Industrial IGBT Modules Explanation of Technical Information

Application Note AN 2011-05
V1.2 November 2015
AN2011-05 Industrial IGBT Modules
Explanation of Technical Information
IFAG IPC APS
Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
Edition 2011-09-30
Published by
Infineon Technologies AG
59568 Warstein, Germany
© Infineon Technologies AG 2011.
All Rights Reserved.
Attention please!
THE INFORMATION GIVEN IN THIS APPLICATION NOTE IS GIVEN AS A HINT FOR THE IMPLEMENTATION OF THE INFINEON TECHNOLOGIES COMPONENT ONLY AND SHALL NOT BE REGARDED
AS ANY DESCRIPTION OR WARRANTY OF A CERTAIN FUNCTIONALITY, CONDITION OR QUALITY
OF THE INFINEON TECHNOLOGIES COMPONENT. THE RECIPIENT OF THIS APPLICATION NOTE
MUST VERIFY ANY FUNCTION DESCRIBED HEREIN IN THE REAL APPLICATION. INFINEON
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(INCLUDING WITHOUT LIMITATION WARRANTIES OF NON-INFRINGEMENT OF INTELLECTUAL
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GIVEN IN THIS APPLICATION NOTE.
Information
For further information on technology, delivery terms and conditions and prices please contact your
nearest Infineon Technologies Office (www.infineon.com).
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
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AN 2011-05
Revision History: date (2015-09-11), V1.2
Previous Version: Rev. 1.1
Subjects: Rev. 1.1 revised
 Update of Paragraph 3.7

Update of Paragraph 6.3

Update of Figure 11
Authors: Infineon Technologies AG
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Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
Table of contents
1 Abstract ........................................................................................................................................................ 4
2 Introduction .................................................................................................................................................. 4
2.1
Status of datasheets .......................................................................................................................... 6
2.2
Type designation ................................................................................................................................ 6
2.3
Module Label Code ............................................................................................................................ 9
3 Datasheet parameters IGBT ....................................................................................................................... 9
3.1
Collector - emitter voltage VCES .......................................................................................................... 9
3.2
Total power dissipation Ptot ................................................................................................................ 9
3.3
DC Collector Current IC nom ...............................................................................................................10
3.4
Repetitive peak collector current ICRM ..............................................................................................10
3.5
Reverse bias safe operating area RBSOA ......................................................................................11
3.6
Typical output and transfer characteristics ......................................................................................11
3.7
Parasitic Capacitances ....................................................................................................................13
3.8
Gate charge QG, gate current, internal and external gate resistor...................................................15
3.9
Parasitic turn-on ...............................................................................................................................16
3.10 Dynamic behavior ............................................................................................................................18
3.11 Short circuit ......................................................................................................................................20
3.12 Leakage currents ICES and IGES ........................................................................................................21
3.13 Thermal characteristics ....................................................................................................................21
4 Datasheet parameters Diode ....................................................................................................................22
4.1
Diode forward characteristic ............................................................................................................22
4.2
Repetitive peak forward current .......................................................................................................23
4.3
I t value ............................................................................................................................................23
4.4
Reverse recovery .............................................................................................................................23
2
5 Datasheet parameters NTC-thermistor ...................................................................................................26
6 Datasheet parameters Module .................................................................................................................28
6.1
Insulation voltage .............................................................................................................................28
6.2
Stray inductance L ..........................................................................................................................28
6.3
Module resistance RCC’+EE’ ...............................................................................................................30
6.4
Mounting torque M ...........................................................................................................................30
7 Symbols and Terms ..................................................................................................................................31
8 References .................................................................................................................................................33
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Industrial IGBT Modules
Explanation of Technical Information
1
Application Note AN 2011-05
V1.2 November 2015
Abstract
The following information is given as a hint for the implementation of the device only and shall not be
regarded as a description or warranty of a certain functionality, condition or quality of the device. This
Application Note is intended to provide an explanation of the parameters and diagrams given in the
datasheet of industrial IGBT modules. With the Application Note, the designer of power electronic systems,
requiring an IGBT module, is able to use the datasheet in a proper way and will be provided with background
information.
2
Introduction
The parameters listed in the datasheet are values that describe the characteristics of the module as detailed
as possible.
With this information, the designer should be able to compare devices from different suppliers to each other.
Furthermore, the information should be sufficient to figure out the limits of the device.
This document explains the interaction between the parameters and the influence of conditions like
temperature. Datasheet values that refer to dynamical characterization tests, e.g. switching losses, are
related to a specific test setup with its individual characteristics. Therefore, these values can deviate from a
user’s application.
The attached diagrams, tables and explanations are referring to the datasheet of a
FS200R07N3E4R_B11 rev.2.0 from 2011-04-06 as an example. The values and characteristics shown are
not necessarily feasible to be used for design-in activities. For the latest version of datasheets please refer to
our website.
Infineon’s datasheets of IGBT power modules are structured as listed below:
 Summarized device description on the front page as shown in Figure 1

