 r 2 1 d 2 c 6 r 2 0 r 2 2 r 2 3 bl 0100a BL0100A - ds rev. 1.1 sanken electric co.,ltd. 7 nov. 27 , 2 013 6. package diagram ? soic14 notes: 1) dimension is in millimeters 2) pb - free. device composition compliant with the rohs directive 7. marking diagram 1 1 4 p a r t n u m b e r b l 0 1 0 0 a s k y m d l o t n u m b e r y i s t h e l a s t d i g i t o f t h e y e a r ( 0 t o 9 ) m i s t h e m o n t h ( 1 t o 9 , o , n o r d ) d i s a p e r i o d o f d a y s ( 1 t o 3 ) : 1 : 1 s t t o 1 0 t h 2 : 1 1 t h t o 2 0 t h 3 : 2 1 s t t o 3 1 s t s a n k e n c o n t r o l n u m b e r 1.27 0.43 0.15 1.45 3.9 6.0 0.6 0.25 8.65 BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 8 nov. 27 , 2 013 8. functional description ? a ll of the parameter values used in these descriptions are typical values , unless they are specified as minimum or maximum. ? with regard to current direction, "+" indicates sink current (toward the ic) and " C " indicates source current (from the ic). 8.1 startup operation figure 8 - 1 shows the vcc pin peripheral circuit. the vcc pin is the power supply input for control circuit from the external power supply. w hen the vcc pin voltage increases to the operation start voltage , v cc(on) = 9.6 v, the control circuit starts operation . after that, when the pwm pin voltage exceeds the pwm pin on threshold voltage, v pwm(on) of 1.5 v (less than absolute maximum voltage of 5 v), the comp pin charge current at startup, i comp(s) = ? 11 a , flows from the comp pin. this charge current flows to capacitors at the comp pin. when the comp pin voltage increases to the comp pin voltage at oscillation start, v comp(on) = 0.50 v or more, the control circuit starts switching operation. as shown in figure 8 - 2 , w hen the vcc pin voltage decreases to the operation stop voltage , v cc(off) = 9.1 v, the control circuit stops operation, by the uvlo (undervoltage lockout) circuit, and reverts to the state before startup . figure 8 - 1 vcc pin peripheral circuit figure 8 - 2 v cc versus i cc when the on - duty of the pwm dimming signal is small, the charge current at the comp pin is controlled as follows in order to raise the output current quickly at startup. figure 8 - 3 shows the operation waveform with the pwm dimming signal at startup. figure 8 - 3 startup operation during pwm dimming while the ifb pin voltage increases to the ifb pin voltage at comp charge switching, v ifb(comp.vr) , a capacitors at the comp pin ar e charged by i comp(s) = C 11 a. during this period, they are charged by the comp pin source current, i comp(src) = C 57 a, when the pwm pin voltage is 1.5 v or more. thus, the comp pin voltage increases immediately. when the ifb pin voltage increases to v if b(cmp1.vr) or more, the comp pin source current is controlled according to the feedback amount, and the output current is controlled to be constant. the on - duty gradually becomes wide according to the increase of the comp pin voltage, and the output power increases (soft start operation). thus, power stresses on components are reduced. when the vcc pin voltage decreases to the operation stop voltage or less, or the auto restart operation (see the section 8.5 prot ection function) after protection is achieved, then the control circuit stops switching operation, and capacitors at the comp pin are discharged by the comp pin reset current, i comp(r) = 360 a, simultaneously . t he soft start operation is achieved at resta rt. the ic is operated by auto restart 1 at startup e x t e r n a l p o w e r s u p p l y u 1 c 3 c o m p g n d p w m 8 1 3 7 4 c 8 c 1 0 c 9 r 2 3 v c c i c c i c c o n v c c o f f v c c o n v c c s t a r t s t o p p w m p i n d i m m i n g s i g n a l c o m p p i n v o l t a g e i f b p i n v o l t a g e c o n s t a n t c u r r e n t c o n t r o l c o m p p i n c h a r g e c u r r e n t i c s w i t c h i n g s t a t u s o f f o n v c o m p ( o n ) v r e f p i n v o l t a g e v i f b ( c o m p . v r ) i c o m p ( s ) i c o m p ( s r c ) 0 0 0 0 v c c p i n v o l t a g e v c c ( o n ) = 9 . 