AN2019-22
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
About this document
Scope and purpose
The gate driver evaluation board EVAL-1ED3122Mx12H with the 1ED3122MU12H or 1ED3122MC12H gate driver
IC demonstrates the functionality and key features of the Infineon EiceDRIVER™ Compact gate driver ICs.
The boards contain a short circuit protection which is described in more detail in the key feature section of this
document.
Details about the EiceDRIVER™ Compact 1ED3122MU12H or 1ED3122MC12H can be found at our product pages
at https://www.infineon.com/gd or the product search.
The design of the EVAL-1ED3122Mx12H was performed with respect to the environmental conditions described
in this document. The design was tested as described in this document, but not qualified regarding
manufacturing, lifetime or over the full range of ambient operating conditions. The boards provided by Infineon
are not subject to full production test.
Evaluation boards are not subject to the same procedures as regular products regarding Returned Material
Analysis (RMA), Process Change Notification (PCN) and Product Discontinuation (PD). Evaluation boards are
intended to be used under laboratory conditions and by trained specialists only.
Intended audience
•
•
•
Engineers who want to learn how to use the Infineon EiceDRIVER™
Experienced design engineers designing circuits with Infineon EiceDRIVER™, IGBT and CoolSiC™ MOSFET
Design engineers designing power electronic devices, like inverters
Table of contents
Table of contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1
1.1
1.2
1.3
Electrical description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Key features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Absolute maximum ratings, operating conditions and supply voltages . . . . . . . . . . . . . . . . . . . . . . . . 2
Start-up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.4
1.5
Overcurrent protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4
Connectors and pin assignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5
2
Schematics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
3
PCB layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
4
Bill of material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Disclaimer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Application Note
www.infineon.com
Please read the Important Notice and Warnings at the end of this document
v1.0
2019-11-06
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
1 Electrical description
1
Electrical description
1.1
Key features
The evaluation board EVAL-1ED3122Mx12H is intended for the product feature evaluation of the Infineon
EiceDRIVER™ Compact 1ED3122MU12H or 1ED3122MC12H in an application circuit. The key elements of the
board and the product are listed here.
•
Evaluation board in half-bridge configuration with two gate driver ICs to drive power switches such as IGBTs
and SiC MOSFETs. The switch type can be freely chosen as seen in Figure 1
•
Additional gate driver IC for isolated over-current feedback signal from high voltage side to logic control
side
•
Fast operational amplifier used as comparator for over-current detection
Figure 1
EVAL-1ED3122Mx12H top view
The board has a size of 85 x 55 x 15 mm³ without any power switch assembled.
This board is best suited for so-called double-pulse testing. However, it requires additional considerations on
thermal and power load for continuous operation. An additional high-voltage DC blocking capacitor at the highvoltage supply is recommended.
The low-voltage interface can be controlled by a pulse generator, a microcontroller or other digital circuits.
For safe operation, a fast over-current detection and protection circuit is implemented with a galvanically
isolated feedback path to the low-voltage input side. The input side flip-flop latches the over-current event
information. This circuit will report the fault and turn off both gate driver ICs. The S1 button, also labeled with
RESET, clears the flip-flop to enable the gate driver ICs again.
1.2
Absolute maximum ratings, operating conditions and supply
voltages
The selected components on this evaluation board as well as the gate driver ICs have maximum ratings and
operating conditions to avoid damaging the individual parts and the evaluation board overall.
Table 1
Absolute maximum ratings
Pin/parameter
name
Abs. Max.
Unit
Note
+15V_IN
-0.2 … 20
V
input, support supply voltage
VCC1
-0.2 … 5.3
V
input, gate driver IC supply voltage
Application Note
2
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AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
1 Electrical description
Table 1
Absolute maximum ratings (continued)
Pin/parameter
name
Abs. Max.
