parameter max. units i d @ t c = 25c continuous drain current, v gs @ 10v 142 � i d @ t c = 100c continuous drain current, v gs @ 10v 100 � a i dm pulsed drain current � � 570 p d @t c = 25c power dissipation 380 w linear derating factor 2.5 w/c v gs gate-to-source voltage 20 v e as single pulse avalanche energy � 1250 mj i ar avalanche current � see fig.12a, 12b, 15, 16 a e ar repetitive avalanche energy � mj dv/dt peak diode recovery dv/dt � 5.2 v/ns t j operating junction and -55 to + 175 t stg storage temperature range soldering temperature, for 10 seconds 300 (1.6mm from case ) c mounting torque, 6-32 or m3 screw 10 lbf?in (1.1n?m) hexfet ? power mosfet this stripe planar design of hexfet ? power mosfets utilizes the lastest processing techniques to achieve extremely low on-resistance per silicon area. additional features of this hexfet power mosfet are a 175c junction operating temperature, fast switching speed and improved repetitive avalanche rating. these benefits combine to make this design an extremely efficient and reliable device for use in a wide variety of applications. s d g absolute maximum ratings v dss = 75v r ds(on) = 0.0075 ? i d = 142a � description �������� www.irf.com 1 � ultra low on-resistance � dynamic dv/dt rating � 175c operating temperature � fast switching � repetitive avalanche allowed up to tjmax � lead-free benefits to-220ab IRF1607PBF parameter typ. max. units r jc junction-to-case ??? 0.40 r cs case-to-sink, flat, greased surface 0.50 ??? c/w r ja junction-to-ambient ??? 62 thermal resistance typical applications � industrial motor drive ��������
�������� � 2 www.irf.com parameter min. typ. max. units conditions v (br)dss drain-to-source breakdown voltage 75 ??? ??? v v gs = 0v, i d = 250a ? v (br)dss / ? t j breakdown voltage temp. coefficient ??? 0.086 ??? v/c reference to 25c, i d = 1ma r ds(on) static drain-to-source on-resistance ??? 0.00580.0075 ? v gs = 10v, i d = 85a � v gs(th) gate threshold voltage 2.0 ??? 4.0 v v ds = 10v, i d = 250a g fs forward transconductance 79 ??? ??? s v ds = 25v, i d = 85a ??? ??? 20 a v ds = 75v, v gs = 0v ??? ??? 250 v ds = 60v, v gs = 0v, t j = 150c gate-to-source forward leakage ??? ??? 200 v gs = 20v gate-to-source reverse leakage ??? ??? -200 na v gs = -20v q g total gate charge ??? 210 320 i d = 85a q gs gate-to-source charge ??? 45 68 nc v ds = 60v q gd gate-to-drain ("miller") charge ??? 73 110 v gs = 10v t d(on) turn-on delay time ??? 22 ??? v dd = 38v t r rise time ??? 130 ??? i d = 85a t d(off) turn-off delay time ??? 84 ??? r g = 1.8 ? t f fall time ??? 86 ??? v gs = 10v � between lead, ??? ??? 6mm (0.25in.) from package and center of die contact c iss input capacitance ??? 7750 ??? v gs = 0v c oss output capacitance ??? 1230 ??? pf v ds = 25v c rss reverse transfer capacitance ??? 310 ??? ? = 1.0mhz, see fig. 5 c oss output capacitance ??? 5770 ??? v gs = 0v, v ds = 1.0v, ? = 1.0mhz c oss output capacitance ??? 790 ??? v gs = 0v, v ds = 60v, ? = 1.0mhz c oss eff. effective output capacitance � ??? 1420 ??? v gs = 0v, v ds = 0v to 60v nh electrical characteristics @ t j = 25c (unless otherwise specified) l d internal drain inductance l s internal source inductance ??? ??? s d g i gss ns 4.5 7.5 i dss drain-to-source leakage current s d g parameter min. typ. max. units conditions i s continuous source current mosfet symbol (body diode) ??? ??? showing the i sm pulsed source current integral reverse (body diode) � ??? ??? p-n junction diode. v sd diode forward voltage ??? ??? 1.3 v t j = 25c, i s = 85a, v gs = 0v �� t rr reverse recovery time ??? 130 200 ns t j = 25c, i f = 85a q rr reverse recoverycharge ??? 690 1040 nc di/dt = 100a/s � � t on forward turn-on time intrinsic turn-on time is negligible (turn-on is dominated by l s +l d ) source-drain ratings and characteristics 142 � 570 � � � repetitive rating; pulse width limited by max. junction temperature. (see fig. 11). � � starting t j = 25c, l = 0.21mh r g = 25 ? , i as = 85a, v gs =10v (see figure 12). � i sd 85a, di/dt 310a/s, v dd v (br)dss , t j 175c � pulse width 400s; 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 . �� calculated continuous current based on maximum allowable junction temperature. package limitation current is 75a. �� limited by t jmax , see fig.12a, 12b, 15, 16 for typical repetitive avalanche performance.
