Evaluation Adapter Board for EconoPACK™4 3-Level Modules in NPC1-Topology

Application Note AN 2011-04
V1.0 June 2011
AN2011-04 MA3L080E07_EVAL
Evaluation Adapter Board for EconoPACKTM 4 3-Level
Modules in NPC1-Topology
IFAG IMM INP M AE
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
Application Note AN 2011-04
V1.0 June 2011
Edition 2011-05-15
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
TECHNOLOGIES HEREBY DISCLAIMS ANY AND ALL WARRANTIES AND LIABILITIES OF ANY KIND
(INCLUDING WITHOUT LIMITATION WARRANTIES OF NON-INFRINGEMENT OF INTELLECTUAL
PROPERTY RIGHTS OF ANY THIRD PARTY) WITH RESPECT TO ANY AND ALL INFORMATION
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
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.
AN 2011-04
Revision History: date (2011-05-15), V1.0
Previous Version: none
Subjects: none
Authors: Alain Siani (IFAG IMM INP M AE)
We Listen to Your Comments
Any information within this document that you feel is wrong, unclear or missing at all? Your feedback will
help us to continuously improve the quality of this document. Please send your proposal (including a
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2
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
Application Note AN 2011-04
V1.0 June 2011
1 Introduction .................................................................................................................................................. 4
1.1
Part Number explanation ................................................................................................................... 4
2 Design features ............................................................................................................................................ 5
2.1
Main features ..................................................................................................................................... 5
2.2
Key Data ............................................................................................................................................ 5
2.3
Mechanical dimensions ...................................................................................................................... 6
3 Pin assignments .......................................................................................................................................... 7
4 Functionality of the board .......................................................................................................................... 8
4.1
Power supply...................................................................................................................................... 8
4.2
Booster ............................................................................................................................................... 9
4.3
VCE monitoring for short circuit detection; active clamping function ................................................10
4.4
Maximum switching frequency .........................................................................................................11
5 Paralleling...................................................................................................................................................12
5.1
Static current imbalance ..................................................................................................................12
5.2
Dynamic current imbalance .............................................................................................................12
5.3
Paralleling with MA3L080E07_EVAL ...............................................................................................12
6 Base plate temperature monitoring by internal NTC resistor ...............................................................14
7 Schematics and Layouts ..........................................................................................................................14
7.1
Schematics.......................................................................................................................................14
7.2
Layouts .............................................................................................................................................17
8 Bill of Material of MA3L080E07_EVAL .....................................................................................................19
9 How to order the Evaluation Adapter Board ...........................................................................................20
10 Literature ....................................................................................................................................................20
The board described is an evaluation board dedicated for laboratory environment
only. It operates at high voltages. This board must be operated by qualified and
skilled personnel familiar with all applicable safety standards.
3
Application Note AN 2011-04
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
1
V1.0 June 2011
Introduction
TM
The evaluation adapter board MA3L080E07_EVAL for 3-Level EconoPACK 4 modules as shown in
Figure 1 was developed to support customers during their first steps designing applications with
TM
EconoPACK 4 3-Level modules. This evaluation board was designed in addition to the module driver
1
board F3L020E07-F-P_EVAL or could be a complementary part for an existing customer driver solution.
For more details about the 3-Level topology, please refer to [1].
The board is available from Infineon in small quantities. The properties of this part are described in the
datasheet chapter of this document, whereas the remaining paragraphs provide information intended to
enable the customer to copy, modify and qualify the design for production, according to their own specific
requirements.
Environmental conditions were considered in the design of the MA3L080E07_EVAL. Components qualified
for a lead-free reflow soldering process were selected. The design was tested as described in this document
but not qualified regarding manufacturing and operation over the whole operating temperature range or
lifetime.
The boards provided by Infineon are subjected to functional testing only.
Due to their purpose evaluation boards are not subjected to the same procedures regarding Returned
Material Analysis (RMA), Process Change Notification (PCN) and Product Discontinuation (PD) as regular
products.