Unit
Note
FAULT
-0.2 … VCC1 + 0.2
V
output, digital signal
RST
-0.2 … VCC1 + 0.2
V
input, digital signal
IN_HS
-0.2 … VCC1 + 0.2
V
input, digital signal
IN_LS
-0.2 … VCC1 + 0.2
V
input, digital signal
VCC2_HS,VCC2_LS
-0.2 … 40
V
overall isolated secondary supply with reference to
VEE2_HS/VEE2_LS
VCC2_HS,VCC2_LS
-0.2 … 25
V
positive secondary supply voltage with reference to
GND2_HS/GND2_LS
GND2_HS,GND2_LS
-0.2 … 25
V
gate reference supply pin with reference to VEE2_HS/
VEE2_LS
V-HV
-0.2 … 1200
V
input, high-voltage supply, for voltages above 42 V,
special high voltage lab environment is strongly
recommended
Phase peak current 25
A
phase peak current for double pulse tests
tpulse
100
µs
maximum ON pulse length for double-pulse tests
fsw
100
kHz
maximum switching frequency for continuous
operation, careful consideration of power dissipation
required
The PCB assembly is optimized for a VCC1 supply voltage of 3.3 V. For higher supply voltages, adjustment to the
current limiting resistors of the status LEDs is required.
Table 2
Operating conditions and supply voltages
Pin name
Min.
Typ.
Max.
Unit
Note
+15V_IN
15.5
16
16.5
V
input, support supply voltage
VCC1
3.2
3.3
3.4
V
input, gate driver IC supply voltage
FAULT
-0.1
3.3
VCC1+ V
0.1
output, digital signal
RST
-0.1
3.3
VCC1+ V
0.1
input, digital signal
IN_HS
-0.1
3.3
VCC1+ V
0.1
input, digital signal
IN_LS
-0.1
3.3
VCC1+ V
0.1
input, digital signal
VCC2_HS,VCC2_LS
12
15
30
V
overall isolated secondary supply with reference to
VEE2_HS/VEE2_LS
GND2_HS,GND2_LS
0
15
V
gate reference supply pin with reference to VEE2_HS/
VEE2_LS
Application Note
3
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AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
1 Electrical description
Table 2
Operating conditions and supply voltages (continued)
Pin name
Min.
V-HV
25
1.3
Typ.
Max.
Unit
Note
600
V
input, high voltage supply, for voltages above 42 V,
special high voltage lab environment is strongly
recommended
Start-up
Follow the steps below to set up, power up and perform first evaluations with the board.
Prerequisites
•
•
•
•
Assemble fitting power switches at the location Q1 and Q2, e.g. IKQ75N120CH3 IGBTs
Assemble an external high-voltage DC capacitor (> 100 µF) between J1-1/2 (V-HV) and J3-2 (HV_GND)
Have low-voltage power supplies ready for input support and logic supply (+15V_IN, VCC1)
Have isolated low-voltage power sources ready for gate driver output supply (VCC2_LS, VCC2_HS, GND2_LS,
GND2_HS, VEE2_LS and VEE2_HS)
•
Have a high-voltage power supply ready for HV-DC between J1-1/2 (V-HV) and J3-2 (HV_GND)
•
Have an inductive load for double-pulse tests ready
•
Have a dual channel PWM generator ready for half-bridge PWM input
To adapt the circuit to the application requirements, resistor or capacitor values can be changed to optimize the
performance.
Power-up sequence
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
Supply +15V_IN at connector J13.2 with +16 V and connect supply GND to connector J13.1
Supply VCC1 at connector J6.2 with +3.3 V and connect supply GND to connector J6.1
The red LED D7 will turn on
Supply both secondary gate driver supplies with individual power sources at VCC2_HS, GND2_HS, and
VEE2_HS at connector J4, and VCC2_LS, GND2_LS and VEE2_LS at connector J5 according to the
assembled power switch needs
The green LED1 will turn on
Push S1 to reset the error flip-flop
The red LED D7 will turn off and green LED D6 will turn on
Connect the digital PWM generator to the digital interface connectors J7 and J8 labeled with IN_HS and
GND as well as IN_LS and GND
Connect the high-voltage supply to connector J1.1 or J1.2 and HV_GND to J3.2.