6 v 0 BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 9 nov. 27 , 2 013 operation. see the section 8.5 protection function about the caution of startup operation. v ifb(comp.vr) is determined by the vref pin voltage, as shown in figure 8 - 4 . when vref pin voltage is 1v, the value of v ifb(comp.vr) becomes 0.60 v. figure 8 - 4 vref pin voltage versus ifb pin voltage at co mp charge switching 8.2 constant current control operation figure 8 - 5 shows the ifb pin peripheral circuit. when q2 turns on, the led output current, i out(cc) , is detected by the current detection resistor, r11 . the ic compares the ifb pin voltage with the vref pin voltage by the internal error amplifier, and controls the ifb pin voltage so that it gets close to the vref pin voltage. the reference voltage at the vref pin is the divided voltage of the reg pin voltage, v r eg = 5 v, by r20 and r21 , and thus this voltage can be externally adjusted. the setting current, i out(cc) , of the led_out can be calculated as follows. (8 - 1) where: v ref is the vref pin voltage. the value is recommended to be 0.5 v t o 2.0 v. r esn is the value of r11 figure 8 - 5 ifb pin peripheral circuit 8.3 pwm dimming function figure 8 - 6 shows the peripheral circuit of p wm pin and sw pin. the pwm pin is used for the pwm dimming signal input. the sw pin drives the gate of external mosfet, q2. t he sw pin voltage is turned on / off by pwm signal, and thus the dimming of led is controlled by pwm signal input. as shown in figure 8 - 7 , when the pwm pin voltage becomes the pwm pin on threshold voltage, v pwm(on) = 1.5 v or more, the sw pin voltage becomes v cc . when the pwm pin voltage becomes the pwm pin off threshold voltage, v pwm(off) = 1 .0 v or less, the sw pin voltage becomes 0.1 v or less. the pwm pin has the absolute maximum voltage of ? 0.3 v to 5.0 v, and the input impedance, r pwm , of 200 k . the pwm dimming signal should meet these specifications and threshold voltages of v pwm(on) and v pwm(off) . figure 8 - 6 the peripheral circuit of pwm pin and sw pin. figure 8 - 7 the waveform of pwm pin and sw pin 8.4 gate drive figure 8 - 8 shows the peripheral circ uit of drv pin and sw pin and fset pin . the drv pin is for boost mosfet, q1 . the sw pin is for dimming mosfet, q2 . table 8 - 1 shows drive voltages and currents of drv pin and sw pin. q1 and q2 should be selected so that these v gs(th) threshold voltages are less than v drv enough over entire operating temperature range. v i f b ( c o m p . v r ) v r e f p i n v o l t a g e 0 . 1 5 v 1 . 2 v 0 . 2 5 v 2 v 1 v 0 . 6 v sen ref ) cc ( out r v i ? u 1 o u t p u t c u r r e n t d e t e c t i o n r e s i s t o r a b n o r m a l d e t e c t o r v r e f e r r o r a m p . q 2 r 1 1 1 1 2 i f b i o u t ( c c ) l e d _ o u t ( + ) l e d _ o u t ( - ) r e g v c c 8 2 r 2 0 r 2 1 5 v u 1 s w q 2 r 1 1 9 d r i v e p w m o s c m a i n l o g i c 4 p w m p w m _ i n p w m p u l s e d e t e c t o r v c c l e d l e d _ o u t ( + ) l e d _ o u t ( ? ) p w m p i n v o l t a g e s w p i n v o l t a g e v p w m ( o n ) v p w m ( o f f ) v c c t i m e t i m e 0 . 1 v BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 10 nov. 27 , 2 013 peripheral components of q1 ( r 1, r 2, and d 2) and q2 (r8, r9, and d3) affect losses of power mosfet, gate waveform (ringing caused by the printed circui t board trace layout ), emi noise, and so forth, these values should be adjusted based on actual operation in the application. r3 for q1 and r10 for q2 are used to prevent malfunctions due to steep dv/dt at turn - off of the power mosfet, and these resistor s are connected near each the gate of the power mosfet s and the ground line side of the current detection resistance . the reference value of them is from 10 k to 100 k. figure 8 - 8 the peripheral circuit of drv pin, sw pin and fset pin table 8 - 1 drive voltage and current p ins drive voltage, v drv drive current, i drv high low source sink drv v cc 0.1v or less C 0.36 a 0.85 a sw v cc 0. 1v or less C 85 ma 220 ma as shown in figure 8 - 9 , the pwm oscillation frequency of drv pin can be set between 100 khz and 500 khz, depending on the value of r22 connected to fset pin, r fset . figure 8 - 9 relation between pwm oscillation fr equency and r fset 8.5 protection function as shown in table 8 - 2 , the ic performs protection ope rations according to kind of abnormal state. in a ll protection functions, when the fault condition is removed, the ic returns to normal operation automatically. the intermitted oscillation operation reduces stress on the power mosfet, the secondary rectifier diode, and so forth. table 8 - 2 relationship between a kind of abnormal state and protection operations abnormal states protection operations 1 overcurrent of boost circuit (ocp) auto restart 1 2 overcurrent of led output (led_ocp) 3 overvoltage of le d_out(+) (ovp) 4 short mode between led_out( ? ) and gnd 5 short mode of led current detection resistor (r sen _short) 6 short mode of both