r ev . a j u n .2 0 1 0 c o p y r igh t @ w i n s em i microelectronics c o . , lt d . , a l l ri g h t r e s er v ed . w w w w f f f f p p p p 6 6 6 6 3 3 3 3 0 0 0 0 s s s s ilic ilic ilic ilic o o o o n n n n n n n n - - - - c c c c h h h h a a a a nn nn nn nn e e e e l l l l m m m m os os os os f f f f e e e e t t t t f f f f e e e e a a a a t t t t u u u u r r r r e e e e s s s s 9 a , 200 v , r d s ( on ) ( m a x 0.4 ) @ v g s = 10 v u l t ra- l o w g a t e charge( t yp i ca l 22nc ) f as t s w i t ch i n g capab ili t y 100 % a v a l an c h e t e ste d m ax i m u m j unc t i o n t e m p era t ur e range(150 ) g g g g e e e e n n n n e e e e r r r r a a a a l l l l d d d d e e e e sc sc sc sc rip rip rip rip t t t t ion ion ion ion t h is p o w e r m o s f e t is produ c e d u s i n g w i n s e m i s advan c e d p l ana r s tr i pe , d m os t echno l og y . t h is l a t es t t echno l og y ha s bee n espe c i a l l y de s i gne d t o mi n im i z e on- st at e re s i s t ance , hav e a h i g h rugge d ava l an c h e c hara c ter i s t i c s . t h is dev i c e s is s pec i a lly we ll s u i te d f o r l o w vo l t ag e app li ca t i on s s uc h a s au t o m ot i ve , h i g h eff i c i en c y s w i tc h i n g f o r dc / d c c onver t ers , an d d c m oto r c on t ro l. a a a a b b b b s s s s o o o o l l l l u u u u t t t t e e e e m m m m ax ax ax ax i i i i m m m m u u u u m m m m r r r r a a a a ti ti ti ti n n n n g g g g s s s s g g g g d d d d s s s s t t t t o o o o 2 2 2 2 2 2 2 2 0 0 0 0 s y m b o l p a r a m e t e r v alu e u n i ts v d s s dr a i n s our ce v o l t a g e 2 0 0 v i d con t i nuou s dra in curren t ( @ t c = 2 5 ) 9 a con t i nuou s dra in curren t ( @ t c = 10 0 ) 5 . 7 a i dm dra in curren t p u l se d (no t e1 ) 3 6 a v g s g a t e t o s our c e v o l t ag e 3 0 v e a s s i ng le p u l se d a va l anch e e nerg y ( no t e 2 ) 16 0 mj e a r repe t i t i v e a va l anch e e nerg y ( no t e 1 ) 7 . 2 mj dv / d t p ea k d i od e re c over y dv / d t (no t e 3 ) 5 . 5 v /n s p d t o t a l p o w e r d i s s i pat i on ( @ t c = 25 ) 7 2 w dera t i n g f ac t o r abov e 25 0.5 7 w / t j , t s tg j unc t i o n an d s torag e t e m peratur e -55 ~ 15 0 t l m ax i m u m l ea d t e m pera t ur e f o r s o l der i n g purpo s e s 30 0 t t t t h h h h e e e e rm rm rm rm al al al al ch ch ch ch a a a a r r r r ac ac ac ac t t t t e e e e ri ri ri ri s s s s t t t t i i i i cs cs cs cs s y m bo l p a r a m e t e r v alu e u n i ts m i n t y p m a x r q j c t her m a l re s i s t ance , jun c t i on- t o-ca s e - - 1 . 7 4 / w r q cs t her m a l re s i s t ance , ca s e t o s i n k - 0 . 5 - / w r q j a t her m a l re s i s t ance , jun c t i on- t o- a m b i en t - - 62 . 5 / w
2 /7 steady, steady, steady, steady, keep keep keep keep you you you you advance advance advance advance e e e e l l l l ec ec ec ec t t t t r r r r i i i i cal cal cal cal ch ch ch ch a a a a r r r r ac ac ac ac t t t t e e e e r r r r i i i i s s s s t t t t i i i i cs cs cs cs ( ( ( ( t t t t c c c c = = = = 25 25 25 25 c c c c ) ) ) ) c h a r ac t e r i s t i c s s y m b o l t e s t c o nd i t i o n mi n t y p e m a x u n i t g a t e l ea k ag e c urren t i g s s v g s = 3 0 v , v ds = 0 v - - 1 0 0 n a g a t e ? s our c e brea k dow n vo l t ag e v ( b r )g s s i g = 1 0 a , v ds = 0 v 3 0 - - v dra in c u t ? o f f c urren t i d s s v ds = 20 0 v , v g s = 0 v - - 1 0 a dra i n ? s ourc e brea k do w n vo l t ag e v ( b r ) d s s i d = 25 0 a , v g s = 0 v 2 0 0 - - v b rea k v o l tag e t e m pera t ur e coe ff i c i en t b v d s s / t j i d = 25 0 a , re f eren c e d t o 25 - 0 . 2 - v / g a t e t hre s ho ld vo l t ag e v g s ( th) v ds = 1 0 v , i d = 25 0 a 2 - 4 v dra i n ? s ourc e on re s i s t anc e r d s (o n) v g s = 1 0 v , i d = 4 . 5 a - - 0 . 4 ? f orwar d t ran s condu c tan c e g f s v ds = 5 0 v , i d = 4 . 