Connect one end of the inductive load to J2.1 and the other end according to the double-pulse
requirements to either J1.1 or J3.2 (low side or high side testing)
The board is now ready for double-pulse evaluation
1.4
Overcurrent protection
An overcurrent protection is implemented to protect the board and components against high current. The
current is determined by measuring the voltage across the shunt resistor R19. This is available at the two test
points TP14 and TP16.
The detection circuit measures the voltage across R19, sends the signal through a low pass filter R18 and C18
and compares it to a reference voltage with the comparator U5. The reference voltage is defined by the voltage
divider R12 and R20. The trip point is at approx. 32 A and can be adapted to application requirements by
changing R19 and/or adapting the reference voltage divider R12 and R20.
Application Note
4
v1.0
2019-11-06
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
1 Electrical description
The output signal is transferred with U3 to the low voltage domain to trigger the flip-flop and store the
overcurrent event. Once the flip-flop is triggered, it turns off both gate driver ICs by the ENABLE signal. In
addition, it reports the overcurrent event to the digital interface connector as FAULT signal and turns the LED7
on.
To return to normal operation, S1 needs to be pushed to reset the flip-flop. As a feedback, LED7 turns off and
LED6 turns back on again.
1.5
Connectors and pin assignment
The following table describes connectors and their pin assignments on the PCB.
Table 3
Connectors and pin assignment
Connector
Pin
Marking/
function
Note
J1
1, 2
V-HV
High voltage power supply
J2
1, 2
PHASE
J3
1
SENSE
J3
2
HV_GND
J4, J9
1
VEE2_HS
High side negative gate driver supply
J4, J9
2
GND2_HS
High side gate driver supply reference
J4, J9
3
VCC2_HS
High side positive gate driver supply
J5, J10
1
VEE2_LS
Low side negative gate driver supply
J5, J10
2
GND2_LS
Low side gate driver supply reference
J5, J10
3
VCC2_LS
Low side positive gate driver supply
J6, J7, J8, J11, J12, J13
1
GND
Logic side ground reference
J6, J12
2
VCC1
Logic side supply voltage, 3.3 V or 5 V
J7
2
IN_HS
Logic PWM input high side gate driver
J8
2
IN_LS
Logic PWM input low side gate driver
J11
2
+15V
15 V for external power supply without protection
diode
J11
3
PWM_PSU
PWM output for external power supply from J14.9
J13
2
+15V_IN
15 V input supply voltage for external power supply
J14
1, 2
n.c.
not connected
J14
3
VCC1
Logic side supply voltage, 3.3 V or 5 V
J14
4
GND
Logic side ground reference
J14
5
RST
Reset input for overcurrent flip-flop, connected to S1
J14
6
FAULT
Fault feedback signal
J14
7
IN_HS
Logic PWM input high side gate driver
J14
8
IN_LS
Logic PWM input low side gate driver
J14
9
PWM_PSU
PWM input for external power supply to J11.3
Application Note
5
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Evaluation board description
2 Schematics
Table 3
Connectors and pin assignment (continued)
Connector
Pin
Marking/
function
Note
J14
10
+15V
15 V for external power supply without protection
diode
2
Schematics
The schematics of the evaluation board are separated into the following parts:
•
Gate driver ICs with surrounding circuit
•
Overcurrent detection
•
Overcurrent status display
•
Interfaces with connectors and reset switch
Application Note
6
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2019-11-06
7
ENABLE
IN_LS
ENABLE
IN_HS
R4
TP8
TP11
TP15
ENABLE R16 0
IN_LS
TP4
TP7
R11 0
ENABLE R7
0
IN_HS
TP1
C14
0.001uF
50V
C6
0.001uF
50V
C7
0.1uF
50V
VCC1
4
3
2
1
GND
R17
N.A.