ends of led output auto restart 2 7 open mode of led current detection resistor (r sen _open) 8 overtemperature of junction of ic (tsd) auto restart 3 auto restart 1: as shown in figure 8 - 10 , the ic repeats a n intermitted oscillation operation, after the detection of any one of abnormal states 1 to 5 in table 8 - 2 . this interm itted oscillation is determined by t ars1 or t ars2 , and t aroff1 . the t ars1 is an oscillation time in the first intermitted oscillation cycle, t ar1 . the t ars2 is an oscillation time in the second and subsequent intermitted oscillation cycle, t ar2 . the t aroff 1 is a non - oscillation time in all intermitted oscillation cycle. in case pwm dimming frequency is low and the on - duty is small, the startup operation, the restart operation from on - duty = 0 % and the restart operation from intermitted oscillation operati on need a long time. thu s t he value of t ars1 and t ars2 depend on frequency and on - duty of the pwm dimming signal, as shown in figure 8 - 12 and figure 8 - 13 . in case the on - duty is 100 %, the value of t ars1 is 61.4 ms, and t ars2 is 41.0 ms . the value of t aroff1 is about 1.3 s. auto restart 2: as shown in figure 8 - 11 , the ic stops the switching operation immediately after the detection of abnormal states 6 or 7 in table 8 - 2 , and repeats a n intermitted oscillation operation. in the intermitted oscillation cycle, the t arsw is an oscillation time, the t aroff1 is a non - oscillation time. the value of t arsw is a few microseconds . the value of t ars2 is derived from figure 8 - 11 , and t aroff2 is calculated as follows: (8 - 3) 0 100 200 300 400 500 600 1 10 100 1000 pwm oscillation frequency of drv pin (khz) r fset (k ) l 1 c 2 q 2 r 1 1 d 1 q 1 c 1 l e d _ o u t ( + ) r 1 r 2 r 3 r 4 r 8 r 9 r 1 0 d 2 d 3 d r v s w 1 0 9 u 1 p w m o s c m a i n l o g o c d r i v e d r i v e v c c v c c g n d f s e t c 7 r 2 2 6 7 (s) 3 . 1 t t t arsw 2 ars 2 aroff ? ? ? BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 11 nov. 27 , 2 013 in case the on - duty is 100%, the value of t aroff1 becomes about 1.341 ms. auto restart 3: the ic stop s the switching operation immediately after the detection of abnormal states 8 in table 8 - 2 , and keeps a non - oscillation. figure 8 - 10 aut o restart 1 figure 8 - 11 auto restart 2 figure 8 - 12 pwm dimming on - duty versus t ars1 figure 8 - 13 pwm dimming on - duty versus t ars2 the operating condition of auto restart 1 and 2 is as follows: < the operating condition of auto restart 1 > the auto restart 1 is operated by the detection signals of the oc pin or ifb pin. operation by the detection signal of oc pin: when t he oc pin voltage increase to the oc pin overcurrent protection threshold voltage , v ocp = 0.6 0 v, or more, the operation of the ic switches to auto restart 1. when the fault condition is removed and the oc pin voltage decreases to under v ocp , the ic returns to normal operation automatically. operation by the detection signal of ifb pin: as shown in figure 8 - 14 , ifb pin has two types of threshold voltage. t hese threshold voltag es depend on the vref pin voltage, as shown in fig ure 8 - 15 . figure 8 - 14 ifb pin threshold voltage and auto restart 1 operation fig ure 8 - 15 vref pin voltage versus ifb pin threshold voltages 0 500 1000 1500 2000 2500 0.01 0.1 1 10 100 t ars1 (ms) duty (%) 0 200 400 600 800 1000 1200 1400 0.01 0.1 1 10 100 t ars2 (ms) duty (%) 0.1 1.0 10.0 0.0 0.5 1.0 1.5 2.0 2.5 ifb pin threshold voltages (v) vref pin voltage (v) v ifb(ocl.vr) v ifb(ocl - off.vr) 0.25v 0.125v 0.4v 0.5v 1.0v 3.2v 4.0v v ifb(ar.vr) v ifb(ocl.vr) : ifb pin overcurrent protection low threshold voltage v ifb(ocl - off.vr) : ifb pin o vercurrent protection release threshold voltage v ifb(ar.vr) : ifb pin auto restart operation threshold voltage f dm = 100 khz f dm = 3 00 khz f dm : pwm dimming frequency f dm = 100 khz f dm = 3 00 khz f dm : pwm dimming frequency t a r s 1 t a r s 2 t a r s 2 t a r o f f 1 t a r o f f 1 t a r o f f 1 t a r 2 t a r 2 t a r 1 a b n o r m a l s t a t e s w p i n v o l t a g e t i m e r e l e a s e r e t u r n t o n o r m a l o p e r a t i o n t a r s w t a r s 2 t a r s 2 t a r o f f 2 t a r s w t h a l t t h a l t t h a l t t a r o f f 2 t a r o f f 2 s w p i n v o l t a g e t i m e r e l e a s e r e t u r n t o n o r m a l o p e r a t i o n a b n o r m a l s t a t e i f b p i n v o l t a g e s w p i n v o l t a g e t i m e v i f b ( o c l . v r ) v i f b ( o c l - o f f . v r ) a u t o r e s t a r t 1 v