5 a - 7 . 0 5 - s i npu t capa c i tan c e c i s s v ds = 2 5 v , v g s = 0 v , f = 1 m h z - 50 0 72 0 p f rever s e t rans f e r c apac i t anc e c r s s - 2 2 2 9 o u t pu t c apac i t anc e c o s s - 8 5 11 0 s w i tc h i n g t ime r i s e t ime t r v dd = 10 0 v , i d = 9 a r g = 1 2 ? (no t e4 , 5 ) - 1 1 3 0 n s t urn ? o n t ime t on - 7 0 15 0 f a ll t ime t f - 6 0 13 0 t urn ? o f f t ime t off - 6 5 14 0 t o t a l ga t e c harg e (ga t e ? s ourc e p l u s ga t e ? dra i n ) q g v dd = 16 0 v , v g s = 1 0 v , i d = 9 a (no t e4 , 5 ) - 2 2 2 9 n c g a t e ? s our c e c harg e q gs - 3 . 6 - g a t e ? dra in ( m i ll er ) charg e q gd - 1 0 - sou sou sou sou r r r r c c c c e e e e ? ? ? ? d d d d r r r r a a a a i i i i n n n n r r r r a a a a t t t t ing ing ing ing s s s s a a a a n n n n d d d d ch ch ch ch a a a a r r r r ac ac ac ac t t t t e e e e r r r r i i i i s s s s t t t t i i i i cs cs cs cs ( ( ( ( t t t t a a a a = = = = 25 25 25 25 c c c c ) ) ) ) c h a r a c t e r i s t i c s s y m b o l t e s t c o nd i t i o n m i n t y p e m a x u n i t con t i nuou s dra in rever s e c urren t i dr - - - 9 a p u l s e dra in rever s e c urren t i drp - - - 3 6 a f or w a r d vo l t ag e (d i ode ) v d s f i dr = 9 a , v gs = 0 v - 1 . 4 1 . 5 v rever s e re c over y t i me t r r i dr = 9 a , v g s = 0 v , di dr / d t = 10 0 a / s - 14 0 - n s rever s e re c over y charg e q r r - 1 . 1 2 . 2 c n o t e 1 . r e pea t i v i t y r at in g : p u l s e w id t h limi te d b y j u n c t i o n t e mper a t ur e 2 . l = 5 00uh , i as =9 a ,v dd = 50 v , r g = 0 , s t ar t i n g t j =2 5 3 . i s d 9 a, di / d t 3 00 a / u s , v dd < bv d ss ,s t a r t i n g tj = 2 5 4 . p ul se t e s t : p ul se w i dt h 3 0 0 u s , du t y c y c le 2 % 5 . e s s e n t i a ll y i n de p end e n t o f o per at in g t em p era t ur e . t h i s t r a n s i s t o r i s a n e le c t r o s t a t i c s e n s i t i ve d e v i ce p lea se h andl e w i t h c a u t io n WFP630 WFP630 WFP630 WFP630
3 /7 steady, steady, steady, steady, keep keep keep keep you you you you advance advance advance advance fig. 1 o n-s t a t e c ha r a c t e r is t ics fig.2 t r ans f er c ha r a c t e r is t ics fig.3 o n- r esis t ance v a r i a t ion vs d r ain c u r re nt fig.5 o n- r esis t ance v a r i a t ion vs ju nc t ion t e mpe r a t u r e fig.4 b ody d i o de f o r w a r d v ol t a ge v a r ia t ion vs. sou rc e c u r r en t and t empe r a t ur e fig.6 g a t e c ha rg e c ha r ac t e r is t ics WFP630 WFP630 WFP630 WFP630
4 /7 steady, steady, steady, steady, keep keep keep keep you you you you advance advance advance advance fig.8 c ap aci t a n ce c h ara c t e r is t ics fig.9 b rea kdown v ol t a ge v a r ia t ion vs. t empe r a t u r e fig.9 maximum safe o pe r a t ion a r ea fig.10 maximum d r ain c u r re nt vs c ase t e mpe r a t u r e fig.11 t r ansient th e r m al r esponse c u r v e WFP630 WFP630 WFP630 WFP630
5 /7 steady, steady, steady, steady, keep keep keep keep you you you you advance advance advance advance fig.10 g a t e t e st c i r cuit & wave f o r m fig.11 r esis t i v e swi t c hing t e st c i r cuit & wave f o r m fig.12 u n c lamped induc t i v e swi t c hing t e st c i r cuit & wave f o r m WFP630 WFP630 WFP630 WFP630
6 /7 steady, steady, steady, steady, keep keep keep keep you you you you advance advance advance advance fig.13 p e ak d iode r ec o v e r y dv/dt t e st c i r cuit & wave f o r m WFP630 WFP630 WFP630 WFP630
7 /7 steady, steady, steady, steady, keep keep keep keep you you you you advance advance advance advance t t t t o o o o -2 -2 -2 -2 2 2 2 2 0 0 0 0 pa pa pa pa c c c c ka ka ka ka ge ge ge ge dim dim dim dim e e e e n n n n s s s s i i i i on on on on unit: unit: unit: unit: m m m m m m m m WFP630 WFP630 WFP630 WFP630
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