VCC1
C15
0.1uF
50V
VCC1
4
3
2
1
GND1
IN-
IN+
VCC1
GND1
IN-
IN+
VCC1
U4
Gate Driver
GND
R8
N.A.
VCC1
U2
5
6
7
8
VEE2
CLAMP
OUT
VCC2
5
6
7
8
1ED3122MC12H
VEE2
CLAMP
OUT
VCC2
1ED3122MC12H
VCC2_LS
VEE2_HS
GND2_HS
R9
4R7
C17
4.7uF
25V VEE2_LS
C16
TP13
4.7uF
25V
VEE2_LS
GND2_LS
R13
10
AS SHORT AS POSSIBLE
D2
ES2AA-13-F
VCC2_LS
C9
4.7uF
25V VEE2_HS
TP10
R3
4R7
R5
10
AS SHORT AS POSSIBLE
C8
TP6
4.7uF
25V
TP3
VCC2_HS
D1
ES2AA-13-F
VCC2_HS
High Voltage HS Domain
G
N.A.
C5
R19
0.003
SENSE
PHASE
V-HV
HV_GND
TP16
TP14
N.A.
C12
G
Q2
IKQ75N120CH3
GND2_LS
TP12
TP9
GND2_HS
TP5
TP2
Q1
IKQ75N120CH3
C
E
Application Note
C
Figure 2
E
Low Voltage Domain
J2
MKDSN 1,5/ 2-5,08
1
2
1
2
MKDSN 1,5/ 2-5,08
J3
LOWSIDE
HIGHSIDE
C4
0.25uF
900V
J1
MKDSN 1,5/ 2-5,08
1
2
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
2 Schematics
Schematic of gate driver ICs and surrounding circuits
Gate driver circuit with optional external input filter, output gate resistors and CLAMP connection.
v1.0
2019-11-06
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
2 Schematics
Voltage Regulator
High Voltage LS Domain
Low Voltage Domain
U1
R1
10k
8
N.C
N.C.
7
EN
RO
6
D
5
3
4
GND
PAD
4.7uF
25V
OUT
IN
2
C2
0.1uF
50V
C3
10uF
25V
R2
1k
TLS810D1EJV50
LED1
Green
VCC2_LS
2
R6
100
5V
1
C1
PAD
1
HV_GND
OC Comparator
C10
0.1uF
50V
R12
51k
R10
10k
C11
0.1uF
50V
HV_GND
R14
6
5
1M
SENSE R18
U5
4
V+
V-
2
1ED3122MC12H
VCC2
8
IN+
OUT
7
3
IN-
CLAMP
6
4
GND1
VEE2
5
+15V
C13
0.1uF
50V
GND GND
3
1k
VCC1
1
R15
4k7
FAULT
U3
1
Figure 3
C19
0.001uF
50V
FAULT
C18
100pF R20
50V
1k
2
LT6200CS6-10#TRMPBF
Schematic of overcurrent detection circuit
Overcurrent comparator with additional gate driver IC for isolated signal transmission and supporting voltage
regulator.
Application Note
8
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2019-11-06
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
2 Schematics
Status LED
C20
0.1uF
50V
U6C
VCC1
VCC1
8
VCC
4
GND
SN74LVC2G132DCUR
R21
10k
U6A
GND
SN74LVC2G132DCUR
RST
RST
1
7
2
R22
47k
D3
BAT165
5
3
FAULT
FAULT
ENABLE
6
C23
100pF
50V
1
R24
270
GND
D7
Red
2
D6
Green
2
D5
BAT165
Figure 4
R23
270
1
U6B
SN74LVC2G132DCUR
GND
GND
Schematic of overcurrent status indication
Fault signal and reset input of flip-flop including status LEDs.