i f b ( a r . v r ) t i m e r e t u r n t o n o r m a l o p e r a t i o n BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 12 nov. 27 , 2 013 1) in case ifb pin voltage increased when the fb pin voltage increase to v ifb(ocl.vr) in fig ure 8 - 15 , or mor e, the operation of the ic switches to auto restart 1. when the fault condition is removed and the ifb pin voltage decreases to v ifb(ocl - off.vr) in fig ure 8 - 15 , or less, the ic returns to normal operation automatic ally. 2) in case ifb pin voltage decreased when the fb pin voltage decrease to v ifb(ar.vr) in fig ure 8 - 15 , or more, the operation of the ic switches to auto restart 1. when the fault condition is removed and the ifb p in voltage increases to above v ifb(ar.vr) , the ic returns to normal operation automatically. < the operating condition of auto restart 2 > the auto restart 2 is operated by the detection signal of the ifb pin. as shown in figure 8 - 16 , when the fb pin voltage increase to the ifb pin overcurrent protection high threshold voltage, v ifb(och) = 4.0 v, or more , the operation of the ic switches to auto restart 2, and the ic stops switching operation immediately. when the f ault condition is removed and the ifb pin voltage decreases to under v ifb(och) , the operation of the ic switches to auto restart 1 . figure 8 - 16 ifb pin threshold voltage and auto restart 2 operation < c aution of startup operation > when the led current is low and the ifb pin voltage is less than v ifb(ar.br) , during startup for example, the ic is operated by auto restart 1. if the startup time is too long, the ic operation becomes the intermitted oscillation by the auto restart 1. it becomes cause of the fault startup operation, thus the startup time should be set less than t ars1 in figure 8 - 10 . the protection operation according to the ab normal states in table 8 - 2 is described in detail as follows: 8.5.1 overcurrent of boost converter part (ocp) when the oc pin detects the overcurrent of boost circuit, the ic switches to auto restart 1. figure 8 - 17 shows the peripheral circuit of oc pin. when q1 turns on, the current flowing to l1 is detected by r4 , and the voltage on r4 is input to the oc pin. when the oc pin voltage increases to the oc pin overcurrent protection threshold voltage, v ocp = 0.60 v or more, the on - duty becomes narrow by pulse - by - pulse basis, and the output power is limited. figure 8 - 17 oc pin peripheral circuit 8.5.2 overcurrent o f led output (led_ocp) figure 8 - 18 shows the peripheral circuit of ifb pin and comp pin. when q2 turns on, the output current is detected by r11. when the boost operation cannot be done by failure such as short cir cuits in led string, t he ifb pin voltage is increased by the increase of led current. there are three types of operation modes in led_ocp state . (1) when the ifb pin voltage is increased by the increase of led current, comp pin voltage is decreases. in additio n, when the comp pin voltage decreases to the comp pin voltage at oscillation stop, v comp(off) = 0.25 v or less, the ic stops switching operation, and limits the increase of the output current. when ifb pin voltage is decreased by the decrease of led curre nt, comp pin voltage increases. w hen comp pin voltage becomes v comp(on) = 0.5 0 v or more, the ic restarts switching operation. (2) when ifb pin voltage becomes v ifb(ocl.vr) or more (see fig ure 8 - 15 ), the ic switches to auto restart 1. (3) the led current increases further and when the ifb pin voltage increases to the ifb pin overcurrent i f b p i n v o l t a g e s w p i n v o l t a g e t i m e r e t u r n t o n o r m a l o p e r a t i o n v i f b ( o c l - o f f . v r ) a u t o r e s t a r t 2 a u t o r e s t a r t 1 v i f b ( o c h ) l 1 c 2 q 2 d 1 q 1 c 1 1 r 4 l e d _ o u t ( + ) l e d _ o u t ( - ) u 1 o c 1 1 g n d 7 r 1 1 r 5 i l ( o n ) BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 13 nov. 27 , 2 013 protection high threshold voltage, v ifb(och) = 4.0 v or more, the ic switches to auto restart 2. figure 8 - 18 the peripheral circuit of ifb pin and comp pin 8.5.3 overvoltage of led_out (+) (ovp) figure 8 - 19 shows ovp pin peripheral circuit. the ovp pin detects the divided led outp ut voltage by r6 and r7 . when the led_out (+) or the ifb pin is open and the ovp pin voltage increases to the ovp pin overvoltage protection threshold voltage, v ovp = 3 .00 v, the ic immediately stops switching operation. when the ovp pin voltage decreases to the ovp pin overvoltage protection release threshold voltage, v ovp(off) = 2.75 v or the ifb pin voltage decreases to v ifb(ar.vr) in fig ure 8 - 15 , then the ic switches to auto restart 1. figure 8 - 19 ovp pin peripheral circuit 8.5.4 short mode between led_out( ? ) and gnd when the led_out ( C ) and the gnd are shorted, and the ifb pin voltage decreases to v ifb(ar.vr) in fig ure 8 - 15 , then the ic switches to auto restart 1. 