Maximum rated electrical values of IGBT-chips

Recommended electrical operating conditions of IGBT-chips

Maximum rated electrical values of diode-chips

Recommended electrical operating conditions of diode-chips

NTC-Thermistor if applicable

Parameters concerning the overall module

Operating characteristics

Circuit diagram

Package outline

Terms and conditions of usage
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Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
Figure 1: Front page of the datasheet
There are also datasheets for older IGBT modules i.e. BSM100GAL120DLCK, where the front page as
shown in Figure 1 does not exist.
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
2.1
V1.2 November 2015
Status of datasheets
Depending on the status of the product development, the relating technical information contains:
 Target data
The numbers in these datasheets are target values, which are expected to be achieved. Values from these
target datasheets are useful for the initial calculations and approximations. The information and values of a
target datasheet cannot be guaranteed for the final product. The dimensioning of an inverter should only be
done with values based on a preliminary or final datasheet.
During the development phase, the modules are labeled with their type designation and carry the suffix ENG.
Modules with the ENG designation are supplied with a Sample Release Document. Important information
can be taken from this additional Sample Release Document, e.g. which values of the module are already
fixed and which values can still change during the development phase. ENG module samples are used for
preliminary and functional tests during the early stages of a product development phase. Samples marked as
ENG are not liable to Product Change Notification (PCN).
 Preliminary data
The difference between a preliminary and a final datasheet is, that certain values are still missing, for
example the maximum values. These missing values in the preliminary datasheet are marked to be defined
(t.b.d.).
Modules without ENG on the label reached series production status. All quality requirements are completely
fulfilled. If any major change to a module with series production status is necessary, customers must be
informed by means of a PCN containing information about the type and extent as well as the time of the
changes.
This also applies to modules that have preliminary datasheets.
 Final data
The final datasheet is completed with the values which were missing in the preliminary datasheet. Major
changes of module characteristics or changes in datasheet values in the series status are accompanied by a
PCN.
2.2
Type designation
The first section of the datasheet begins with the type designation of the module as shown in Figure 2.
FS 200 R 07 N3 E4 R B11
Construction variation
Particularity of the module
Chip Type
Mechanical construction
Blocking Voltage
Functionality
Current Rating
Module Topology
Figure 2: Structure of the type designation
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
V1.2 November 2015
The following tables give a detailed insight to the type designation of Infineon’s industrial IGBT Modules.
As an example the FS200R07N3E4R_B11 is chosen.
FS
FF
FZ
FS
FP
200
R 07
N
E
4
R
B11
FB
FM
FR
F4
F5
FD/
DF
DD
F3L
FS3L
FT
Explanations
Dual switch
Single switch
3 phase full bridge
Power integrated module
Power integrated module with single
phase input rectifier
Matrix converter module
Switched reluctance module
H bridge
Module with 5 switches
Chopper configuration
Dual diode (for circuit see outline)
3-Level one leg IGBT module
3-level 3 phase bridge
Tripack
Max. DC-collector current
Reverse conducting
Fast diode
Reverse blocking
Collector-emitter-voltage in 100 V
07 denotes 650V
Mechanical construction: module
Package: IHM / IHV B-Series
Package: PrimePACK™
Econo DUAL™
EconoPACK™1..3
EconoPACK™+
EconoPACK™4
Package: Smart 1..3
Easy 750
200
R
S
T
06
33
07
45
12
65
17
K
H
I
M
N1..3
O
P
U1..3
V
W1..
3
EasyPACK , EasyPIM™ 1..3
F
H
J
L
S
E
T
P
1..n
C
D
F
G
I
P
R
T
-K
B1..n
S1..n
7
Fast switching IGBT chip
High speed IGBT chip
SiC JFET chip
Low Loss IGBT chip
Fast Short tail IGBT chip
Low Sat & fast IGBT chip
Fast trench IGBT
Soft switching trench IGBT
Internal reference numbers
With Emitter Controlled-Diode
Higher diode current
With very fast switching diode
Module in big housing
Integrated cooling
Pre-applied thermal interface material
Reduced numbers of pins
Low temperature type
Design with common cathode
Construction variation
Electrical selection
Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
BSM100GB120DLx as an Example for the old designation
BSM 100 GB
120 DLx
Explanations
BSM
Switch with IGBT and FWD
BYM
Diode module
100
Max. DC-collector current (A)
GA
Single switch with one IGBT and FWD
GB
Half bridge
GD
3 phase full bridge
GT
3 single switches and FWD
GP
Power integrated module B6 / Break / Inverter
GAL
Chopper module ( diode on collector side)
GAR
Chopper module (diode on emitter side)
A
Single diode
120
Collector-emitter-voltage in 10V
DL
Typ with low VCEsat
DN2 Fast switching type
DLC Low loss type with Emitter Controlled-diode
S
With collector sense
G
Design variation
Exx
Special type
Example for MIPAQ module IFS150B12N3T4
Designation of MIPAQ (Module Integrating Power, Application and Quality)
I
FS
150 B
12
N3
T 4
Explanations
I
MIPAQ family
FF
Dual switch
FZ
Single switch
FS
3 phase full bridge
FT
Tripack
FP
Power Integrated Module
150
Max. DC-collector current in A
B
With current sensor
S
With digital current measurement
V
With gate driver and temperature measurement
12
Collector-emitter-voltage in 100 V
N1..3
Package: EconoPACK™1..3
P
Package: EconoPACK™4
U1..3
Package: Smart1..3
S
Fast Short tail IGBT chip
E
Low Sat & fast IGBT chip
T
Thin IGBT
P
Soft switching IGBT chip
1..n
Internal reference numbers
B1..n
Construction variation
S1..n
Electrical selection
8
Industrial IGBT Modules
Explanation of Technical Information
2.3
Application Note AN 2011-05
V1.2 November 2015
Module Label Code
To facilitate the handling of the module from logistic’s and traceability point of view, all Infineon IGBT
modules are considered as unique and labeled as represented in Figure 3. Each module can be identified
with its material number, serial number, date code and lot number. All IGBT modules follow similar rules for
labeling and identification. Bar code or DMX codes are given on the modules for automated identification.
Test data are stored for eleven years.
Figure 3: Example of Module Label Code
3
Datasheet parameters IGBT
This section explains the electrical properties of the IGBT chip inside the given IGBT module.
If one of these maximum ratings presented in the datasheet is exceeded, it may result in a breakdown of the
semiconductor, even if the other ratings are not stressed to their limits. Unless specified to the contrary, the
values apply at a temperature of 25°C.
3.1
Collector - emitter voltage VCES
The permissible peak collector - emitter voltage is specified at a junction temperature of 25°C as seen in
Figure 4. This value decreases for lower temperatures with a factor of approximately
.
Figure 4: Collector - emitter voltage of the IGBT
3.2
Total power dissipation Ptot
This parameter as shown in Figure 5 describes the maximum feasible power dissipation through the thermal
resistance junction to module case RthJC.
Figure 5: Maximum rating for Ptot
The total power dissipation can be calculated in general to be:
(1) (1)
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Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
The considered IGBT module is an EconoPACK™ 3 with a base plate structure. The power dissipation is
related to ∆T between junction and case and the thermal resistance RthJC between junction and case as
hinted out in equation (2).
(2) (2)
At a case temperature of 25°C, the power dissipation is specified as a maximum value of:
(3) (3)
The power dissipation of the diode chips can be calculated the same way as for the IGBTs, in accordance to
equation(2).
3.3
DC Collector Current IC
Based on the total power dissipation, the maximum permissible collector current rating of a module can be
calculated with equation (4). Thus, in order to give a current rating of a module, the corresponding junction
and case temperature has to be specified, as shown for example in Figure 6. Please note that current ratings
without defined temperature conditions have no technical meaning at all.
(4) (4)
Since IC is not known in equation (4), VCEsat @ IC is also not known, but can be found within a few iterations.
The ratings of continuous DC-collector current are calculated using maximum values for VCEsat to ensure the
specified current rating, taking component tolerances into account.
Figure 6: DC collector current
3.4
Repetitive peak collector current ICRM
The nominal current rating can be exceeded in an application for a short time. This is defined as repetitive
peak collector current in the datasheet as can be seen in Figure 7 for the specified pulse duration. In theory,
this value can be derived from the feasible power dissipation and the transient thermal impedance Z th, if the
duration of the over current condition is defined. However, this theoretical value is not taking any limitations
of bond wires, bus-bars or power connectors into account.
Therefore, the datasheet value is quite low compared to a calculated value based on theory, but it specifies a
safe operation considering all practical limitations of the power module.
Figure 7: Repetitive peak collector current
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
3.5
V1.2 November 2015
Reverse bias safe operating area RBSOA
This parameter describes safe operating conditions at turn-off for the IGBT. The chip can be driven within its
specified blocking voltage up to twice its nominal current rating, if the maximum temperature under switching
conditions is not exceeded. The safe operating area of the power module is limited due to the module’s
internal stray inductances and specified at the maximum temperature under switching conditions as shown in
Figure 8. With increasing currents, the allowed DC-Link voltage is decreased. Furthermore, this derating
strongly depends on system related parameters, like stray inductance of the DC-Link and the current
commutation slope during the switching transitions. The DC-Link capacitor is assumed to be ideal for this
operating area. The current commutation slope is defined via a specified gate resistance and gate driving
voltage. In no event the voltage spike must not exceed the specified voltage of the module at the terminals or
at chip level to keep the RBSOA limits.
U
U
Module Level
Chip Level
Due to strayinductance
inside module
 V