See Legal Disclaimer and Warnings for further restrictions on Infineon’s warranty and liability.
Figure 1: The Evaluation Adapter Board MA3L080E07_EVAL for EconoPACK
1.1
1
Part Number explanation
Evaluation Driver Board for 3-Level EconoPACK
TM
4 AN2011-03
4
TM
4 3-Level modules
Application Note AN 2011-04
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
2
V1.0 June 2011
Design features
Electrical features of the evaluation board and mechanical dimensions including necessary interface
connections are presented in following sections.
2.1
Main features
2
The evaluation board is developed to work in combination with the F3L020E07-F-P_EVAL driver board. The
F3L020E07-F-P driver board provides the following main features:






TM
Electrically and mechanically suitable for 3-Level EconoPACK 4 modules family
Different gate resistor values for turning-on and -off are possible
Active clamping protection for high and low-side IGBTs
Desaturation output signal for short circuit monitoring
Base plate temperature monitoring by internal NTC resistor
3
Suitable for -8V/+15V or up to ±20V
2.2
Key Data
All values given in the table below are typical values, measured at an ambient temperature of
Tamb = 25 °C.
Table 1: General key data and characteristic values
Parameter
Description
Value
Unit
VDC
maximum DC supply voltage
±20
V
IG
continuous output current
±8
A
fS
maximum PWM signal frequency
60
kHz
Top
operating temperature (design target)
-40…+85
°C
Tsto
storage temperature (design target)
-40…+85
°C
TM
The EconoPACK 4 3-Level IGBT module has four vertically aligned IGBTs. As a reference, Figure 2
presents the positions of the semiconductors with their designation used throughout this document.
Figure 2: IGBT module with the designation of each IGBT
2
3
Evaluation Driver Board for 3-Level EconoPACKTM 4 AN2011-03
Due to IGBT short circuit performance a maximum value of VGE ~15V is recommended.
5
Application Note AN 2011-04
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
V1.0 June 2011
Figures 3 shows the functional groups of the MA3L080E07 evaluation board top side.
1:
2:
3:
4:
5:
6:
7:
Booster for outer low side IGBT
Desat and Active clamp for outer low side IGBT
Desat and Active clamp for outer high side IGBT
Temperature measurement
Booster for inner high side IGBT
Booster for inner low side IGBT
Booster for outer high side IGBT
Figure 3: Functional groups of the evaluation board MA3L080E07_EVAL top side
2.3
Mechanical dimensions
The dimensions of the MA3L080E07 adapter board are given in Figure 4.
Figure 4: Mechanical dimensions of the MA3L080E07_EVAL
6
Application Note AN 2011-04
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
3
V1.0 June 2011
Pin assignments
All PWM, logic signals and voltage supplies have to be applied as listed in the following tables.
Table 2: Pin assignment of the connector ST1 of the outer high side IGBT
Pin name
Pin function
ST1-1
+15V_T1
ST1-2
GND_T1
ST1-3
-8V_T1
ST1-4
PWM_T1
ST1-5
DESAT1
Table 3: Pin assignment of the connector ST2 of the inner high side IGBT
Pin name
Pin function
ST2-1
+15V_T2
ST2-2
GND_T2
ST2-3
-8V_T2
ST2-4
PWM_T2
ST2-5
NC (not connected)
Table 4: Pin assignment of the connector ST3 of the inner low side IGBT
Pin name
Pin function
ST3-1
+15V_T3
ST3-2
GND_T3
ST3-3
-8V_T3
ST3-4
PWM_T3
ST3-5
NC (not connected)
Table 5: Pin assignment of the connector ST4 of the outer low side IGBT
Pin name
Pin function
ST4-1
+15V_T4
ST4-2
GND_T4
ST4-3
-8V_T4
ST4-4
PWM_T4
ST4-5
DESAT4
Table 6: Pin assignment of the connector ST5 of the temperature output signal
Pin name
ST5-1
ST5-2
Pin function
NTC+
NTC-
Table 7: Pin assignment of the connector ST6
Pin name
ST6-1
ST6-2
Pin function
NCLAMP (IGBT neutral clamping point)
AC_OUT (IGBT AC output)
The optional connector ST6 can be used to measure the voltage between the AC-output and the neutral
point of the DC-Link capacitor.