8.5.5 short mode of led current detection resistor (r sen _short) when the output current detection resistor, r11 , is shorted, the ifb pin voltage decreases. when the ifb pin voltage decreases to v if b(ar.vr) in fig ure 8 - 15 , then the ic switches to auto restart 1. 8.5.6 short mode of led output both ends when the led_out (+) and led_out ( C ) are shorted, the short current flows through the detection resistor (r11 ) whi le q2 turns on. the ifb pin detects the voltage rise of the detection resistor. when the ifb pin voltage increases to the ifb pin overcurrent protection high threshold voltage, v ifb(och) = 4.0 v or more, the ic switches to auto restart 2. 8.5.7 open mode of led current detection resistor (r sen _open) when the output current detection resistor, r11 , is open, the ifb pin voltage increases. when the ifb pin voltage increases to the ifb pin overcurrent protection high threshold voltage, v ifb(och) = 4 .0 v or more, the ic switches to auto restart 2. 8.5.8 overtemperature of junction of ic (tsd) w hen the temperature of the ic increases to t j( tsd) = 1 2 5 c (min) or more , the tsd is activated , and the ic stops switching operation . when the junction temperature decreases by t j(tsd ) ? t j(tsd)hys after the fault condition is removed, the ic returns to normal operation automatically. 8.6 error signal output function when the protection function is active, the internal switch becomes off. the drain of this internal switch is connected to er pin. in case the error signal is receive d by external microcomputer , the pull - up resistor, r17, and the protection resistor of er pin, r er , are connected as shown in figure 8 - 20 . when the protection function is act ive, er_out becomes reg pin voltage from 0 v. t he resistances of r17 and r er are about 10 k . figure 8 - 20 er pin peripheral circuit u 1 o u t p u t c u r r e n t d e t e c t i o n r e s i s t o r q 2 r 1 1 1 2 i f b l e d _ o u t ( + ) l e d _ o u t ( - ) 1 3 c o m p r 2 3 c 9 c 1 0 f e e d b a c k 1 c o n t r o l o c 1 c o n t r o l l 1 c 2 q 2 d 1 q 1 c 1 2 r 6 r 7 r 4 l e d _ o u t ( + ) l e d _ o u t ( - ) u 1 o v p 3 g n d 7 r 1 1 r 1 7 r e g e r 2 1 4 g n d 7 c 6 r e r e r _ o u t a u t o r e s t a r t p r o t e c t i o n BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 14 nov. 27 , 2 013 9. desi gn notes 9.1 peripheral components take care to use the proper rating and proper type of components. ? input and output electrolytic capacit ors , c1 and c2 ? apply proper design margin to accommodate ripple current, voltage, and temperature rise. ? use of high ripple current and low impedance types, designed for switch - mode power supplies, is recommended, depending on their purposes. ? inductor, l1 ? apply proper design margin to temperature rise by core loss and copper loss. ? apply proper design margin to core saturation ? current detection resistor s , r4 and r11 choose a type of low internal inductance because a high frequency switching current fl ows to the c urrent detection resisto r , and of properly allowable dissipation . 9.2 inductor design parameters the crm * or dcm* mode of boost converter with pwm dimming can improve the output current rise during pwm dimming. * crm is the critical conduction mode , dcm is the discontinuous conduction mode. the crm or dcm inductor design procedure is described as follow: (1) on - duty setting the output voltage of boost converter is more than the input voltage. the on - duty, d on can be calculated using following equation. the equality of the equation means the condition of crm mode operation and the inequality means that of dcm mode operation. (9 - 1) where: v in is the minimum input voltage, v out is the maximum forward voltage drop of led string. d on is selected by the above equation applied to crm or dcm mode. in case f pwm = 100 khz, the range of d on should be 1.4 % to 90 %. in case f pwm = 500 khz, the range of d on should be 7 % to 90 %. (the minimum value results from the condition of t min = 140 ns, and f pwm . t he maximum value is d max ). (2) pwm oscillation frequency selection the pwm oscillation frequency of drv pin, f pwm , depends on the value of r22 connected to f set pin. the value of f pwm is set by figure 8 - 9 . (3) inductance value, l the inductance value, l, for dcm or crm mode can be calculated as follow: (9 - 2) where: i out is the maximum output current, f pwm is the maximum operation frequency of pwm (4) peak inductor current, i lp (9 - 3) (5) inductor selection the inductor should be applied the value of inductance, l, from equation (9 - 2) and the dc superimposition characteristics being higher than the peak inductor current, i lp , from equation (9 - 3). 