Cool MOS Power Transistor Feature New revolutionary high voltage technology Worldwide best R DS(on) in TO 47 Ultra low gate charge Periodic avalanche rated Extreme dv/dt rated Ultra low effective capacitances Improved noise immunity SPW47N6C Product Summary V DS 6 V R DS(on).7 Ω I D 47 P-TO47 Type Package Ordering Code SPW47N6C P-TO47 Q674-S433 Marking 47N6C Maximum Ratings, at T C = 5 C, unless otherwise specified Parameter Symbol Value Unit Continuous drain current T C = 5 C T C = C I D 47 3 Pulsed drain current, t p limited by T jmax I D puls 94 valanche energy, single pulse E S 8 mj I D =, V DD =5V valanche energy, repetitive t R limited by T ) jmax E R I D =, V DD =5V valanche current, repetitive t R limited by T jmax I R Reverse diode dv/dt dv/dt 6 V/ns I S =47, V DS < V DD, di/dt=/µs, T jmax =5 C Gate source voltage V GS ± V Power dissipation, T C = 5 C P tot 45 W Operating and storage temperature T j, T stg -55... +5 C Page -8-
SPW47N6C Thermal Characteristics Parameter Symbol Values Unit min. typ. max. Characteristics Thermal resistance, junction - case R thjc - -.3 K/W Thermal resistance, junction - ambient, leaded R thj - - 6 Linear derating factor - - 3.33 W/K Soldering temperature,.6 mm (.63 in.) from case for s T sold - - 6 C Electrical Characteristics, at T j = 5 C, unless otherwise specified Static Characteristics Drain-source breakdown voltage V (BR)DSS 6 - - V V GS =V, I D =.5m Drain-source avalanche breakdown voltage V (BR)DS - 7 - V GS =V, I D = Gate threshold voltage, V GS = V DS V GS(th) 3.5 4.5 5.5 I D =.7m Zero gate voltage drain current V DS = 6 V, V GS = V, T j = 5 C V DS = 6 V, V GS = V, T j = 5 C I DSS µ - -.5-5 5 Gate-source leakage current I GSS - - n V GS =V, V DS =V Drain-source on-state resistance R DS(on) -.6.7 Ω V GS =V, I D =3, T j =5 C Gate input resistance R G -.6 - f = MHz, open drain Repetitve avalanche causes additional power losses that can be calculated as PV =E R *f. Page -8-
SPW47N6C Electrical Characteristics, at T j = 5 C, unless otherwise specified Parameter Symbol Conditions Values Unit min. typ. max. Characteristics Transconductance g fs V DS *I D *R DS(on)max, - 3 - S I D =3 Input capacitance C iss V GS =V, V DS =5V, - 88 - pf Output capacitance C oss f=mhz - 35 - Reverse transfer capacitance C rss - 36 - Effective output capacitance, ) C o(er) V GS =V, - 33 - pf energy related V DS =V to 48V Effective output capacitance, ) C o(tr) - 47 - time related Turn-on delay time t d(on) V DD =38V, V GS =/3V, - 8 - ns Rise time t r I D =47, R G =.8Ω, - 9.5 - Turn-off delay time t d(off) T j =5 C - 3 55 Fall time t f - 9.6 4.4 Gate Charge Characteristics Gate to source charge Q gs V DD =35V, I D =47-56 - nc Gate to drain charge Q gd - 3 - Gate charge total Q g V DD =35V, I D =47, - 86 V GS = to V Gate plateau voltage V (plateau) V DD =35V, I D =47-8 - V Co(er) is a fixed capacitance that gives the same stored energy as C oss while V DS is rising from to 8% V DSS. Co(tr) is a fixed capacitance that gives the same charging time as C oss while V DS is rising from to 8% V DSS. Page 3-8-
SPW47N6C Electrical Characteristics, at T j = 5 C, unless otherwise specified Parameter Symbol Conditions Values Unit min. typ. max. Characteristics Inverse diode continuous I S T C =5 C - - 47 forward current Inverse diode direct current, I SM - - 94 pulsed Inverse diode forward voltage V SD V GS =V, I F =I S -. V Reverse recovery time t rr V R =35V, I F =I S, - 65 ns Reverse recovery charge Q rr di F /dt=/µs - 4 - µc Peak reverse recovery current I rrm - 6 - Peak rate of fall of reverse di rr /dt - 5 - /µs recovery current Typical Transient Thermal Characteristics Symbol Value Unit Symbol Value Unit typ. typ. Thermal resistance Thermal capacitance R th.694 K/W C th.9 Ws/K R th.636 C th.4 R th3.79 C th3.6484 R th4.3 C th4.88 R th5.35 C th5.5 R th6.8 C th6.36 P tot (t) T j R th R th,n T case External Heatsink C th C th C th,n T amb Page 4-8-
