Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272 Intellimod™ Module
Dual-In-Line Intelligent
Power Module
25 Amperes/1200 Volts
PS22A76
1Rev. 08/09
Description:
DIPIPMs are intelligent power
modules that integrate power
devices, drivers, and protection
circuitry. Design time is reduced
by the use of application-specific
HVICs and value-added features
such as linear temperature feed-
back. Overall efficiency and
reliability are increased by the
use of full gate CSTBT technology
and low thermal impedance.
Features:
Low-loss, Full Gate
CSTBT IGBTs
Single Power Supply
Integrated HVICs
Direct Connection to CPU
Applications:
Variable Speed Pumps
Variable Speed Compressors
Small Motor Control
Ordering Information:
PS22A76 is a 1200V, 25 Ampere
DIP Intelligent Power Module.
Dimensions Inches Millimeters
A 3.11±0.02 79.0±0.5
B 1.22±0.02 31.0±0.5
C 0.63 16.0
D 2.76±0.01 70.0±0.3
E 0.5 12.7
F 0.39±0.01 10.0±0.3
G 0.1±0.01 2.54±0.3
H 0.2±0.01 5.08±0.3
J 1.0 25.4
K 0.11 2.8
L 0.12 Dia. 2.9 Dia.
M 0.18±0.01 Dia. 4.5±0.2 Dia.
N 1.42±0.02 36.2±0.5
P 0.03 0.7
Dimensions Inches Millimeters
Q 0.08 2.0
R 0.66 16.73
S 0.44 11.13
T 015.±0.04 3.8±1.0
U 0.082 2.1
V 0.086 2.2
W 0.31 8.0
X 0.07 1.8
Y 0.34 8.6
Z 0.03 0.8
AA 0.10 2.7
AB 0.48 12.33
AC 0.39 10.12
AD 0.068 1.75
Outline Drawing and Circuit Diagram
C
W
Q
AB
Z
X
Y
B
E
F
A
D
F F F F F
K
G
GG GGG GG
HH H H J
N
R
S
T
W
AB
AC
U
V
Q
AD
HH
L (5 PLACES)
DEPTH 1.6
M (2 PLACES)
1 2 3 4 5 6 7 8 9 10 11 12
41 42
13 14 15 16 17 18 19 29
30
31
32
33
3440
6 VUFS
5 (UPG)
3 VP1
2 (VPC)
26 FO19 VSC
24 CIN
23 VOT
22 VNC
21 VN1
25 CFO
20 UNG
28 VN
27 UN
33 W
31 WNG
30 VNC
29 WN
32 VNG
35 NV
34 NW
40 P
38 V
37 W
36 NU
39 U
41 U
42 V
7 VP
9 VP1
11 V PG
10 VVFB
12 VVFS
1 UP
4 VUFB
8 VPC
16 VWFB
15 VPC
17 WPG
18 VWFS
13 WP
14 VP1
TERMINAL CODE
PS22A76
Intellimod™ Module
Dual-In-Line Intelligent Power Module
25 Amperes/1200 Volts
Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272
2 Rev. 08/09
Absolute Maximum Ratings, Tj = 25°C unless otherwise specied
Characteristics Symbol PS22A76 Units
Self-protection Supply Voltage Limit (Short Circuit Protection Capability)* VCC(prot.) 800 Volts
Module Case Operation Temperature (See TC Measurement Point Below) TC -20 to 100 °C
Storage Temperature Tstg -40 to 125 °C
Mounting Torque, M4 Mounting Screws — 13 in-lb
Module Weight (Typical) — 65 Grams
Isolation Voltage, AC 1 minute, 60Hz Sinusoidal, Connection Pins to Heatsink Plate VISO 2500 Volts
IGBT Inverter Sector
Supply Voltage (Applied between P-NU, NV, NW) VCC 900 Volts
Supply Voltage, Surge (Applied between P-NU, NV, NW) VCC(surge) 1000 Volts
Collector-Emitter Voltage (TC = 25°C) VCES 1200 Volts
Collector Current (TC = 25°C) ±IC 25 Amperes
Peak Collector Current (TC = 25°C, <1ms) ±ICP 50 Amperes
Collector Dissipation (TC = 25°C, per 1 Chip) PC 113.6 Watts
Power Device Junction Temperature** Tj -20 to 150 °C
Control Sector
Supply Voltage (Applied between VP1-VPC, VN1-VNC) VD 20 Volts
Supply Voltage (Applied between VUFB-VUFS, VVFB-VVFS, VWFB-VWFS) VDB 20 Volts
Input Voltage (Applied between UP
, VP
, WP-VPC, UN, VN, WN-VNC) VIN -0.5 ~ VD+0.5 Volts
Fault Output Supply Voltage (Applied between FO-VNC) VFO -0.5 ~ VD+0.5 Volts
Fault Output Current (Sink Current at FO Terminal) IFO 1 mA
Current Sensing Input Voltage (Applied between CIN-VNC) VSC -0.5 ~ VD+0.5 Volts
*VD = 13.5 ~ 16.5V, Inverter Part, Tj = 125°C, Non-repetitive, Less than 2µs
**The maximum junction temperature rating of the power chips integrated within the DIPIPM is 150°C (@Tf ≤ 100°C). However, to ensure safe operation of the DIPIPM,
the average junction temperature should be limited to Tj(avg) ≤ 125°C (@Tf ≤ 100°C).