9.3 pcd trace layout and component placement since the pcb circuit trace design and the component layout significantly affects operation, emi noise, and power dissipation , the high frequency pcb trace as shown in figure 9 - 1 should be low impedance with small loop and wide trace. figure 9 - 1 high - frequency current l oops (hatched areas) in addition, the ground traces affect radiated emi noise, and wide, short traces should be taken into account. figure 9 - 2 shows the circuit design example. (1) main circuit trace layout this is the main trace containing switching currents, and thus it should be as wide trace and small loop as possible. c1 s hould be connected near the inductors, l1, in order to reduce impedance of the high frequency current loop. (2) control ground trace layout since the operation of ic may be affected from the large current of the main trace that flows in control ground trace, t he control ground trace should be out in out on v v v d ? ? ? ? ? ? in ut o pwm out 2 on in v v f i 2 d v l ? ? ? ? ? ? pwm on in lp f l d v i ? ? ? l 1 c 1 q 1 c 2 d 1 BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 15 nov. 27 , 2 013 connected at a single point grounding of point a with a dedicated trace. (3) current detection resistor trace layout r4 and r11 are current detection resistors. the trace from the base of current detection resistor should be c onnected to the pin of ic with a dedicated trace. (4) comp pin trace layout for compensation component r23, c9 and c10 are compensation components. the trace of the compensation component should be connected as close as possible to the pin of ic, to reduce the influence of noise. (5) bypass capacitor trace layout on vcc , reg, and vref pins c8, c6 and c5 of bypass capacitors, connected to vcc, reg, and vref pins respectively, should be connected as close as possible to the pin of ic (6) power mosfet gate trace layout r 3 for q1 and r 10 for q2 should be connected near each the gate of the power mosfet s and the ground line side of the current detection resistance . peripheral components of q1 ( r 1, r 2, and d 2) and q2 (r8, r9, and d3) should be connected as close as possibl e between each the gate of the power mosfet s and the pin of ic. figure 9 - 2 peripheral circuit example around the ic f 1 l 1 q 1 d 1 c 2 l e d _ o u t ( + ) l e d _ o u t ( ? ) q 2 c 1 3 c 1 2 c 1 1 d 3 c 9 c 1 0 v c c _ i n e r _ o u t o n / o f f p w m _ i n s _ g n d q 3 c 3 c 4 r 1 r 1 3 q 4 c 1 c 8 p _ i n p _ g n d c 5 c 7 r 2 r 3 r 4 r 5 r 6 r 7 r 8 r 9 r 1 0 r 1 1 r 1 2 r 1 4 r 1 5 r 1 6 r 1 7 r 1 8 r 1 9 r 2 1 d 2 c 6 r 2 0 r 2 2 r 2 3 v c c 1 4 3 2 s w d r v o c g n d f s e t ( n . c . ) p w m u 1 b l 0 1 0 0 a 7 6 5 1 2 1 3 1 4 o v p r e g v r e f i f b c o m p 9 8 1 0 1 1 e r a ( 1 ) m a i n c i r c u i t t r a c e s h o u l d b e a s w i d e t r a c e a n d s m a l l l o o p . ( 4 ) c o m p p i n p e r i p h e r a l c o m p o n e n t s s h o u l d b e c o n n e c t e d a s c l o s e a s p o s s i b l e t o t h e p i n o f i c . ( 3 ) c u r r e n t d e t e c t i o n r e s i s t a n c e s h o u l d b e c o n n e c t e d t o t h e p i n o f i c w i t h a d e d i c a t e d t r a c e . ( 6 ) p o w e r m o s f e t g a t e t r a c e l a y o u t r 3 ( r 1 0 ) s h o u l d b e c o n n e c t e d n e a r g a t e o f q 1 ( q 2 ) a n d g r o u n d l i n e s i d e o f r 4 ( r 1 1 ) . r 1 , r 2 a n d d 2 ( r 8 , r 9 a n d d 3 ) a r e s h o u l d b e c o n n e c t e d a s c l o s e a s p o s s i b l e b e t w e e n g a t e o f q 1 ( q 2 ) a n d d r v ( s w ) p i n . ( 5 ) b y p a s s c a p a c i t o r c 5 , c 6 , c 8 s h o u l d b e c o n n e c t e d a s c l o s e a s p o s s i b l e t o t h e p i n o f i c . ( 2 ) c o n t r o l g r o u n d t r a c e l a y o u t s h o u l d b e c o n n e c t e d a t a s i n g l e p o i n t g r o u n d i n g o f p o i n t a w i t h a d e d i c a t e d t r a c e BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 