SPW47N6C Power dissipation P tot = f (T C ) 5 SPW47N6C W Safe operating area I D = f ( V DS ) parameter : D =, T C =5 C 4 35 Ptot 3 ID 5 5 - tp =. ms tp =. ms tp =. ms tp = ms DC 5 4 6 8 C 6 T C - V 3 V DS 3 Transient thermal impedance Z thjc = f (t p ) parameter: D = t p /T K/W 4 Typ. output characteristic I D = f (V DS ); T j =5 C parameter: t p = µs, V GS 8 V 5V V V 6 ZthJC - ID 4 V - -3 D =.5 D =. D =. D =.5 D =. D =. single pulse 8 6 4 9V 8V 7V -4-7 -6-5 -4-3 - s t p Page 5 5 5 V 5 V DS -8-
SPW47N6C 75 Drain-source Typ. output characteristic on-state resistance RI D DS(on) = f (V DS = f ); (TT j ) j =5 C parameter: : ti p D = = 3 µs,, V GS = V ID RDS(on).38 SPW47N6C Ω.3 9.8 8.4 7. 6 5.6 4. 3.8.4 V V 98% typ V 8.5V 7.5V 6.5V -6-5 6 5 V C 8 5 VT DS j 9 Gate threshold voltage V GS(th) = f (T j ) parameter: V GS = V DS, I D =.7 m V 7 9V 8V 7V 6V 68 Typ. drain-source transfer characteristics on resistance RI D DS(on) = f ( V=f(I GS D );) V DS x I D x R DS(on)max parameter: tt p j =5 C, = µs V GS RDS(on) ID.5 Ω 8.4 6.35 4.3.5 8 6. 4.5. 4 64 8 6 84 V 8 IV DGS Typ. gate charge V GS = f (Q Gate ) parameter: I D = 47 pulsed 6 SPW47N6C V 9V 6V 6.5V 7V 7.5V 8V 8.5V V V V VGS(th) 5 4 max. VGS, V DS max,8 V DS max 3 typ. min. 8 6 4-6 - 6 C 8 T j Page 6 4 8 6 4 8 nc 36 Q Gate -8-
SPW47N6C Forward characteristics of body diode I F = f (V SD ) parameter: T j, tp = µs Typ. switching time t = f (R G ), inductive load, T j =5 C par.: V DS =38V, V GS =/+3V, I D =47 SPW47N6C 3 ns t d(off) t d(on) IF t t r t f T j = 5 C typ T j = 5 C typ T j = 5 C (98%) T j = 5 C (98%) -.4.8..6.4 V 3 V SD 3 Typ. switching losses ) E = f (I D ), inductive load, T j =5 C par.: V DS =38V, V GS =/+3V, R G =.8Ω mws 5 4 3.5 *) E on includes SDP6S6 diode commutation losses. This chart helps to estimate the switching power losses. The values can be different under other operating conditions. 4 6 8 4 6 Ω R G 4 Typ. switching losses ) E = f(r G ), inductive load, T j =5 C par.: V DS =38V, V GS =/+3V, I D =47 mws 3 *) E on includes SDP6S6 diode commutation losses. This chart helps to estimate the switching power losses. The values can be different under other operating conditions. E 3 E.5.5 E on * E off.5 E on* E off.5.5 3 4 5 6 7 8 I D Page 7 4 6 8 4 6 Ω R G -8-
SPW47N6C 5 valanche SO I R = f (t R ) par.: T j 5 C 6 valanche energy E S = f (T j ) par.: I D =, V DD = 5 V mj 6 IR ES 4 T j (STRT)=5 C 8 5 T j (STRT)=5 C 6 4-3 - - µs 4 t R 7 Drain-source breakdown voltage V (BR)DSS = f (T j ) 7 SPW47N6C 4 6 8 C 6 T j 8 valanche power losses P R = f (f ) parameter: E R =mj 5 V W V(BR)DSS 68 66 64 PR 3 6 6 58 56 54-6 - 6 C 8 T j 4 5 Hz 6 f Page 8-8-
SPW47N6C 9 Typ. capacitances C = f (V DS ) parameter: V GS =V, f= MHz 5 pf 4 C iss Typ. C oss stored energy E oss =f(v DS ) 4 µj 3 C 3 Eoss 5 C oss C rss 5 5 3 4 V 6 V DS 3 4 V 6 V DS Definition of diodes switching characteristics Page 9-8-
SPW47N6C P-TO-47-3- 5.9 6.35 ø3.6.3 5.3 9.9 6.7 4.37.9 5.94 D 7 5.97 x.7 4..75 D.4 6.43..76 MX..4 +.5.9 5.46 General tolerance unless otherwise specified: Leadframe parts: ±.5 Package parts: ±. Page -8-
SPW47N6C Published by Infineon Technologies G, Bereichs Kommunikation St.-Martin-Strasse 53, D-854 München Infineon Technologies G 999 ll Rights Reserved. ttention please! The information herein is given to describe certain components and shall not be considered as warranted characteristics. Terms of delivery and rights to technical change reserved. We hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding circuits, descriptions and charts stated herein. Infineon Technologies is an approved CECC manufacturer. Information For further information on technology, delivery terms and conditions and prices please contact your nearest Infineon Technologies Office in Germany or our Infineon Technologies Reprensatives worldwide (see address list). Warnings Due to technical requirements components may contain dangerous substances. For information on the types in question please contact your nearest Infineon Technologies Office. Infineon Technologies Components may only be used in life-support devices or systems with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system, or to affect the safety or effectiveness of that device or system Life support devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered. Page -8-