7
Application Note AN 2011-04
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
4
V1.0 June 2011
Functionality of the board
The MA3L080E07_EVAL adapter board is a complementary part of the evaluation kit to drive one 3-Level
TM
IGBT module as shown in Figure 5. The adapter board should be pressed on the EconoPACK 4.
F3L020E07-F-P_EVAL
MA3L080E07_EVAL
F3L300R07PE4
Figure 5: Mounting sequence of the Evaluation Kit
The IGBT module is not a part of this evaluation kit. The needed IGBT module can be purchased separately.
4.1
Power supply
The MA3L080E07_EVAL as represented in Figure 6 needs four external -8V/+15V isolated power supplies
when it is driven by F3L020E07-F-P_EVAL. If the MA080E07 adapter board is not used in conjunction with
the F3L020E07-F-P_EVAL, it can be supplied with an isolated power supply providing max. ±20V.
The input PWM voltage level should be selected according to the power supply voltage level. If an
asymmetrical supply voltage of -8V/+15V is applied, the PWM signal should not exceed +15V and should not
be lower than -8V.
The voltage sources are applied to the corresponding driver channels using the connectors ST1, ST2, ST3
and ST4.
Figure 6: Principle diagram of the MA3L080E07_ EVAL
8
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
Application Note AN 2011-04
V1.0 June 2011
Figure 7 gives hints about the power as a function of the switching frequency. This power is needed to drive
TM
one IGBT of an F3L300R07PE4 EconoPACK 4 3-Level module equipped with the adapter board at
Tcase = 125°C and Tamb = 25°C. The adapter board is supplied with -8V/+15V.
Figure 7: Power consumption of one IGBT of the 3-Level leg
4.2
Booster
Figure 8 shows the booster circuit where two complementary pairs of transistors are used to amplify the input
PWM signal. This allows to drive IGBTs that need more current than the driver IC can deliver. Two NPN
transistors are used for turning-on the IGBT and two PNP transistors for turning-off the IGBT.
The transistors are dimensioned to provide enough peak current to drive all EconoPACK™ 4 3-Level IGBT
modules.
Figure 8: Schematic details of the output stage for a single IGBT driver
Gate resistors are connected between the booster stage and the IGBT module’s gate terminals. These
resistors should have a suitable rating for repetitive pulse power to avoid degradation.
9
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
4.3
Application Note AN 2011-04
V1.0 June 2011
VCE monitoring for short circuit detection; active clamping function
The short circuit protection of the outer high side and outer low side IGBTs are based on the monitoring of
the VCE voltage for the corresponding IGBT using the active clamp feature as represented in Figure 9. If the
IGBT conducts a current a few times higher than the nominal value, the transistor desaturates and the
voltage across the device increases. This behavior can be used for short circuit detection and to turn-off of
the IGBT. The short circuit withstand time for Infineon IGBT modules is 10µs. During this time the short
circuit needs to be detected and the IGBT has to be turned off without exceeding its maximum blocking
voltage.
When the MA3L080E07_EVAL is connected to a F3L020E07-F-P_EVAL driver board, each 1ED020I12-F
Coreless Transformer driver IC of the outer high side and outer low side IGBTs detects and handles the
short circuit separately.
