�������� www.kersemi.com 1 hexfet ? power mosfet v dss = 55v r ds(on) = 7.5m ? i d = 42a specifically designed for automotive applications, this hexfet ? power mosfet utilizes the latest processing techniques to achieve extremely low on-resistance per silicon area. additional features of this design are a 175c junction operating temperature, fast switching speed and improved repetitive avalanche rating . these features com- bine to make this design an extremely efficient and reliable device for use in automotive applications and a wide variety of other applications. s d g description � advanced process technology � ultra low on-resistance � 175c operating temperature � fast switching � repetitive avalanche allowed up to tjmax � lead-free features d-pak irfr1010z i-pak irfu1010z automotive mosfet pd - 95951 IRFR1010ZPBF irfu1010zpbf absolute maximum ratings parameter units i d @ t c = 25c continuous drain current, v gs @ 10v (silicon limited) i d @ t c = 100c continuous drain current, v gs @ 10v a i d @ t c = 25c continuous drain current, v gs @ 10v (package limited) i dm pulsed drain current � p d @t c = 25c power dissipation w linear derating factor w/c v gs gate-to-source voltage v e as (thermally limited) single pulse avalanche energy � mj e as (tested ) single pulse avalanche energy tested value � i ar avalanche current �� a e ar repetitive avalanche energy � mj t j operating junction and t stg storage temperature range c soldering temperature, for 10 seconds mounting torque, 6-32 or m3 screw thermal resistance parameter typ. max. units r jc junction-to-case � ??? 1.11 r ja junction-to-ambient (pcb mount) �� ??? 40 c/w r ja junction-to-ambient � ??? 110 220 110 see fig.12a, 12b, 15, 16 140 0.9 20 max. 91 65 360 42 -55 to + 175 300 (1.6mm from case ) 10 lbf � in (1.1n � m)
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� 2 www.kersemi.com s d g el ectr i ca l ch aracter i st i cs @ t j = 2 5 c ( un l ess ot h erw i se spec ifi e d) parameter min. typ. max. units v (br)dss drain-to-source breakdown voltage 55 ??? ??? v ? v (br)dss / ? t j breakdown voltage temp. coefficient ??? 0.051 ??? v/c r ds(on) static drain-to-source on-resistance ??? 5.8 7.5 m ? v gs(th) gate threshold voltage 2.0 ??? 4.0 v gfs forward transconductance 31 ??? ??? s i dss drain-to-source leakage current ??? ??? 20 a ??? ??? 250 i gss gate-to-source forward leakage ??? ??? 200 na gate-to-source reverse leakage ??? ??? -200 q g total gate charge ??? 63 95 q gs gate-to-source charge ??? 17 ??? nc q gd gate-to-drain ("miller") charge ??? 23 ??? t d(on) turn-on delay time ??? 17 ??? t r rise time ??? 76 ??? t d(off) turn-off delay time ??? 42 ??? ns t f fall time ??? 48 ??? l d internal drain inductance ??? 4.5 ??? between lead, nh 6mm (0.25in.) l s internal source inductance ??? 7.5 ??? from package and center of die contact c iss input capacitance ??? 2840 ??? c oss output capacitance ??? 470 ??? c rss reverse transfer capacitance ??? 250 ??? pf c oss output capacitance ??? 1630 ??? c oss output capacitance ??? 360 ??? c oss eff. effective output capacitance ??? 560 ??? source-drain ratin g s and characteristics parameter min. typ. max. units i s continuous source current ??? ??? 42 (body diode) a i sm pulsed source current ??? ??? 360 (body diode) �� v sd diode forward voltage ??? ??? 1.3 v t rr reverse recovery time ??? 24 36 ns q rr reverse recovery charge ??? 