http://www.fujielectric.com/products/semiconductor/
FMH20N60S1
Super J-MOS series
Features
Low on-state resistance Low switching loss easy to use (more controllabe switching dV/dt by Rg)
FUJI POWER MOSFET
N-Channel enhancement mode power MOSFET
Outline Drawings [mm]
TO-3P(Q)
5±0.1 15.5max 13 ± 0.2 10 ± 0.2 φ3.2± 0.1
1.5±0.2 4.5±0.2
Equivalent circuit schematic
UPS Server Telecom Power conditioner system Power supply
3 ±0.2
Applications
1.6
+0.3 -0.1 +0.3 -0.1
1.6
+0.3 -0.1
2.2
14.5 ±0.2
19.5 ±0.2
1.5
Drain(D)
PRE-SOLDER
1.1 5.45 ± 0.2
+0.2 -0.1
0.5
+0.2 0
Gate(G) Source(S)
5.45 ± 0.2
1.5
CONNECTION 1 GATE 2 DRAIN 3 SOURCE
DIMENSIONS ARE IN MILLIMETERS.
Maximum Ratings and Characteristics
Absolute Maximum Ratings at TC =25°C (unless otherwise specified)
Description Drain-Source Voltage Continuous Drain Current Pulsed Drain Current Gate-Source Voltage Repetitive and Non-Repetitive Maximum Avalanche Current Non-Repetitive Maximum Avalanche Energy Maximum Drain-Source dV/dt Peak Diode Recovery dV/dt Peak Diode Recovery -di/dt Maximum Power Dissipation Operating and Storage Temperature range
Note *1 : Limited by maximum channel temperature. Note *2 : Tch ≤150°C, See Fig.1 and Fig.2 Note *3 : Starting Tch =25°C, IAS=2A, L=216mH, VDD =60V, RG =50Ω, See Fig.1 and Fig.2 E AS limited by maximum channel temperature and avalanche current. Note *4 : I F ≤-I D, -di/dt=100A/μs, VDD ≤400V, Tch ≤150°C. Note *5 : I F ≤-I D, dV/dt=15kV/μs, VDD ≤400V, Tch ≤150°C.
Symbol VDS VDSX ID IDP VGS IAR EAS dVDS /dt dV/dt -di/dt PD Tch Tstg
Characteristics 600 600 ±20 ±12.6 ±60 ±30 6.6 472.2 50 15 100 2.5 140 150 -55 to +150
Unit V V A A A V A mJ kV/μs kV/μs A/μs W °C °C
Remarks VGS=-30V TC=25°C TC=100°C
Note*1 Note*1
Note *2 Note *3 VDS ≤ 600V Note *4 Note *5 Ta=25°C TC=25°C
1
FMH20N60S1
Electrical Characteristics at TC =25°C (unless otherwise specified) Static Ratings
Description Drain-Source Breakdown Voltage Gate Threshold Voltage Symbol BVDSS VGS(th) Conditions ID =250μA VGS=0V ID =250μA VDS=VGS VDS=600V VGS=0V VDS=480V VGS=0V VGS= ± 30V VDS=0V ID =10A VGS=10V f=1MHz, open drain ID =10A VDS=25V VDS=10V VGS=0V f=1MHz VGS=0V VDS=0…480V VGS=0V VDS=0…480V ID=constant VDD =400V, VGS=10V ID =10A, RG =27Ω See Fig.3 and Fig.4 VDD =480V, ID =20A VGS=10V See Fig.5 L=6.02mH, Tch =25°C See Fig.1 and Fig.2 IF=20A,VGS=0V Tch =25°C IF=20A, VGS=0V VDD =400V -di/dt=100A/μs Tch =25°C See Fig.6 Tch =25°C Tch =125°C
FUJI POWER MOSFET http://www.fujielectric.com/products/semiconductor/
min. 600 2.5 8.5 6.6 -
typ. 3 10 0.161 3.7 17.5 1470 3120 280 90 305 22 40 162 22 48 12.5 15 8 0.9 370
max. 3.5 25
Unit V V
Zero Gate Voltage Drain Current
IDSS
μA 250 100 0.19 1.35 pF nA Ω Ω S
Gate-Source Leakage Current Drain-Source On-State Resistance Gate resistance Forward Transconductance Input Capacitance Output Capacitance Reverse Transfer Capacitance Effective output capacitance, energy related (Note *6) Effective output capacitance, time related (Note *7) Turn-On Time Turn-Off Time Total Gate Charge Gate-Source Charge Gate-Drain Charge Drain-Source crossover Charge Avalanche Capability Diode Forward On-Voltage Reverse Recovery Time Reverse Recovery Charge Peak Reverse Recovery Current
IGSS RDS(on) RG gfs Ciss Coss Crss Co(er) Co(tr) td(on) tr td(off) tf QG QGS QGD QSW IAV VSD trr Qrr Irp
ns
nC
A V ns μC A
-
6.2 32
Note *6 : C o(er) is a fixed capacitance that gives the same stored energy as C oss while VDS is rising from 0 to 80% BVDSS . Note *7 : C o(tr) is a fixed capacitance that gives the same charging times as C oss while VDS is rising from 0 to 80% BVDSS .