TC Measurement Point
IGBT CHIP
BUILT-IN HEATSINK
1.2
40.5
TC POINT
PS22A76
Intellimod™ Module
Dual-In-Line Intelligent Power Module
25 Amperes/1200 Volts
Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272
3Rev. 08/09
Electrical and Mechanical Characteristics, Tj = 25°C unless otherwise specied
Characteristics Symbol Test Conditions Min. Typ. Max. Units
IGBT Inverter Sector
Collector-Emitter Saturation Voltage VCE(sat) I
C = 25A, Tj = 25°C, VD = VDB = 15V, VIN = 5V — 1.9 2.6 Volts
I
C = 25A, Tj = 125°C, VD = VDB = 15V, VIN = 5V — 2.0 2.7 Volts
Diode Forward Voltage VEC T
j = 25°C, -IC = 25A, VIN = 0V — 2.5 3.0 Volts
Inductive Load Switching Times ton 0.8 1.5 2.2 µs
t
rr V
CC = 600V, VD = VDB = 15V, — 0.3 — µs
t
C(on) I
C = 25A, Tj = 125°C, VIN = 0 ⇔ 5V, — 0.6 0.9 µs
t
off Inductive Load (Upper-Lower Arm) — 2.8 3.8 µs
t
C(off) — 0.7 1.0 µs
Collector-Emitter Cutoff Current ICES V
CE = VCES, Tj = 25°C — — 1.0 mA
V
CE = VCES, Tj = 125°C — — 10 mA
Control Sector
Circuit Current ID VD = VDB = 15V, VIN = 5V, — — 3.70 mA
Total of VP1-VPC, VN1-VNC
V
D = VDB = 15V, VIN = 5V, — — 1.30 mA
V
UFB-VUFS, VVFB-VVFS, VWFB-VWFS
VD = VDB = 15V, VIN = 0V, — — 3.50 mA
Total of VP1-VPC, VN1-VNC
V
D = VDB = 15V, VIN = 0V, — — 1.30 mA
V
UFB-VUFS, VVFB-VVFS, VWFB-VWFS
Fault Output Voltage VFOH VSC = 0V, FO Terminal Pull-up to 5V by 10kΩ 4.9 — — Volts
V
FOL V
SC = 1V, IFO = 1mA — — 1.1 Volts
Input Current IIN V
IN = 5V 0.7 1.5 2.0 mA
Short-Circuit Trip Level* ISC -20°C ≤ TC ≤ 100°C, VD = 15V 42.5 — — Amps
Supply Circuit Undervoltage UVDBt Trip Level, TC ≤ 100°C 10.0 — 12.0 Volts
Protection UVDBr Reset Level, TC ≤ 100°C 10.5 — 12.5 Volts
UVDt Trip Level, TC ≤ 100°C 10.3 — 12.5 Volts
UVDr Reset Level, TC ≤ 100°C 10.8 — 13.0 Volts
Fault Output Pulse Width** tFO C
FO = 22nF 1.6 2.4 — ms
ON Threshold Voltage Vth(on) Applied between UP
, VP
, WP-VPC, — — 3.5 Volts
OFF Threshold Voltage Vth(off) U
N, VN, WN-VNC 0.8 — — Volts
Temperature Output*** VOT At LVIC Temperature = 85°C 3.50 3.63 3.76 Volts
* Short-Circuit protection is functioning only at the lower arms. Please select the value of the external shunt resistor such that the SC trip level is less than 85A.