16 nov. 27 , 2 013 10. reference design of power supply as an example, the followi ng show a power supply specification, circuit schematic, bill of materials, and transformer specification. this reference design is the example of the value of parts, and should be adjusted based on actual operation in the application. ? power supply spec ification ic BL0100A input voltage dc 24 v maximum output power 20 w (max . ) drv pin oscillation frequency 100 khz output voltage 50 v output current 400 ma ? circuit schematic f 1 vcc 1 4 3 2 sw drv oc gnd fset ( n . c .) pwm u 1 b l 0 1 0 0 a 7 6 5 12 13 14 ovp reg vref ifb comp 9 8 10 11 er l 1 q 1 d 1 c 2 led _ out (+) led _ out ( - ) q 2 c 13 c 12 c 11 d 3 c 9 c 10 vcc _ in er _ out on / off pwm _ in s _ gnd q 3 c 3 c 4 r 1 r 13 q 4 c 1 c 8 p _ in p _ gnd c 5 c 7 r 2 r 3 r 4 r 5 r 6 r 7 r 8 r 9 r 10 r 11 r 12 r 14 r 15 r 16 r 17 r 18 r 20 r 22 d 2 c 6 r 21 r 24 r 25 r 19 r 23 BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 17 nov. 27 , 2 013 ? bill of materials symbol part type ratings (1) recommended sanken parts symbol part type ratings (1) recommended sanken parts f1 fuse 3 a r3 general , chip, 2012 10 k l1 inductor 50 h, 3 a r4 general 0.22 , 2 w d1 fast recovery 200 v, 1.5 a el 1z r5 general , chip, 2012 100 d2 sch ottky 30 v, 1 a sjpa - d3 r 6 ( 3 ) general , chip, 2012 220 k d3 schottky 30 v, 1 a sjpa - d3 r 7 ( 2 ) general , chip, 2012 11 k q1 power mosfet 200 v, 45 m (typ.) skp202 r8 general , chip, 2012 470 q2 power mosfet 100 v, 1 (typ.) r9 general , ch ip, 2012 1.5 k q3 pnp transistor ? 50 v, 0.1 a r10 general , chip, 2012 10 k q4 npn transistor 50 v, 0.1 a r 11 general , chip, 2012 1.35 , 11 w c1 electrolytic 50 v, 2 2 f r12 general , chip, 2012 1.5 k c2 electrolytic 100 v, 100 f r13 general , chip, 2012 10 k c 3 electrolytic 50 v, 47 f r14 general , chip, 2012 12 k c 4 ceramic , chip, 2012 50 v, 0.1 f r15 general , chip, 2012 10 k c 5 ceramic , chip, 2012 0.1 f r16 general , chip, 2012 15 k c6 ceramic , chip, 2012 0.1 f r17 general , chip, 2012 10 k c7 ceramic , chip, 2012 0.1 f r18 general , chip, 2012 82 k c8 (2) ceramic , chip, 2012 50 v, 0.1 f r19 ( 2 ) general , chip, 2012 560 c9 ceramic , chip, 2012 0.047 f r20 general , chip, 2012 10 k c10 ceram ic , chip, 2012 2200 pf r21 general , chip, 2012 10 k c 11 ceramic , chip, 2012 100 pf r22 general , chip, 2012 33 k c 12 (2) ceramic , chip, 2012 10 nf r23 general , chip, 2012 1 k c 13 (2) ceramic , chip, 2012 100 pf r24 general , chip, 2012 open r 1 general , chip, 2012 10 r25 general , chip, 2012 22 k r 2 general , chip, 2012 100 u1 ic BL0100A (1) unless otherwise specified, the voltage rating of capacitor is 50v or less, and the power rating of resistor is 1/8w or less. (2) it is necessary t o be adjusted based on actual operation in the application. (3) resistors applied high dc voltage and of high resistance are recommended to select resistor s designed against e lectromigration or use combination s of resistors in series for that to reduce each ap plied voltage, according to the requirement of the application. BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 18 nov. 27 , 2 013 operating precautions in the case that you use sanken products or design your products by using sanken products, the reliability largely depends on the degree of derating to be made to th e rated values. derating may be interpreted as a case that an operation range is set by derating the load from each rated value or surge voltage or noise is considered for derating in order to assure or improve the reliability. in general, derating factors include electric stresses such as electric voltage, electric current, electric power etc., environmental stresses such as ambient temperature, humidity etc. and thermal stress caused due to self - heating of semiconductor products. for these stresses, insta ntaneous values, maximum values and minimum values must be taken into consideration. in addition, it should be noted that since power devices or ics including power devices have large self - heating value, the degree of derating of junction temperature affe cts the reliability significantly. because reliability can be affected adversely by improper storage environments and handling methods, please observe the following cautions. cautions for storage ? ensure that storage conditions comply with the standard tem perature (5 to 35c) and the standard relative humidity (around 40 to 75%) ; avoid storage locations that experience extreme changes in temperature or humidity. ? avoid locations where dust or harmful gases are present and avoid direct sunlight. ? reinspect for rust on leads and solderability of the products that have been stored for a long time. cautions for testing and handling when tests are carried out during inspection testing and other standard test periods, protect the products from power surges from the testing device, shorts between the product pins, and wrong connectio ns. ensure all test parameters are within the ratings specified by sanken for the product s . soldering ? when soldering the products, please be sure to minimize the working time, within the f ollowing limits: ? 