Thermal Characteristics
Description Channel to Case Channel to Ambient Symbol Rth(ch-c) Rth(ch-a) min. typ. max. 0.89 50 Unit °C/W °C/W
2
FMH20N60S1
Allowable Power Dissipation PD=f(Tc)
140 120 100
FUJI POWER MOSFET http://www.fujielectric.com/products/semiconductor/
10
2
Safe Operating Area ID=f(VDS):Duty=0(Single pulse), Tc=25°C
t= 1µs
10
1
10µs 100µs
PD [W]
80 60 40 20 0 0 25 50 75 TC [°C] 100 125 150
ID [A]
10
0
10
-1
Power loss waveform : Square waveform PD
t
1ms
10
-2
10
-1
10
0
10
1
10
2
10
3
VDS [V]
Typical Output Characteristics ID=f(VDS): 80µs pulse test, Tch=25°C
60 55 50 45 40 35 ID [A] 30 25 20 15 10 5 0 0 5 10 VDS [V] 15 20 25 40
Typical Output Characteristics ID=f(VDS): 80µs pulse test, Tch=150°C
10V
20V 8V 6.5V
35 30
8V
10V
20V
6V
25 ID [A]
6V
5.5V
20 15 10
5.5V
5V
5V
5
4.5V
VGS=4.5V
0 0 5 10 VDS [V] 15 20
VGS=4V
25
0.6
Typical Drain-Source on-state Resistance RDS(on)=f(ID): 80µs pulse test, Tch=25°C
4.5V 5V 5.5V 6V 6.5V 8V 10V 1.4 1.2 1.0 RDS (on) [ Ω ] VGS=20V 0.8 0.6 0.4
Typical Drain-Source on-state Resistance RDS(on)=f(ID): 80µs pulse test, Tch=150°C
4V 4.5V 5V
0.5
5.5V
0.4 RDS (on) [ Ω ]
6V
8V 10V VGS=20V
0.3
0.2
0.1
0.2 0.0 0 5 10 15 20 25 30 ID [A] 35 40 45 50 55 60 0 5 10 15 20 ID [A] 25 30 35 40
0.0
3
FMH20N60S1
Drain-Source On-state Resistance RDS(on)= f(Tch): ID=10A, VGS=10V
FUJI POWER MOSFET http://www.fujielectric.com/products/semiconductor/
0.6
6
Gate Threshold Voltage vs. Tch VGS(th)= f(Tch): VDS= VGS, ID= 250µA
0.5
5
0.4 RDS(on) [ Ω ]
4 VGS(th) [V]
max.
0.3
3 typ. 2
0.2 typ. 0.1
1
0.0 -50 -25 0 25 50 Tch [°C] 75 100 125 150
0 -50 -25 0 25 50 75 Tch [°C] 100 125 150
100
Typical Transfer Characteristic ID= f(VGS): 80µs pulse test, VDS= 25V
Typical Transconductance gfs= f(ID):80µs pulse test, VDS= 25V
100
10
Tch=25℃
10
1 ID[A]
150℃
gfs [S]
Tch=25℃
150℃
0.1
1
0.01
1E-3 0 1 2 3 4 5 VGS[V] 6 7 8 9 10
0.1 0.1 1 ID [A] 10 100
Typical Forward Characteristics of Reverse Diode IF=f(VSD): 80µs pulse test
10
5
Typical Capacitance C=f(VDS): VGS=0V, f=1MHz
100
10
4
10 C [pF]
3
Ciss
10 IF [A]
150℃
Tch=25℃
10
2
Coss
1
10
1
10
0
Crss
0.1 0.00 .51 .01 VSD [V] .52 .0
10
-1
10
-2
10
-1
10
0
10
1
10
2
VDS [V]
4
FMH20N60S1
Typical Coss stored energy
14
FUJI POWER MOSFET http://www.fujielectric.com/products/semiconductor/
10
3
Typical Switching Characteristics vs. ID Tch=25°C t=f(ID): Vdd=400V, VGS=10V/0V, RG=27Ω, L=500uH
12
10
Eoss [uJ]
8
tr t [ns] 10
2
td(off)
6
4
tf
2
td(on)
0 0 100 200 300 VDS [V] 400 500 600
10
1
10
0
10 ID [A]
1
10
2
10
Typical Gate Charge Characteristics VGS= f(Qg): ID=20A, Vdd=480V, Tch=25°C
500 450
Maximum Avalanche Energy vs. startingTch E(AV)= f(starting Tch): VCC=60V, I(AV)
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