**Fault signal is asserted when the lower arm short circuit or control supply under-voltage protective functions operate. The fault output pulse-width tFO depends on the capacitance value
of CFO according to the following approximate equation: CFO = (12.2 x 10-6 x tFO [F]).
***When the temperature rises excessively, the controller (MCU) should stop the DIPIPM.
PS22A76
Intellimod™ Module
Dual-In-Line Intelligent Power Module
25 Amperes/1200 Volts
Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272
4 Rev. 08/09
Thermal Characteristics, Tj = 25°C unless otherwise specied
Characteristic Symbol Condition Min. Typ. Max. Units
Thermal Resistance Junction to Case Rth(j-C)Q IGBT Part (Per 1/6 Module) — — 0.88 °C/Watt
Thermal Resistance Junction to Case Rth(j-C)D FWDi Part (Per 1/6 Module) — — 1.25 °C/Watt
Recommended Conditions for Use
Characteristic Symbol Condition Min. Typ. Max. Units
Supply Voltage VCC Applied between P-NU, NV, NW 350 600 800 Volts
Control Supply Voltage VD Applied between VP1-VPC, VN1-VNC 13.5 15.0 16.5 Volts
V
DB Applied between VUFB-VUFS, 13.0 15.0 18.5 Volts
V
VFB-VVFS, VWFB-VWFS
Control Supply Variation ΔVD, ΔVDB -1 — 1 V/µs
Arm Shoot-through tDEAD For Each Input Signal, TC ≤ 100°C 3.3 — — µs
Blocking Time
PWM Input Frequency fPWM T
C ≤ 100°C, Tj ≤ 125°C — — 15 kHz
Allowable rms Current* IO V
CC = 600V, VD = 15V, — — 5.5 Arms
f
C = 15kHz, PF = 0.8, Sinusoidal PWM,
T
j ≤ 125°C, TC ≤ 100°C
Minimum Input PWIN(on)** — — — µs
Pulse Width PWIN(off)***
IC ≤ 25A 350 ≤ VCC ≤ 800V, 13.5 ≤ VD ≤ 16.5V, — — — µs
25 ≤ IC ≤ 42.5A 13.5 ≤ VDB ≤ 16.5V, -20°C ≤ TC ≤ 100°C, — — — µs
N-line Wiring Inductance Less Than 10nH
VNC Variation VNC Between VNC-NU, NV, NW (Including Surge) -5.0 — 5.0 Volts
* The allowable rms current value depends on the actual application conditions.
**If input signal ON pulse is less than PWIN(on), the device may not respond.
***The IPM may fail to respond to an ON pulse if the preceeding OFF pulse is less than PWIN(off).
Delayed Response Against Shorter Input OFF Signal Than PWIN(off), P-side only
t2 t1
P-SIDE
CONTROL INPUT
INTERNAL
IGBT GATE
OUTPUT
CURRENT IC
Solid Line – OFF Pulse Width > PWIN(off): Turn ON time t1.
Dotted Line – OFF Pulse Width < PWIN(off): Turn ON time t2.
PS22A76
Intellimod™ Module
Dual-In-Line Intelligent Power Module
25 Amperes/1200 Volts
Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272
5Rev. 08/09
Application Circuit
Component Selection:
Dsgn. Typ. Value Description
D1 1A, 600V Control and boot strap supply overvoltage suppression
DZ1 24V, 1W Control and boot strap supply over voltage suppression
C1 10-100µF, 50V Boot strap supply reservoir – electrolytic long lifem low impedance, 105°C
C2 0.22-2.0µF, 50V Local decoupling/High frequency noise filters – multilayer ceramic (Note 4)
C3 200 to 2500µF, 450V Main DC bus filter capacitor – electrolytic, long life, high ripple current, 105°C
C4 100pF, 50V Optional input signal noise filter – multilayer ceramic (Note 11)
C5 0.1-0.22µF, 1000V Surge voltage suppression (Note 2)
CSF 1000pF, 50V Short circuit detection filter capacitor – multilayer ceramic
RSF 1.8kΩ Short circuit detection filter resistor
RSHUNT 20ohm-500ohm Current sensing resistor
R1 1-10Ω Boot strap supply inrush limiting resistor – non-inductive, temperature stable, tight tolerance (Note 5)
R2 330Ω Optional input signal noise filter (Note 11)
R3 10kΩ Fault signal pull-up resistor (Note 9)
Notes:
1) If control GND is connected to power GND by broad pattern, it may cause malfunction by power GND fluctuation.