20 30 nc t on forward turn-on time intrinsic turn-on time is negligible (turn-on is dominated by ls+ld) v gs = 10v � v dd = 28v i d = 42a r g = 7.6 ? t j = 25c, i s = 42a, v gs = 0v � t j = 25c, i f = 42a, v dd = 28v di/dt = 100a/s � conditions v gs = 0v, i d = 250a reference to 25c, i d = 1ma v gs = 10v, i d = 42a � v ds = v gs , i d = 100a v ds = 55v, v gs = 0v v ds = 55v, v gs = 0v, t j = 125c mosfet symbol showing the integral reverse p-n junction diode. conditions v gs = 10v � v gs = 0v v ds = 25v ? = 1.0mhz v gs = 0v, v ds = 1.0v, ? = 1.0mhz v gs = 0v, v ds = 44v, ? = 1.0mhz v gs = 0v, v ds = 0v to 44v � v gs = 20v v gs = -20v v ds = 44v v ds = 25v, i d = 42a i d = 42a
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� www.kersemi.com 3 fig 2. typical output characteristics fig 1. typical output characteristics fig 3. typical transfer characteristics fig 4. typical forward transconductance vs. drain current 0.1 1 10 100 v ds , drain-to-source voltage (v) 1 10 100 1000 i d , d r a i n - t o - s o u r c e c u r r e n t ( a ) vgs top 15v 10v 8.0v 7.0v 6.0v 5.5v 5.0v bottom 4.5v 60s pulse width tj = 25c 4.5v 0.1 1 10 100 v ds , drain-to-source voltage (v) 1 10 100 1000 i d , d r a i n - t o - s o u r c e c u r r e n t ( a ) vgs top 15v 10v 8.0v 7.0v 6.0v 5.5v 5.0v bottom 4.5v 60s pulse width tj = 175c 4.5v 2 4 6 8 10 v gs , gate-to-source voltage (v) 0.1 1 10 100 1000 i d , d r a i n - t o - s o u r c e c u r r e n t ( ) t j = 25c t j = 175c v ds = 25v 60s pulse width 0 20406080100 i d ,drain-to-source current (a) 0 20 40 60 80 100 120 g f s , f o r w a r d t r a n s c o n d u c t a n c e ( s ) t j = 25c t j = 175c v ds = 10v 380s pulse width
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� 4 www.kersemi.com fig 8. maximum safe operating area fig 6. typical gate charge vs. gate-to-source voltage fig 5. typical capacitance vs. drain-to-source voltage fig 7. typical source-drain diode forward voltage 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 v sd , source-to-drain voltage (v) 0.10 1.00 10.00 100.00 1000.00 i s d , r e v e r s e d r a i n c u r r e n t ( a ) t j = 25c t j = 175c v gs = 0v 1 10 100 v ds , drain-to-source voltage (v) 0 1000 2000 3000 4000 5000 c , c a p a c i t a n c e ( p f ) v gs = 0v, f = 1 mhz c iss = c gs + c gd , c ds shorted c rss = c gd c oss = c ds + c gd c oss c rss c iss 0 20406080100 q g total gate charge (nc) 0 4 8 12 16 20 v g s , g a t e - t o - s o u r c e v o l t a g e ( v ) v ds = 44v vds= 28v vds= 11v i d = 42a 1 10 100 v ds , drain-tosource voltage (v) 0.1 1 10 100 1000 10000 i d , d r a i n - t o - s o u r c e c u r r e n t ( a ) tc = 25c tj = 175c single pulse 1msec 10msec operation in this area limited by r ds (on) 100sec dc
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� www.kersemi.com 5 fig 11. maximum effective transient thermal impedance, junction-to-case fig 9. maximum drain current vs. case temperature fig 10. normalized on-resistance vs. temperature 25 50 75 100 125 150 175 t c , case temperature (c) 0 20 40 60 80 100 i d , d r a i n c u r r e n t ( a ) limited by package -60 -40 -20 0 20 40 60 80 100 120 140 160 180 t j , junction temperature (c) 0.5 1.0 1.5 2.0 2.5 r d s ( o n ) , d r a i n - t o - s o u r c e o n r e s i s t a n c e ( n o r m a l i z e d ) i d = 42a v gs = 10v 1e-006 1e-005 0.0001 0.001 0.01 0.1 t 1 , rectangular pulse duration (sec) 0.001 0.01 0.1 1 10 t h e r m a l r e s p o n s e ( z t h j c ) 0.20 0.10 d = 0.50 0.02 0.01 0.05 single pulse ( thermal response ) notes: 1. duty factor d = t1/t2 2. peak tj = p dm x zthjc + tc ri (c/w) i (sec) 0.3854 0.000251 0.3138 0.001092 0.4102 0.015307 j j 1 1 2 2 3 3 r 1 r 1 r 2 r 2 r 3 r 3 c ci i / ri ci= i / ri