 L

.
di
dt
DC-Link voltage
Figure 8: Reverse bias safe operating area
3.6
Typical output and transfer characteristics
This data can be used to calculate conduction losses of the IGBT. In order to contribute to a much better
understanding of these parameters, the IGBT device structure as well as it’s difference in output
characteristic compared to a power MOSFET is discussed briefly. After this, the datasheet parameters of the
IGBT module are explained.
Figure 9a shows in detail the structure of a trench-field-stop IGBT with a simplified two-transistor equivalent
circuit. The emitter-sided pn-junction of the pnp-transistor resembles the IGBT’s collector side. Like a diode it
leads to a characteristic voltage drop when the IGBT is conducting current. The intrinsic bipolar transistor of
the IGBT is driven by a MOSFET. Therefore, the gate driving characteristic is quite similar to a power
MOSFET. The output characteristic is different, which is illustrated in Figure 9b schematically. It shows the
characteristic of turned-on devices at two different junction temperatures.
The MOSFET as shown in Figure 9b is reverse conducting for negative drain-source voltages due to its
intrinsic body diode. The IGBT has no body diode and thus an anti-parallel diode has to be used, when this
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
V1.2 November 2015
operating mode is required. The advantage is, that the external diode can be optimized independently to suit
the IGBT’s switching characteristics.
In contrast to the MOSFET, that has an on resistance as a dominant parameter, the IGBT has a forward
voltage drop. As a result, at very low load, indicated with 1 in Figure 9b, the MOSFET always has lower
conduction losses than an IGBT.
Both output characteristics depend on the junction temperature. The R ds(on) of a MOSFET typically increases
by a factor of about two, when the junction temperature increases from 25°C to 150°C. The temperature
coefficient of an IGBT’s forward voltage is much lower. At low load, the conduction losses even decrease
with increasing temperature, due to the lower voltage drop at the pn-junction as represented in Figure 9b. At
higher currents, the increase of the ohmic resistance is dominant. Due to this, a parallel connection of
several IGBTs is possible and is commonly required for high current IGBT power modules.
a)
b)
Emitter
IGBT
Gate
Gate
ICE
IDS
IC
VCE
+
+
nn
p+ p+
n
Collector
Tj2IGBT
Tj1MOSFET
MOSFET
ID
VDS
n-
Tj1IGBT
High load
2
Low load
1
(substrate)
Low load Pcond-IGBT(@150°C)
< Pcond-IGBT(@25°C)
(fieldstop)
High load
p+
Tj2MOSFET
IGBT 25°C
IGBT 150°C
MOSFET 25°C
MOSFET 150°C
VCE
VDS
Pcond-IGBT(@150°C)
> Pcond-IGBT(@25°C)
Figure 9: Structure of a Trench-Field-Stop IGBT and two-transistor equivalent circuit (a).
Comparison of the output characteristics of power MOSFET and IGBT (b)
The transfer characteristic shows, that the turn-on threshold voltage decreases with increasing junction
temperature as seen in Figure 10.
VGEth @ Tvj=25°C
VGEth @ Tvj=150°C
Figure 10: Typical transfer characteristic
As discussed in chapter 3.6, the output characteristic of the IGBT depends on the temperature of the
junction. Figure 11a shows the collector current in conducting state as a function of the collector-emitter
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
V1.2 November 2015
voltage at different junction temperatures. For currents lower than about 80A, the conduction losses
decrease with increasing temperature. For higher currents, the conduction losses increase slightly. In the
case considered, an increase in conduction losses of about 6% at nominal current 200A and a temperature
increase from 25°C to 150°C can be observed.
b)
Pcond @ 25°C
> Pcond @150°C
Pcond @ 25°C
< Pcond @ 150°C
a)
Saturation
mode
Linear mode
Figure 11: Typical output characteristic as a function of the temperature (a)
and gate-emitter voltage variation (b)
Figure 11b shows the typical output characteristic for different gate-emitter voltages. The IGBT should not be
operated in linear mode, as this causes excessive conduction losses. If the power dissipation is not limited in
magnitude and time, the device might be destroyed. Using 15V as typical gate drive voltage, this linear mode
only occurs for short periods at the switching transitions, which is a normal operating condition for the IGBT.
3.7
Parasitic Capacitances
The dynamic characteristics of an IGBT are influenced by several parasitic capacitances. These are inherent
parts of the die’s internal structure as represented in Figure 12a. A simplified schematic is shown in Figure
12b. The input capacitance Cies and the reverse transfer capacitance Cres are the basis for an adequate
dimensioning of the gate driver circuit. The output capacitance Coss limits the dV/dt at switching transitions.
Losses related to Coss can usually be neglected.
The major parasitic capacitances inside the IGBT die are:
a)