It is recommended to connect control GND at only a point at which NU, NV, NW are connected to power GND line.
2) To prevent surge destruction, the wiring between the smoothing capacitor and the P-N1 terminals should be as short as
possible. Generally inserting a 0.1µ ~ 0.22µF snubber capacitor C3 between the P-N1 terminals is recommended.
3) The time constant R1,C4 of RC filter for preventing the protection circuit malfunction should be selected in the range of 1.5µ ~ 2µs.
SC interrupting time might vary with the wiring pattern. Tight tolerance, temp-compensated type is recommended for R1,C4.
4) All capacitors should be mounted as close to the terminals of the DIPIPM as possible. (C1: good temperature, frequency
characteristics electrolytic type, and C2 : good temperature, frequency and DC bias characteristic ceramic type are recommended.)
5) It is recommended to insert a Zener diode DZ1 (24V/1W) between each pair of control supply terminals to prevent surge destruction.
6) To prevent erroneous SC protection, the wiring from VSC terminals to CIN filter should be divided at the point D that is close
to the terminal of sense resistor and the wiring should be patterned as short as possible.
7) For sense resistor, the variation within 1% (including temperature characteristics), low inductance type is recommended.
1/8W is recommended, but an evaluation of your system is recommended.
8) To prevent erroneous operation, wiring A, B, and C should be as short as possible.
9) FO output is open drain type. It should be pulled up to the positive side of 5V or 15V power supply with a resistor that limits
F
O sink current (IFO) under 1mA. (Over 5.1kΩ is needed and 10kΩ is recommended for 5V supply.)
10) Error signal output width (tFO) can be set by the capacitor connected to the CFO terminal. tFO(typ) = CFO / 9.1 x 10-6 (s).
11) Input drive is high-active type. There is a 3.3kΩ pull-down resistor integrated in the IC input circuit. To prevent malfunction, the wiring of each input
should be patterned as short as possible. When inserting the RC filter, make sure the input signal level meets the turn-on and turn-off threshold voltage.
Thanks to HVIC inside the module, connection to the MCU may be direct or with an opto-coupler.
VN1
UN
FO
VOT
VNC
VNO
VSC
D
B
C
A
RSHUNT
CIN
CSF
RSF
VN
WN
CFO
HVIC1
IGBT1
FWDi1
IGBT2
FWDi2
IGBT3
IGBT4
IGBT5
IGBT6
FWDi3
FWDi4
FWDi5
FWDi6
LVIC
P
U
HVIC2
V
VWFB
VP1
VWFS
WP
VPC HVIC3
W
NU
NV
NW
C2
DZ1
C1
VD15V
+
+
C2
C4
C4
C4
R3
R2
R2
R2
C2
DZ1
C1
D1
+
VVFB
VP1
VVFS
VP
C2
C2
DZ1
C1
D1
MCU
+
VUFB
VP1
VUFS
UP
C2
C2
C3
C3
C5
DZ1
C1
D1
+
M
PS22A76
Intellimod™ Module
Dual-In-Line Intelligent Power Module
25 Amperes/1200 Volts
Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272
6 Rev. 08/09
Protection Function Timing Diagrams
a1 SC
SC REFERENCE VOLTAGE
RC CIRCUIT TIME CONSTANT DELAY
a2
a3
a4 a8
a5
a7a6
SET RESET
N-SIDE
CONTROL INPUT
PROTECTION
CIRCUIT STATE
INTERNAL IGBT GATE
SENSE VOLTAGE OF RS
OUTPUT CURRENT IC
FAULT OUTPUT FO
Short Circuit Protection (N-side Only with External Shunt Resistor and RC Filter)
a1: Normal operation – IGBT turns on and carries current.