Figure 9: Desaturation protection and active clamping diodes
Active clamping is a technique which keeps transient overvoltage below the critical limits when the IGBT
4
turns off. The standard approach for active clamping is to use a TVS diodes connected between the
auxiliary collector and the gate of an IGBT module. When the Collector-Emitter voltage exceeds the diodes
breakdown voltage the diodes current sums up with the current from the driver output. Due to the increased
gate-emitter voltage the transistor is held in an active mode and the turn-off process is prolonged. The dIC/dt
slows down which results in a limited voltage overshoot. Avalanche diodes conduct high peak currents
during the time in which the clamping is actively limiting the overvoltage.
A typical turn-off waveform of a F3L300R07PE4 module at room temperature without overvoltage limiting
function can be seen in Figure 10a. Figure 10b shows the waveform with the same load conditions as
Figure 10a with active clamping function.
a)
b)
Figure 10: a) turn-off without active clamping
4
TVS Transient voltage suppressor diode
10
b) with active clamping function
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
4.4
Application Note AN 2011-04
V1.0 June 2011
Maximum switching frequency
The switching frequency on the adapter board is limited either by the maximum output power of the driver
power supply or by the maximum temperature of the PCB due to the power losses in the external gate
resistors. These power losses in the gate resistors depend on the IGBT gate charge, gate voltage magnitude
and on the switching frequency of the IGBT. Due to the power losses in the external gate resistors, heat will
be generated, which leads to an increase of the PCB temperature in the neighborhood of these resistors.
This temperature must not be higher than the maximum working temperature of the PCB, i.e. 105°C for a
standard FR4 material.
The calculation of the power losses in the gate resistors can be done by utilizing equation (1):
Pdis  P( REXT )  P( RINT )  Vout  f s  QG
(1)
where:
Pdis
= dissipated power
P(REXT) = dissipated power external gate resistors
P(RINT) = dissipated power internal gate resistor
ΔVout = voltage magnitude at the driver output
fs
= switching frequency
QG
= IGBT gate charge for the given gate voltage range
The complete gate resistor consists of the internal gate resistor together with an external gate resistor and
due to that, a part of the IGBT drive power losses will be dissipated directly in the PCB, whereas the other
part of the losses will be dissipated to the ambient air. The ratio of the losses dissipated internally P(RINT)
and externally P(REXT) corresponds directly to the ratio of the mentioned R INT and REXT resistors.
Corresponding to -8/+15V operation the datasheet value of QGE needs to be reduced by 20%.
Due to the PCB temperature criteria the power dissipated in external gate resistors P(REXT) has to be
considered for the thermal design.
Figure 11 shows the PCB board temperature around the gate resistors depending on the switching
frequency under following conditions: Tcase = 125°C, Tamb = 25°C, VGE = -8V/+15V.
Figure 11: Local temperature development of the MA3L080E07_EVAL adapter board
11
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
5
Application Note AN 2011-04
V1.0 June 2011
Paralleling
In contrast to the operation of one single IGBT, where the working point is relatively easy to set up, the
switching of paralleled IGBT modules on the same operation point is not trivial. This can be explained by the
fact that the IGBTs have a certain variation in their characteristics. A direct consequence of this is a slight
current imbalance between the IGBTs. The biggest challenge is to minimize the deviation of the leg current
to achieve highly efficient systems and an improved reliability.
Two main factors have a primary role in the current maldistribution:
- the difference between the impedance of each leg of the paralleled setup
- and the difference in the output voltages of the individual leg of the paralleled setup
5.1
Static current imbalance
The static current imbalance can be caused due to:
- the variation of the collector-emitter-voltage of each leg of the paralleled setup
- the variation of the resistance of the main current path
5.2
Dynamic current imbalance
The dynamic current imbalance can be caused by
- the variation of the transmission characteristics caused by the different VGEth of each IGBT
- the variation of the impedance of the main current path
- the stray inductance of the internal and external commutation path of the IGBT module
- the IGBT driver output resistance in the paralleled legs
- the transfer characteristic IC = f(VGE)
5.3
Paralleling with MA3L080E07_EVAL
The MA3L080E07_EVAL was designed primarily to work with the evaluation driver board
3FL020E07-F-P_EVAL, which allows the parallel connection of up to three modules, each equipped with one
MA3L080E07 adapter board as represented in Figure 12a. In case of paralleling, the driver board doesn’t
need to be plugged into the complementary adapter board. The connection from the driver to the adapter
boards is done utilizing the connectors on the top side of the driver board as shown in Figure 12b.