�������� � www.irf.com 3 fig 4. normalized on-resistance vs. temperature fig 2. typical output characteristics fig 1. typical output characteristics fig 3. typical transfer characteristics 1 10 100 1000 0.1 1 10 100 20s pulse width t = 175 c j top bottom vgs 15v 10v 8.0v 7.0v 6.0v 5.5v 5.0v 4.5v v , drain-to-source voltage (v) i , drain-to-source current (a) ds d 4.5v 1 10 100 1000 4.0 5.0 6.0 7.0 8.0 9.0 10.0 v = 25v 20s pulse width ds v , gate-to-source voltage (v) i , drain-to-source current (a) gs d t = 25 c j t = 175 c j -60 -40 -20 0 20 40 60 80 100 120 140 160 180 0.0 0.5 1.0 1.5 2.0 2.5 3.0 t , junction temperature ( c) r , drain-to-source on resistance (normalized) j ds(on) v = i = gs d 10v 142a 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 ) 4.5v 20s pulse width tj = 25c vgs top 15v 10v 8.0v 7.0v 6.0v 5.5v 5.0v bottom 4.5v
�������� � 4 www.irf.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 0 100 200 300 400 0 4 8 12 16 20 q , total gate charge (nc) v , gate-to-source voltage (v) g gs for test circuit see figure i = d 13 85a v = 15v ds v = 37v ds v = 60v ds 0.1 1 10 100 1000 0.2 0.6 1.0 1.4 1.8 2.2 v ,source-to-drain voltage (v) i , reverse drain current (a) sd sd v = 0 v gs t = 25 c j t = 175 c j 1 10 100 v ds , drain-to-source voltage (v) 0 2000 4000 6000 8000 10000 12000 c , c a p a c i t a n c e ( p f ) coss crss ciss 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 1 10 100 1000 v ds , drain-tosource voltage (v) 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
�������� � www.irf.com 5 fig 11. maximum effective transient thermal impedance, junction-to-case fig 9. maximum drain current vs. case temperature 0.001 0.01 0.1 1 0.00001 0.0001 0.001 0.01 0.1 1 notes: 1. duty factor d = t / t 2. peak t = p x z + t 1 2 j dm thjc c p t t dm 1 2 t , rectangular pulse duration (sec) thermal response (z ) 1 thjc 0.01 0.02 0.05 0.10 0.20 d = 0.50 single pulse (thermal response) 25 50 75 100 125 150 175 0 40 80 120 160 t , case temperature ( c) i , drain current (a) c d limited by package v ds 90% 10% v gs t d(on) t r t d(off) t f � �� ������
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�������� � 6 www.irf.com 25 50 75 100 125 150 175 0 500 1000 1500 2000 2500 3000 starting t , junction temperature ( c) e , single pulse avalanche energy (mj) j as i d top bottom 35a 60a 85a q g q gs q gd v g charge d.u.t. v ds i d i g 3ma v gs .3 f 50k ? .2 f 12v current regulator same type as d.u.t. current sampling resistors + - ���
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 -75 -50 -25 0 25 50 75 100 125 150 175 200 t j , temperature ( c ) 1.0 2.0 3.0 4.0 5.0 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 = 250a
�������� � www.irf.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-07 1.0e-06 1.0e-05 1.0e-04 1.0e-03 1.0e-02 1.0e-01 tav (sec) 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) 0 200 400 600 800 1000 1200 1400 e a r , a v a l a n c h e e n e r g y ( m j ) top single pulse bottom 10% duty cycle i d = 85a
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�������� � www.irf.com 9 data and specifications subject to change without notice. this product has been designed and qualified for the industrial market. qualification standards can be found on ir?s web site. ir world headquarters: 233 kansas st., el segundo, california 90245, usa tel: (310) 252-7105 tac fax: (310) 252-7903 visit us at www.irf.com for sales contact information . 09/2010 ���������
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���� note: "p" inas s embly line pos ition indicates "l ead - f ree" line c week 19 part number dat e code year 7 = 1997 as s embled on ww 19, 1997 t his is an irf1010 example: in the assembly line "c" lot code 1789 international as s e mb l y lot code rectifier logo to-220ab packages are not recommended for surface mount application. notes: 1. for an automotive qualified version of this part please see http://www.irf.com/product-info/auto/ 2. for the most current drawing please refer to ir website at http://www.irf.com/package/
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