Input capacitance Cies = CGE + Cres. CGE includes C1,C3,C4 and C6.

Reverse transfer capacitance Cres including C2 and C5. Cres = CCG

Output capacitance Cce represented by C7. Coss = CCE + Cres
b)
Figure 12: Parasitic capacitances of an IGBT, internal structure a), schematic b)
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Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
The values of the parasitic capacitances strongly depend on the operating point of the IGBT. To measure
these capacitances with gate- or collector-emitter voltages applied, dedicated measurement circuits
according to IEC60747-8 have to be utilized.
Input capacitance Cies
This parameter is determined using the setup in Figure 13. Cies is measured across the gate and emitter
connections with collector-emitter connection shorted for AC voltage. The values of the DC voltage across
the gate-emitter and collector-emitter connections are specified with the test frequency. Capacitors C1 and
C2 must form an adequate bypass at the test frequency. The inductor L decouples the DC supply.
Figure 13: Basic circuit diagram for measuring the input capacitance C ies
Output capacitance Coss
Coss is measured according to the setup in Figure 14. This value is measured across the collector and emitter
connections with gate-emitter connections shorted for AC voltage. The values of the DC voltage across the
gate-emitter and collector-emitter connections are specified with the test frequency. The capacitors C1, C2
and C3 must form an adequate bypass at the test frequency. The inductor L decouples the DC supply.
Figure 14: Basic circuit diagram for measuring the output capacitance C oss
Reverse transfer capacitance Cres
Figure 15 gives details about the measurement setup for the reverse transfer capacitance. C res is measured
across the collector and gate connections, the emitter connection being connected to the protective screen
of the bridge. The values of the DC voltage across the gate-emitter connection are specified with the test
frequency. Capacitors C1 and C2 must form an adequate bypass at the test frequency. The inductors L1 and
L2 decouple the DC supply.
Figure 15: Basic circuit diagram for measuring the reverse transfer capacitance Cres
The capacitance meter used for the measurements of C ies, Coss and Cres has to be a high resolution
capacitance bridge with a sufficient measurement range.
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
3.8
V1.2 November 2015
Gate charge QG, gate current, internal and external gate resistor
The value of the gate charge can be used to optimize the design of the gate driver circuit. The average
output power that the gate driving circuit has to deliver can be calculated with data of the gate charge, gate
driver voltages and switching frequency as given in equation (5).
(5) (5)
Within this formula, QG refers to the part of the gate charge that is truly active in the given design. What part
is used is depending on the gate driver output voltage; an accurate approximation can be done using the
gate charge curve.
The real gate charge Q’G that has to be taken into account results from the diagram in Figure 16, by
choosing the values that correspond to the gate driver’s output voltage:
Typical gate charge diagram 1200V IGBT4
20,00
15,00
10,00
VGE [V]
5,00
0,00
0,00
0,10
0,20
0,30
0,40
0,50
0,60
0,70
0,80
0,90
1,00
-5,00
-10,00
-15,00
-20,00
standardized QGate/QGate_nominal [µC]
Figure 16: Typical gate charge curve of an 1200V IGBT
Typical values used in industrial applications include designs with a turn-off voltage VGE=0V as well as
designs featuring negative supply like VGE=-8V
Q’G = 0.62 • QG
for 0V/15V
Q’G = 0.75 • QG
for -8V/15V
At a switching frequency of fsw=10 kHz and a driver output voltage of +15/ -8V, the required output power of
the gate driving circuit PGdr can be calculated using the adapted gate charge from Figure 16 and the gate
charge as seen in the datasheet Figure 17.
.
Figure 17: Gate charge and internal gate resistor
The theoretical gate drive peak current can be calculated according to equation (6), knowing the gate drive
voltages and gate resistances. The gate resistor is the sum of external and internal gate drive resistance.
Figure 17 shows the value for the internal resistance to be considered.
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
V1.2 November 2015
(6) (6)
In practice, this peak current will not be reached, because it is limited by stray inductances and non-ideal
switching transitions of a real gate driving circuit.
The datasheet value given for the internal gate resistor has to be understood as a single resistance and may
result from paralleled resistors inside the IGBT module as illustrated in Figure 18. This usually counts for
larger modules only, especially medium- and high-power types. These internal resistors lead to improved
internal current sharing.
The internal resistance should be considered as one part of total gate resistor to calculate the peak current
capability of a driver.
DC+
C
Rgext
G
E
C
Rgext
R’g1
R’g2
R’g3
AC
G
E
R’g4
R’g5
R’g6
DC-
Figure 18: internal gate resistor of the IGBT
The designer can use the external gate resistor to influence the switching performance of the IGBT.
Minimum RGon is limited by turn-on di/dt, minimum RGoff is limited by turn-off dV/dt. Too small gate resistors
can cause oscillations and may lead to damage the IGBT or diode. The minimum recommended external
gate resistor RGext is given in the switching losses test conditions as mentioned in Figure 19. The allowed
external gate resistor values are shown in the switching loss diagram of Figure 24b.
Figure 19: External gate resistors
3.9
Parasitic turn-on
With the parasitic capacitances of the IGBT, noted in the datasheet as stated in Figure 20, dV/dt induced
parasitic turn-on phenomena can occur. The cause of a possible parasitic turn-on is based on the intrinsic
capacitive voltage divider between collector-gate and gate-emitter.
In consideration of high voltage transients across collector-emitter, this intrinsic capacitive voltage divider is
much faster than an external gate driving circuit that is limited by parasitic inductances. Therefore, even if the
gate driver turns off the IGBT with zero gate-emitter voltage, transients of collector-emitter voltage lead to an
increase of the gate-emitter voltage. If the gate emitter voltage exceeds the gate threshold voltage VGEth, the
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Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
IGBT will turn on. Neglecting the influence of the gate driving circuit, the gate-emitter voltage can be
calculated by
(7) (7)
The quotient Cres/Cies should be as low as possible. To avoid a parasitic dV/dt induced turn-on, the quotient
Cies/Cres for the FS200R07N3E4_B11 is about 35. Furthermore, the input capacitance should be as low as
possible to avoid gate driving losses; therefore the use of additional gate-emitter capacitance CGE has to be
evaluated carefully.
Figure 20: Parasitic capacitances of the IGBT
The parasitic capacitances are determined under the conditions given in Figure 20. The gate-emitter
capacitance CGE as shown in Figure 21 can be approximated to be constant over the collector-emitter
voltage as shown in equation (8).
(8) (8)
The reverse transfer capacitance Cres strongly depends on the collector-emitter voltage and can be
estimated according to equation (9).
(9) (9)
Figure 21: Approximation of CGE and CCE as function of the
collector-emitter voltage according to equations (8) and (9)
Consequently, the robustness against dV/dt induced parasitic turn-on increases with the collector-emitter
voltage as seen in equation (7).
17
Industrial IGBT Modules
Explanation of Technical Information
3.10
Application Note AN 2011-05
V1.2 November 2015
Dynamic behavior
The switching characteristic described in the datasheet provides useful information to determine an
appropriate dead time between turn-on and turn-off of the complementary devices in a half bridge
1
configuration. For further information about dead time calculation please refer to AN2007-04 available at
Infineon’s website.