a2: Short circuit current is detected (SC trigger).
a3: All N-side IGBT's gate are hard interrupted.
a4: All N-side IGBT's turn off.
a5: FO output wirh a fixed pulse width (determined by the external capacitance CFO).
a6: Input "L" – IGBT off.
a7: Input "H" – IGBT on, but during the FO output perid the IGBT will not turn on.
a8: IGBT turns on when L→H signal is input after FO is reset.
b1
b4
b5
b2
UVDt
b7
b3
SET RESETRESET
UVDr
b6
CONTROL INPUT
PROTECTION
CIRCUIT STATE
CONTROL SUPPLY
VOLTAGE VD
OUTPUT CURRENT IC
FAULT OUTPUT FO
Under-Voltage Protection (N-side , UVD)
b1: Control supply voltage VD rises – After VD level reaches under voltage reset level (UVDr), the circuits
start to operate when next input is applied.
b2 : Normal operation – IGBT turns on and carries current.
b3: VD level dips to under voltage trip level (UVDt).
b4: All N-side IGBT’s turn off in spite of control input condition.
b5: FO is low for a minimum period determined by the capacitance CFO but continuously during UV period.
b6: VD level reaches UVDr.
b7: Normal operation – IGBT turns on and carries current.
PS22A76
Intellimod™ Module
Dual-In-Line Intelligent Power Module
25 Amperes/1200 Volts
Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272
7Rev. 08/09
Protection Function Timing Diagrams
Typical Interface Circuit
Wiring Method Around Shunt Resistor
c1 c5
c6
c3
c2
UVDt
c4
SET RESETRESET
HIGH LEVEL (NO FAULT OUTPUT)
UVDBr
CONTROL INPUT
PROTECTION
CIRCUIT STATE
CONTROL SUPPLY
VOLTAGE VDB
OUTPUT CURRENT IC
FAULT OUTPUT FO
Under-Voltage Protection (P-side, UVDB)
c1: Control supply voltage VDB rises – After VDB level reaches under voltage reset level (UVDBr),
the circuits starts to operate when next input is applied.
c2: Normal operation – IGBT turns on and carries current.
c3: VDB level dips to under voltage trip level (UVDBt).
c4: P-side IGBT turns off in spite of control input signal level, but there is no FO signal output.
c5: VDB level reaches UVDBr.
c6: Normal operation – IGBT on and carries current.
UP, VP, WP, UN, VN, WN
MCU
5V LINE
10kΩ
2.5kΩ (MIN)
FO
VNC (LOGIC)
DIP-IPM
NOTE: RC coupling at each input
(parts shown dotted) may change
depending on the PWM control
scheme used in the application and
the wiring impedance of the printed
circuit board. The DIPIPM input signal
section integrates a 2.5kΩ (min)
pull-down resistor. Therefore, when
using an external filtering resistor, care
must be taken to satisfy the turn-on
threshold voltage requirement.
VNC NW
NV
NU
DIPIPM
It is recommended to make the inductance under 10nH.
For shunt resistors, it is recommended to use as low
inductance type as possible.
Shunt
Resistors
Connect the wiring from VNC terminal at the point as
close to shunt resistors’ terminal as possible.
It is recommended to divide the wiring to current detecting
circuit at the point as close to shunt resistor’s terminal as
possible.