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� 6 www.kersemi.com q g q gs q gd v g charge ���� fig 13b. gate charge test circuit fig 13a. basic gate charge waveform fig 12c. maximum avalanche energy vs. drain current fig 12b. unclamped inductive waveforms fig 12a. unclamped inductive test circuit t p v (br)dss i as fig 14. threshold voltage vs. temperature r g i as 0.01 ? t p d.u.t l v ds + - v dd driver a 15v 20v v gs 1k vcc dut 0 l 25 50 75 100 125 150 175 starting t j , junction temperature (c) 0 100 200 300 400 500 e a s , s i n g l e p u l s e a v a l a n c h e e n e r g y ( m j ) i d top 7.6a 11a bottom 42a -75 -50 -25 0 25 50 75 100 125 150 175 t j , temperature ( c ) 1.0 1.5 2.0 2.5 3.0 3.5 4.0 v g s ( t h ) g a t e t h r e s h o l d v o l t a g e ( v ) i d = 1.0ma i d = 250a i d = 100a
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� www.kersemi.com 7 fig 15. typical avalanche current vs.pulsewidth fig 16. maximum avalanche energy vs. temperature notes on repetitive avalanche curves , figures 15, 16: (for further info, see an-1005 at www.irf.com) 1. avalanche failures assumption: purely a thermal phenomenon and failure occurs at a temperature far in excess of t jmax . this is validated for every part type. 2. safe operation in avalanche is allowed as long ast jmax is not exceeded. 3. equation below based on circuit and waveforms shown in figures 12a, 12b. 4. p d (ave) = average power dissipation per single avalanche pulse. 5. bv = rated breakdown voltage (1.3 factor accounts for voltage increase during avalanche). 6. i av = allowable avalanche current. 7. �' t = allowable rise in junction temperature, not to exceed t jmax (assumed as 25c in figure 15, 16). t av = average time in avalanche. d = duty cycle in avalanche = t av f z thjc (d, t av ) = transient thermal resistance, see figure 11) p d (ave) = 1/2 ( 1.3bvi av ) = � � t/ z thjc i av = 2 � t/ [1.3bvz th ] e as (ar) = p d (ave) t av 1.0e-06 1.0e-05 1.0e-04 1.0e-03 1.0e-02 1.0e-01 tav (sec) 0.1 1 10 100 1000 a v a l a n c h e c u r r e n t ( a ) 0.05 duty cycle = single pulse 0.10 allowed avalanche current vs avalanche pulsewidth, tav assuming �' tj = 25c due to avalanche losses 0.01 25 50 75 100 125 150 175 starting t j , junction temperature (c) 0 20 40 60 80 100 120 e a r , a v a l a n c h e e n e r g y ( m j ) top single pulse bottom 1% duty cycle i d = 42a
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� www.kersemi.com 11 � � repetitive rating; pulse width limited by max. junction temperature. (see fig. 11). � � limited by t jmax , starting t j = 25c, l = 0.13mh r g = 25 ? , i as = 42a, v gs =10v. part not recommended for use above this value. � pulse width 1.0ms; duty cycle 2%. ���
� � c oss eff. is a fixed capacitance that gives the same charging time as c oss while v ds is rising from 0 to 80% v dss . �� limited by t jmax , see fig.12a, 12b, 15, 16 for typical repetitive avalanche performance. �� this value determined from sample failure population. 100% tested to this value in production. � �� when mounted on 1" square pcb (fr-4 or g-10 material) . for recommended footprint and soldering techniques refer to application note #an-994 � ���� � ���������������� ) ������ ������!�"�#$ ������ �� �
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