Turn-on delay time td on:
Time it takes from getting the gate-emitter voltage to 10% of the rated value to the moment the
collector current reaches 10% of its nominal size

Rise time tr:
Time which the collector current takes to rise from 10% to 90% of its nominal value

Turn-off delay time td off:
Time necessary from getting the gate-emitter voltage to 90% of the rated value to the moment the
collector current reaches 90% of its nominal size

Fall time tf:
Time which the collector current takes to fall from 90% to 10% of his nominal value
The times in the datasheet are defined as detailed in Figure 22:
Figure 22: Specification of rise and fall times and conditions to calculate switching losses
1
Application note 2007-04: How to calculate and minimize the dead time requirement for IGBTs properly.
18
Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
These times alone will not give reliable information about switching losses, because voltage rise and fall
times as well as current tail shape are not specified. Therefore, switching losses per pulse are given
separately.
The switching losses per pulse are defined using the integrals:
(10) (10)
The integration limits for the switching losses are given in Figure 22:

Eon as turn-on energy per pulse from t1 to t2

Eoff as turn-off energy per pulse from t3 to t4
Dynamic behavior and thus energy per pulse strongly depend on a variety of application specific operating
conditions like gate driving circuit, layout, gate resistance, magnitude of voltages and currents to be switched
as well as the junction temperature. Therefore, datasheet values can only give an indication for the switching
performance of the power module. For more accurate values, detailed simulations taking application specific
parameters into account or experimental investigations are necessary.
Typically, switching transition duration and energy per pulse are characterized at nominal operating
conditions for different temperatures as noted in Figure 23.
Figure 23: Switching times and energies
A first estimation of dynamical losses can be done utilizing Figure 24. The diagram hints out typical losses
depending on RG, IC and junction temperature Tvj. The switching loss diagram Figure 24b and Figure 35b
shows also the allowed external gate resistor values. The left end of the curves in Fig 24b and Fig 35b
specifies the minimum allowed external gate resistor value. The gate resistors must not be lower because
this may lead to a destruction of the device.
19
Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
a)
V1.2 November 2015
b)
Figure 24: Switching losses per pulse as a function of the collector current and the gate resistance
3.11
Short circuit
The short circuit characteristic strongly depends on application specific parameters like temperature, stray
inductances, gate driving circuits and the resistance of the short circuit path. For device characterization, a
test setup as drawn in Figure 25a is used. One IGBT is short circuited while the other IGBT is driven with a
single pulse. The corresponding typical voltage and current waveforms are illustrated in Figure 25b. The
current in the conducting IGBT increases rapidly with a current slope that is depending on parasitic
inductances and the DC-Link voltage. Due to desaturation of the IGBT, the current is limited to about 5 times
the nominal current in case of IGBT3 and the collector-emitter voltage remains on the high level. The chip
temperature increases during this short circuit due to high currents and thus high losses. Because of the
increasing chip temperature the current decreases slightly while operating in short circuit condition.
Within a defined short-circuit-withstand time tsc the IGBT has to be switched off to avoid a device failure.
a)
b)
VCE, IC
VCE
IC(t)
ISC
VGE
VCE
VGE
10% IC
10% IC
IC
t = t0
tSC
t = tP
Figure 25: Short circuit test setup (a) and
typical voltage/current waveforms during short circuit test (b)
20
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Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
The data of the measured short circuit and the applied parameters are noted in the datasheet as depicted in
Figure 26. All of Infineon's IGBT modules are designed to achieve a short circuit-withstand-time of up to
10µs. The IGBT3 600V is an exception as it features a short circuit withstands time of tp = 6µs
Figure 26: Short circuit data
3.12
Leakage currents ICES and IGES
Two major types of leakage currents as given in Figure 27 have to be considered:

The maximum collector-emitter cut-off current describes the leakage current between the collector
and emitter, when the IGBT is in blocking mode

The gate-emitter leakage current gives a hint about the maximum leakage current between gate and
emitter, with collector-emitter short circuited and maximum gate-emitter voltage applied.
Figure 27: Leakage currents
3.13
Thermal characteristics
The values of power dissipation and current ratings as discussed in chapters 3.2 and 3.3 have no meaning
without specification of temperatures as well as thermal resistances. Therefore, in order to compare different
devices, it is also necessary to compare thermal characteristics. More information about the thermal
2
equivalent circuit can be found in AN2008-03 .
When power modules with a base plate or discrete devices are characterized, junction-, case-, and heat sink
temperatures are observed. The thermal resistances of junction to case and case to heat sink are specified
in the datasheet as given in Figure 28. The datasheet value of the RthCH with a referenced thermal resistance
of the thermal interface material is a typical value under the specified conditions.
Figure 28: Thermal resistance IGBT, junction to case and case to heat sink
The thermal resistance characterizes the thermal behavior of the IGBT module at steady state, whereas the
thermal impedance characterizes the thermal behavior of the IGBT module at transient conditions like short
current pulses. Figure 29a shows the transient thermal impedance ZthJC as a function of the time.
2
Application note 2008-03: Thermal equivalent circuit model
21
Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
a)
V1.2 November 2015
b)
r1
r2
r3
r4
c1
c2
c3
c4
TVJ
TF
Figure 29: a) Transient thermal impedance junction to case and b) transient thermal model
The main power losses of the IGBT module are dissipated from the silicon die to the heat sink through
different materials. Each material within the dissipation path has its own thermal characteristics. As a result,
the thermal impedance behavior can be modeled with the appropriate coefficients of the IGBT module and is
given as diagram ZthJC(t) as shown in Figure 29a. The separate RC-elements from Figure 29b have no
physical meaning. Their values are extracted from the measured heating-up curve of the module by a
corresponding analysis tool. The datasheet includes the partial fraction coefficients in tabular form as shown
in Figure 29a. The values of the capacitances can be calculated by:
(11) (11)
4
Datasheet parameters Diode
This section explains the electrical properties of the diode-chip inside the given IGBT module
4.1
Diode forward characteristic
The maximum permissible diode forward current rating can be calculated with equation (12). To give a
current rating of a module, the corresponding junction and case temperature have to be specified, for
example in Figure 30. Please note that current ratings without defined temperature conditions have no
technical meaning at all. Since IF is not known in equation (12), VF @ IF is also not known, but can be found
within a few iterations. The ratings of continuous collector current are calculated with maximum values for VF
to ensure the specified current rating, taking component tolerances into account.
(12) (12)
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
V1.2 November 2015
Figure 30 depicts the typical forward characteristic of the implemented diode at different junction
temperatures. A negative temperature coefficient of the diode’s forward voltage drop can be observed, which
is typical for minority-carrier devices. Therefore, the conduction losses of the diode decrease with increasing
temperatures.
Figure 30: Forward characteristic of diode datasheet
4.2
Repetitive peak forward current
The nominal diode current rating can be exceeded in an application for a short time. This is defined as
repetitive peak forward current in the datasheet for the specified pulse duration, for example 1ms as noted in
Figure 31. In theory, this value can be derived from the feasible power dissipation and the transient thermal
impedance Zth, if the duration of the over current condition is defined. However, this theoretical value is not
taking any limitations of bond wires, bus-bars or power connectors into account.
Figure 31: Repetitive peak forward current
I2t value
4.3
2
This value defines the surge current capability of the diode. The I t value applied should be lower than the
2
specified I t value and tp should not exceed 10ms as mentioned in Figure 32.
Figure 32: Values of the surge capability
4.4
Reverse recovery
To investigate the transient behavior of a diode, the surrounding circuitry as already shown in Figure 8 on
page 11 has to be taken into account. To simplify the circuitry, the output current of the half bridge can be
assumed to be constant during commutation. The remaining stray inductances formed by the current loop
23
Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
can now be replaced by just one stray inductance between high-side and low-side switch/freewheeling
diode.
Figure 33: Schematic voltage and current waveform of a soft-recovery diode during turn-off
transition
Figure 33 describes the current commutation from a high-side (HS) freewheeling diode to a low-side (LS)
IGBT.
The commutation is triggered by turning-on the LS-IGBT which will not reduce the blocking voltage to
roughly zero immediately. It will keep a portion of blocking voltage during the commutation. Due to the fact
that the HS-diode is still on, the difference VL = VR - VIGBT will drop across the stray inductance causing a
linear change of current. The diode current will reduce in the same way as the IGBT current increases. As
soon as the diode current at t = t’ crosses zero, a space charge region within the diode can be formed.
Hence the voltage drop across the diode increases as can be seen in Figure 33.
The voltage drop across the stray inductance will be zero if the sum of diode and IGBT voltage is equal to
the blocking voltage VR
if di/dt = 0
(13) (13)
As a result, the peak reverse recovery current IRM is reached. The current commutation is finished and the
reverse recovery current has to be reduced to zero. Any kind of oscillation has to be avoided.
After t > tRM, the LS-IGBT which is still not fully turned on will reduce its voltage further and the blocking
voltage of the HS-diode will increase to the final VR. During this last step, the current change from IRM to zero
will result in an overvoltage across the diode; however in this case it will be masked by the increasing
blocking voltage.
The reverse recovery of the diode will lead to additional turn-off losses as well as additional turn-on losses in