a)
b)
Figure 12: a) Principle of parallel connection, b) Photo of the setup
Figure 12b shows a parallel connection of three 3-Level IGBT modules. The wires to connect the driver to
the adapter boards should have the same length to avoid differences of signal run time between the gates of
the three legs. Star connection of the IGBTs improves the reduction of cross flow in the auxiliary emitter
paths after the switching sequence. The MA3L080E07_EVAL boards are equipped with 4R7 resistors in the
auxiliary emitter path and other power supply lines (-8V / +15V) to reduce the current cross flow between the
units of the paralleled circuits.
12
Application Note AN 2011-04
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
V1.0 June 2011
The MA3L080E07 adapter board is equipped with 4R7 decoupling resistors in the power supply lines. This
avoids currents in the emitter path between the paralleled modules.
Figure 13a gives a hint about the balancing current flowing in the emitter paths when MA3L080E07_EVAL is
equipped with 0R decoupling resistance. Balancing currents of up to 5A can be measured after the switching
sequences. With a standard equipped adapter board, the balancing current is reduced to a few mA as
represent in Figure 13b.
a)
b)
Figure 13: Current distribution in the auxiliary emitter paths
a) With 0R as decoupling resistor
b) With 4R7 as decoupling resistor
Figure 14 shows the turn-on and turn-off behavior of 3 IGBT modules in parallel and their current sharing on
the AC terminals.
a)
b)
Figure 14: Current distribution on the AC terminals of 3 parallel F3L300R07PE4 modules
a) Turn-on
b) Turn-off
The Eon and Eoff values measured with a gate resistance Rgon = Rgoff = 2R and at ambient temperature of
25°C are listed in 0.
Datasheet values of Eon and Eoff for F3L300R07PE4: Eon = 1.5mJ; Eoff = 14mJ
Table 8: Overview of Eon and Eoff of three paralleled F3L300R07PE4 modules
Device under Test
DUT1
DUT2
Eon [mJ]
2.3
3.5
Eoff [mJ]
14.28
13.24
DUT3
4
14
Compared to the datasheet values, the measured Eoff values are similar. The variation in Eon is higher and in
general higher than the datasheet values. Nevertheless the influence of Eoff is dominating.
13
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
6
Application Note AN 2011-04
V1.0 June 2011
Base plate temperature monitoring by internal NTC resistor
The MA3L080E07_EVAL adapter board offers to monitor the IGBT case temperature. If the
MA3L080E07_EVAL Adapter board is equipped with F3L020E07-F-P_EVAL driver board, no further effort
would be necessary for the acquisition of the temperature signal from the NTC. For driver solutions different
to
F3L020E07-F-P_EVAL driver board, an external circuit would be required for the acquisition of
the NTC signal. Electronic acquisition of the NTC temperature requires an external circuit and some
examples of circuits and details of the NTC characteristics are described in the application note: AN2009-10.
Notice: This temperature measurement is not suitable for short circuit detection or short term overload and
may be used to protect the module from long term overload conditions or malfunction of the cooling system.
An electrical isolation must be assured between the NTC input signal (IGBT side) and the NTC output control
signal.
7
Schematics and Layouts
To meet the individual customer requirements and to make the Evaluation Adapter Board simple for
development or modification, all necessary technical data like schematic, layout and components are
included in this chapter.
7.1
Schematics
Figure 15 to Figure 18 depict the driving circuit of the IGBTs.