To Current
Detecting Circuit
PS22A76
Intellimod™ Module
Dual-In-Line Intelligent Power Module
25 Amperes/1200 Volts
Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272
8 Rev. 08/09
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
COLLECTOR RECOVERY CURRENT, -IC, (AMPERES)
REVERSE RECOVERY CURRENT, Irr, (AMPERES)
REVERSE RECOVERY TIME, trr, (s)
COLLECTOR RECOVERY CURRENT, -IC, (AMPERES)
REVERSE RECOVERY CHARACTERISTICS
(TYPICAL - N-SIDE)
COLLECTOR RECOVERY CURRENT, -IC, (AMPERES)
EMITTER-COLLECTOR VOLTAGE, VEC, (VOLTS)
FREE-WHEEL DIODE
FORWARD CHARACTERISTICS
(TYPICAL)
VIN = 5V
Tj = 25°C
Tj = 125°C
COLLECTOR-CURRENT, IC, (AMPERES)
COLLECTOR-EMITTER
SATURATION VOLTAGE, VCE(sat), (VOLTS)
COLLECTOR-EMITTER
SATURATION VOLTAGE CHARACTERISTICS
(TYPICAL)
0 40 60
VD = VDB = 15V
VIN = 5V
Tj = 25°C
Tj = 125°C
20
3.5
3.0
2.0
2.5
1.5
1.0
0.5
00 40 6020
3.0
2.0
2.5
1.5
1.0
0.5
0
REVERSE RECOVERY CHARACTERISTICS
(TYPICAL - N-SIDE)
100101102
10-1
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING TIME, toff, (µs)
SWITCHING TIME (OFF) VS.
COLLECTOR CURRENT
(TYPICAL - N-SIDE)
100
101
100101102
100
101
102
100101102
10-1
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING TIME, ton, (µs)
SWITCHING TIME (ON) VS.
COLLECTOR CURRENT
(TYPICAL - N-SIDE)
100
101
100101102
10-2
10-1
100
100101102
10-2
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING TIME, tc(on), (µs)
SWITCHING TIME (ON) VS.
COLLECTOR CURRENT
(TYPICAL - N-SIDE)
10-1
100
101
10-2
10-1
100
101
10-1
100
101
102
100101102
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING TIME, tc(off), (µs)
SWITCHING TIME (OFF) VS.
COLLECTOR CURRENT
(TYPICAL - N-SIDE)
100101102
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING LOSS, PSW(on), (mJ/PULSE)
SWITCHING LOSS (ON) VS.
COLLECTOR CURRENT
(TYPICAL - N-SIDE)
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
PS22A76
Intellimod™ Module
Dual-In-Line Intelligent Power Module
25 Amperes/1200 Volts
Powerex, Inc., 173 Pavilion Lane, Youngwood, Pennsylvania 15697 (724) 925-7272
9Rev. 08/09
100101102
10-1
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING LOSS, PSW(off), (mJ/PULSE)
SWITCHING TIME (OFF) VS.
COLLECTOR CURRENT
(TYPICAL - N-SIDE)
100
101
102
10-2
10-1
100
101
10-2
10-1
100
101
10-1
100
101
102
10-1
100
101
102
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
100101102
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING LOSS, PSW(off), (mJ/PULSE)
SWITCHING TIME (OFF) VS.
COLLECTOR CURRENT
(TYPICAL - P-SIDE)
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
100101102
10-1
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING TIME, toff, (µs)
SWITCHING TIME (OFF) VS.
COLLECTOR CURRENT
(TYPICAL - P-SIDE)
100
101
100101102
100
101
102
100101102
10-1
100
101
100101102
10-1
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING TIME, ton, (µs)
SWITCHING TIME (ON) VS.
COLLECTOR CURRENT
(TYPICAL - P-SIDE)
100
101
100101102
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING TIME, tc(on), (µs)
SWITCHING TIME (ON) VS.
COLLECTOR CURRENT
(TYPICAL - P-SIDE)
100101102
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING TIME, tc(off), (µs)
SWITCHING TIME (OFF) VS.
COLLECTOR CURRENT
(TYPICAL - P-SIDE)
100101102
COLLECTOR CURRENT, IC, (AMPERES)
SWITCHING LOSS, PSW(on), (mJ/PULSE)
SWITCHING LOSS (ON) VS.
COLLECTOR CURRENT
(TYPICAL - P-SIDE)
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
COLLECTOR RECOVERY CURRENT, -IC, (AMPERES)
REVERSE RECOVERY CURRENT, Irr, (AMPERES)
REVERSE RECOVERY TIME, trr, (s)
COLLECTOR RECOVERY CURRENT, -IC, (AMPERES)
REVERSE RECOVERY CHARACTERISTICS
(TYPICAL - P-SIDE)
REVERSE RECOVERY CHARACTERISTICS
(TYPICAL - P-SIDE)
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
VCC = 600V
VD = VDB = 15V
VIN = 0V ↔ 5V
L = 1mH
Tj = 25°C
Tj = 125°C