260 5 c 10 1 s (flow, 2 times) ? 380 10 c 3 .5 0.5 s (soldering iron , 1 time ) electrostatic discharge ? when handling the products, the operator must be grounded. grounded wrist straps worn should have at least 1m of resistance from the operator to ground to prevent shock hazard, and it should be placed near the operator. ? workbenches where the products are handled should be grounded and be provided with conductive table and floor mats. ? when using measuring equipme nt such as a curve tracer, the equipment should be grounded. ? when soldering the products, the head of soldering irons or the solder bath must be grounded in order to prevent leak voltages generated by them from being applied to the products. ? the products s hould always be stored and transported in sanken shipping containers or conductive containers, or be wrapped in aluminum foil. BL0100A BL0100A - ds rev. 1.1 sanken electric co.,ltd. 19 nov. 27 , 2 013 important notes ? the contents in this document are subject to changes, for improvement and other purposes, without notice. make sure that this is the latest revision of the document before use. ? application and operation examples described in this document are quoted for the sole purpose of reference for the use of the products herein and sanken can assume no responsibility for any infringement of industrial property rights, intellectual property rights or any other rights of sanken or any third party which may result from its use. unless otherwise agreed in writing by sanken, sanken makes no warranties of any kind, whether express o r implied, as to the products, including product merchantability, and fitness for a particular purpose and special environment, and the information, including its accuracy, usefulness, and reliability, included in this document. ? although sanken undertakes to enhance the quality and reliability of its products, the occurrence of failure and defect of semiconductor products at a certain rate is inevitable. users of sanken products are requested to take, at their own risk, preventative measures including safet y design of the equipment or systems against any possible injury, death, fires or damages to the society due to device failure or malfunction. ? sanken products listed in this document are designed and intended for the use as components in general purpose el ectronic equipment or apparatus (home appliances, office equipment, telecommunication equipment, measuring equipment, etc.). when considering the use of sanken products in the applications where higher reliability is required (transportation equipment and its control systems, traffic signal control systems or equipment, fire/crime alarm systems, various safety devices, etc.), and whenever long life expectancy is required even in general purpose electronic equipment or apparatus, please contact your nearest sanken sales representative to discuss, prior to the use of the products herein. the use of sanken products without the written consent of sanken in the applications where extremely high reliability is required (aerospace equipment, nuclear power control systems, life support systems, etc.) is strictly prohibited. ? when using the products specified herein by either (i) combining other products or materials therewith or (ii) physically, chemically or otherwise processing or treating the products, please duly consider all possible risks that may result from all such uses in advance and proceed therewith at your own responsibility. ? anti radioactive ray design is not considered for the products listed herein. ? sanken assumes no responsibility for any troubles, su ch as dropping products caused during transportation out of sankens distribution network. ? the contents in this document must not be transcribed or copied without sankens written consent. |
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