Figure 15: Driving circuit of the outer high side IGBT
14
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
Figure 16: Driving circuit of the inner high side IGBT
Figure 17: Driving circuit of the inner low side IGBT
15
Application Note AN 2011-04
V1.0 June 2011
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
Application Note AN 2011-04
V1.0 June 2011
Figure 18: Driving circuit of the outer low side IGBT
Figure 19: Pin description of the connectors of the MA3L080E07_EVAL
16
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
7.2
Layouts
Figure 20: Component placement, top side
Figure 21: Component placement, bottom side
Figure 22: Top- Layer
17
Application Note AN 2011-04
V1.0 June 2011
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
Figure 23: Layer 2
Figure 24: Layer 3
Figure 25: Bottom- Layer
18
Application Note AN 2011-04
V1.0 June 2011
Application Note AN 2011-04
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
8
V1.0 June 2011
Bill of Material of MA3L080E07_EVAL
The bill of material includes a part list as well as assembly notes.
The tolerances for resistors should be less or equal to ±1 %, for capacitors of the type C0G less or equal to
±5 % and for capacitors of the type X7R less or equal to ±10 %.
Type
Value
Package
QTY
Name Part
Manufacturer
Resistor
1R8
R-EU_1206
2
R1, R2
-
-
-
Resistor
Puls resistors
optional
R-EU_1206
24
R107,R108, R109, R110, R111, R112,
R206, R207, R208, R209, R210,
R211, R306, R307, R308, R309,
R310, R311, R407, R408, R409,
R410, R411, R412
Resistor
4R7
R-EU_1206
12
R102, R105, R106, R201, R204,
R205, R301, R304, R305, R402,
R405, R406
Resistor
1k
R-EU_0603
2
R101, R401
Resistor
39R
R-EU_0805
8
R103, R104, R202, R203, R302,
R303, R403, R404
-
Resistor
10k
R-EU_0805
4
R115, R214, R314, R415
-
Capacitor
4µ7/25V/X7R
C1206
16
C102, C103, C105, C106, C202,
C203, C205, C206, C302, C303,
C305, C306, C402, C403, C405, C406
Murata
Diode
ES1D
DO214AC
6
D1, D2, D5, D6, D7, D8
Diode
P6SMB480C
SMB
2
D3, D4
Diode
STTH112U
SOD6
2
D101, D401
-
Diode
BAT165
SOD323R
8
D103, D104, D201, D202, D301,
D302, D402, D403
Infineon
Bipolar
transistor
ZXTN2010Z
SOT89
8
T101, T102, T201, T202, T301, T302,
T401, T402
Diodes
Bipolar
transistor
ZXTP2012Z
SOT89
8
T103, T104, T203, T204, T303, T304,
T403, T404
Diodes
Connector
MOLEX
2223-2051
PITCH KK
4
ST1, ST2, ST3, ST4
Molex
Connector
MOLEX
2223-2021
PITCH KK
1
ST5
Molex
Connector
MOLEX
2223-2021
PITCH KK
N.C
ST6
Molex
19
Evaluation Adapter Board for
EconoPACKTM 4 3-Level Modules
9
Application Note AN 2011-04
V1.0 June 2011
How to order the Evaluation Adapter Board
Every Evaluation Adapter Board has its own IFX order number and can be ordered via your Infineon Sales
Partner.
Information can also be found at the Infineon’s Web Page: www.infineon.com
CAD-data for the board described here are available on request. The use of this data is subjected to the
disclaimer given in this AN. Please contact: [email protected]
IFX order number for MA3L080E07_EVAL:
IFX order number for F3L020E07-F-P_EVAL:
36293
36294
10
Literature
[1]
Zhang Xi, Uwe Jansen, Holger Rüthing : ‘IGBT power modules utilizing new 650V IGBT3 and Emitter
Controlled Diode3 chips for 3-Level converter’ ISBN: 978-3-8007-3158-9 Proceedings PCIM Europe
2009 Conference
[2]
AN2009-10 : ‘Using the NTC inside a power electronic module’, is available on Infineon’s website
[3]
Evaluation Driver Board for EconoPACK
TM
4 3-Level modules AN2011-03
20