the complementary switch. A current and voltage waveform of a soft-recovery emitter controlled diode during
turn-off transition can be seen in Figure 33
The characterized peak reverse recovery current I RM given in the datasheet section on Figure 34, is defined
as the difference between the maximum negative current peak and zero current. The recovered charge
results from:
(14) (13)
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Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
V1.2 November 2015
The integration limits are defined as t = t’1 @ IF =0 and t = t’2 @
as marked in Figure 33.
The losses due to reverse recovery can be calculated with the recovered energy per pulse. The energy is
determined as defined in equation (15):
(15) (14)
The integration limits are chosen for the time t’1 corresponding to 10% of the diode reverse voltage VR and
the time t2 when the reverse recovery current IRM peak attains 2%.
The recovered charge and thus switching losses caused by the reverse recovery of the diode strongly
depend on junction temperature as well as current slope.
Figure 34: Reverse recovery current, charge and reverse recovery energy
To give an indication of application specific switching losses, the losses per diode turn-off pulse as noted in
the datasheet are a function of diode forward current and gate resistance of the switching IGBT as
represented in Figure 35. The variation in gate resistance is an equivalent to a variation in commutation
current slopes.
Figure 35: Reverse recovery energy per pulse as a function of
a) diode conducting current and
25
b) gate resistance
Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
5
V1.2 November 2015
Datasheet parameters NTC-thermistor
One of the most important parameters in power electronic devices is the chip temperature. The
measurement of this temperature during operation is very difficult. One approach to estimate the real chip
temperature in steady state is to use the NTC inside the IGBT module. This method is not adequate for
measurement of fast variation of the chip temperature.
The temperature of the chips can be calculated using a thermal model and measuring the temperature at the
NTC. The resistance of the NTC can be calculated as a function of the NTC temperature T2
(16)
The resistance R25 at temperature
is specified in the datasheet as shown in Figure 36.
With measurement of the actual NTC-resistance R2, the temperature
can be calculated with equation
(17).
(17) (1
6)
The maximum relative deviation of the resistance is defined at a temperature of 100°C by
from Figure
36. To avoid self heating of the NTC, the power dissipation inside the NTC has to be limited.
To limit the self heating of the NTC up to a maximum value of 1K, the current through the NTC can be
calculated according to equation (18). More detailed information how to use the NTC inside the IGBT module
is provided in AN2009-10
3
(18) (17)
Figure 36: Characteristic values of the NTC-thermistor
To calculate the NTC resistance as well as temperature more accurately, B-values are required. The B-value
stated in Figure 37 depends on the temperature range considered. Typically a range of 25 to 100°C is of
interest and thus B25/100 has to be used. In case a lower temperature range is in focus, the B-values B25/80 or
B25/50 can be used, which leads to more accurate calculation of the resistance in these lower ranges.
3
Application note 2009-10: Using the NTC inside a power electronic module
26
Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
Figure 37: B-values of the NTC-thermistor
The use of the NTC for temperature measurement is not suitable for short circuit detection or short term
overload, but may be used to protect the module from long term overload conditions or malfunction of the
cooling system.
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Industrial IGBT Modules
Explanation of Technical Information
6
Application Note AN 2011-05
V1.2 November 2015
Datasheet parameters Module
This part covers electrical topics related to the mechanical construction of the IGBT module.
6.1
Insulation voltage
To verify the rated insulation voltage of the IGBT module, all terminals are connected to the high side of a
high voltage source. The base plate is connected to the low side of the high voltage source. This high
voltage source with high impedance must be able to supply the required voltage Viso. A test voltage is slowly
raised to the specified value determined by equation (19) and maintained at that value for the specified
time t.
(19) (18)
The voltage is then reduced to zero. Infineon’s IGBT modules are designed to achieve at least the basic
insulation class 1 according to IEC 61140. For IGBT modules with an internal NTC, the functional insulation
requirement is fulfilled between the grounded NTC terminals and the remaining control and power terminals
connected and powered by the high voltage source.
The appropriate insulation voltage depends on the maximum rated collector-emitter voltage of the IGBT.
Most drive applications require an insulation voltage of 2.5kV for IGBT modules up to 1700V blocking
voltage. For traction applications, the required insulation voltage is defined to be 4kV for the same IGBT
blocking voltage of 1700V. Therefore it is important to focus on the application field during the choice of the
IGBT module.
Figure 38: Insulation test voltage
The insulation test voltage in the datasheet as mentioned in Figure 38 is measured before and after reliability
tests of the power module and is furthermore part of failure criteria of such stress tests.
The insulation voltage of the NTC inside the IGBT fulfills a functional isolation requirement only. In case of
failures, for example of the gate driving circuit, a conducting path can be formed by moving bond wires that
change their position during the failure event or by a plasma path forming as a consequence of arcing during
failure. Therefore, if insulation requirements higher than a functional insulation have to be achieved,
additional insulating barriers have to be added externally.
6.2
Stray inductance L
Stray inductances lead to transient over voltages at the switching transients and are a major source of EMI.
Furthermore, in combination with parasitic capacitances of the components, they can lead to resonant
circuits, which can cause voltage and current ringing at switching transients. The transient voltage due to
stray inductances can be calculated with:
(20) (1
28
Industrial IGBT Modules
Explanation of Technical Information
Application Note AN 2011-05
V1.2 November 2015
Consequently, the stray inductances have to be minimized in order to reduce voltage overshoot at turn-off
transitions. The value of the stray inductance as given in Figure 39, depends on the IGBT topology and
would be understood as:

The inductance of single switch modules

The inductance of one switch for modules with two switches

The loop with the highest inductance for half bridge, four- and sixpack modules specifies the
inductance of one bridge

The largest loop from P to N specifies the inductance for PIM modules
Figure 39: Module stray inductance
29
Application Note AN 2011-05
Industrial IGBT Modules
Explanation of Technical Information
6.3
V1.2 November 2015
Module resistance RCC’+EE’
The lead resistance of the module is a further contributor to voltage drop and power losses. The specified
value in the datasheet characterizes the lead resistance between the power terminals of one switch as
mentioned in Figure 40. According to the equivalent circuit shown in Figure 41, the module’s lead resistance
is defined as:
(21) (21)
Figure 40: Module lead resistance
P C’
C
P C’
RCC’
C
RCC’
shunt
resistor
E
E’’
REE’
RE’’E’
N
E
E’
E’’
a)
N
REE’
E’
RE’’E’ R
20
b)
Figure 41: Equivalent circuit of module lead resistance a) without integrated shunt resistor,
b) with integrated shunt resistor
If the module is equipped with a shunt resistor at the output terminal, as displayed in Figure 41 b), the
resistance of the shunt resistor R20 is not included in the module lead resistance RCC’+EE’.
6.4
Mounting torque M
The torque for the mechanical mounting of the module is specified in the datasheet as noted in Figure 42.
These values are important to ensure the proper clamping force of the module to the heat sink. For modules
with screwable power terminals, an additional mounting torque for terminal connection is given in the
datasheet to ensure a reliable mechanical and electrical connection of bus-bars.
Figure 42: Module mounting torque requirements
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Industrial IGBT Modules
Explanation of Technical Information
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Application Note AN 2011-05
V1.2 November 2015
Symbols and Terms
Symbols and terms used in this document are part of the standards specification as listed below:
Symbols
A
C
Co(er)
Co(tr)
Cies
Coes
Cres
Cth
CDS
CGD
CGS
CMi
Cσ
D
diF/dt
di/dt
dirr /dt
dv/dt
E
EA
EAR
EAS
Eoff
Eon
F
G
Gfs
I
I
IAR
ID
IDpuls
IDSS
IDSV
IC
ICM
ICES
ICRM
ICpuls
IG
Terms
Anode
Capacitance, collector
Effective output capacitance, energy related
Effective output capacitance, time related
Input capacitance
Output capacitance
Reverse transfer capacitance
Thermal capacitance
Drain-Source capacitance
Gate-Drain capacitance
Gate-Source capacitance
Miller capacitance
Stray capacity
Pulse duty factor/duty cycle D = tp/T
Rate of diode current rise
Rate of current rise general
Peak rate fall of reverse recovery current
Rate of diode voltage rise
Energy
Avalanche energy
Avalanche energy, repetitive
Avalanche energy, single pulse
Turn-off loss energy
Turn-on loss energy
Frequency
Gate
Transconductance
Current
Current, instantaneous value
Avalanche current, repetitive
DC drain current
DC drain current, pulsed
Drain cutoff current
Drain cutoff current with gate voltage applied
Collector current
Peak collector current
Collector cut-off current, gate-emitter short-circuited
Repetitive peak collector current
Collector current, pulsed
Gate current
31
Industrial IGBT Modules
Explanation of Technical Information
Symbols
IF
IFSM
Ic nom, Ic
IGSS
IRM
ISM
IGES
IL
IRRM
K
L
LL
Lp
Lσ
PAV
Psw
Ptot
Pcon
QG
QGS
QGD
QGtot
Qrr
RDS(on)
RG
RGint, rg
RGE
RGon
RGoff
RGS
Ri
RL
RthCH
RthHA
RthJA
RthJC
RthJS
S
T
TA
TC
Terms
General diode forward current
Diode current surge crest value 50 Hz sinusoidal
Continuous DC collector current
Gate-Source leakage current
Diode peak reverse recovery current
Inverse diode direct current, pulsed
Gate leakage current, collector-emitter short-circuited
Current through inductance
Maximum reverse recovery current
Cathode
Inductance
Load inductance
Parasitic inductance (e.g. lines)
Leakage inductance
Avalanche power losses
Switching power losses
Total power dissipation
Conducting state power dissipation
Gate charge
Charge of Gate-Source capacitance
Charge of Gate-Drain capacitance
Total Gate charge
Reverse recovery charge
Drain-Source on state resistance
Gate resistance
Internal gate resistance
Gate-emitter resistance
Gate-turn on resistance
Gate-turn off resistance
Gate-Source resistance
Internal resistance (pulse generator)
Load resistance
Thermal resistance, case to heat sink
Thermal resistance, heat sink to ambient
Thermal resistance, junction to ambient
Thermal resistance, junction to case
Thermal resistance, junction to soldering point
Source
Cycle time; temperature
Ambient temperature
Case temperature
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Application Note AN 2011-05
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Industrial IGBT Modules
Explanation of Technical Information
Symbols
t
t1
td off
td on
tf
Tj
tp
Tvj max
Tvj op
toff
ton
tr
trr
Tstg
Tsold
V
VIN
V(BR)CES
V(BR)DSS
VCC
VCE
VCES
VCEsat
VCGR
VDD
VDGR
VDS
VF
VGE
VGES
VGE(th)
VGS
VGSth
VSD
Vplateau
ZthJA
ZthJS
ZthJC
8
Application Note AN 2011-05
V1.2 November 2015
Terms
Time, general
Instant time
Turn-off delay time
Turn-on delay time
Fall time
Chip or operating temperature
Pulse duration time
Maximum junction temperature
Temperature under switching condition
Turn-off time
Turn-on time
Rise time
Reverse recovery time
Storage temperature
Soldering temperature
Voltage, instantaneous value
Drive voltage
Collector-emitter breakdown voltage
Drain-Source Avalanche breakdown voltage
Supply voltage
Collector-emitter voltage
Collector-emitter voltage, gate-emitter short-circuited
Collector-emitter saturation voltage
Collector-Gate voltage
Supply voltage
Drain-Gate voltage
Drain-Source voltage
Diode forward voltage
Gate-emitter voltage
Gate-emitter voltage, collector-emitter short-circuited
Gate-emitter threshold voltage (IGBT)
Gate-Source voltage
Gate threshold voltage
Inverse diode forward voltage
Gate plateau voltage
Transient thermal resistance, chip to ambient
Transient thermal resistance, chip to solder point
Transient thermal resistance, chip to case
References
Infineon Technologies AG 'IGBT Modules Technologies, Driver and Application' ISBN978-3-00-032076-7
33