Connectors
J4
J5
VCC2_HS
GND2_HS
VEE2_HS
3
2
1
EXTERN
3
2
1
VCC2_HS
GND2_HS
VEE2_HS
TSW-103-07-G-S
VCC2_LS
GND2_LS
VEE2_LS
J6
VCC2_LS
GND2_LS
VEE2_LS
TSW-103-07-G-S
J7
VCC1
GND
2
1
J8
2
1
VCC1
GND
TSW-102-07-G-S
IN_HS
GND
2
1
IN_HS
GND
TSW-102-07-G-S
IN_LS
IN_LS
TSW-102-07-G-S
GND
J9
J10
VCC2_HS
GND2_HS
VEE2_HS
3
2
1
PS MODUL
VCC2_HS
GND2_HS
VEE2_HS
SSW-103-01-G-S
VCC2_LS
GND2_LS
VEE2_LS
J12
VCC2_LS
GND2_LS
VEE2_LS
SSW-103-01-G-S
2
1
SSW-102-01-G-S
+15V
PWM_PSU
+15V
SSW-103-01-G-S
C21
4.7uF
25V
+15V_IN
2
1
3 PWM_PSU
2
1
VCC1
D4
J13
SUPPLY IN
J11
3
2
1
C22
4.7uF
25V
+15V
BAS3010B-03W
GND
GND
TSW-102-07-G-S
GND
J14
VCC1
C24
1uF
50V
GND
Figure 5
VCC1
RST
RST
IN_HS
IN_HS
C25
PWM_PSU
PWM_PSU
0.1uF
50V
1
3
5
7
9
2
4
6
8
10
FAULT
IN_LS
+15V
1
2
FAULT
IN_LS
+15V
S1
3
4
RST
RST
7914G-1-000E
GND
N2510-6002-RB
GND
GND
Schematic of connectors and reset switch
Interface connectors and reset button.
Application Note
9
v1.0
2019-11-06
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
3 PCB layout
3
PCB layout
The layout from this basic schematic is intended as a starting point for developing more complex application
circuits. The evaluation board has a two-layer PCB with top and bottom layer. Most components are assembled
at the top layer.
COJ12
PAFID201
COC21
COFID2 COD4
PAD401
PAJ1201 PAJ1202
PAC2102PAC2101
PAD402
COJ13
COTP1
PAJ1302
COC6
PAC602
PAC601 PAU201
COR4
PAR401
PAR402 PAU202
PAR701
PAR702 PAU203
COR7
PAJ1301
COJ8
PAJ1406 PAJ1405
COC25 COC24
PAJ1404 PAJ1403
PAJ1402 PAJ1401
PAC2502 PAC2401
PAJ802
PAJ801
COC15
COTP8
PAC2501 PAC2402 COJ6
PAS104
PAS103
COFID1
PAQ10G
PAQ10C
PAD101 PAR501 PAR502 COR5
PAD102 PAR301 PAR302 COR3
COC9
COD1
PAQ10E
PAJ102
COQ1
PAC401
PAJ101
COJ1
COC4
PAS101
PAS102
COD7
PAR901 PAR902 COR9 COR19
PATP1001
PAD201 PAR1301 PAR1302 COR13 COQ2
PAU406
PAC2002
COC20
PAR2202
COU6
COR23 PAC2302
COC22 PAC2202PAC2201
PAJ1101 PAJ1102 PAJ1103
PAR2201
PAD502
COC23 COD5
PAU405
COU4
COTP10 COD2
PAQ20G
PAC1702
PAC1701
COC17
PAU106
COR15
PAU305
PAU306
PAU303
PAR1501 PAR1502
PAU307
PAU302
PAU308
PAU301
PAD302
COR2 COD3
PAC1302 PAC1301
PAU304
COU3
COC13
COJ11
PAR1902
PAQ20C
PAJ302
PAQ20E
PAJ301
COJ3
PAU105
PAD301
PAJ201
COJ2
PAR1901
PAU407
PAU404
COTP9 PATP901COC12PATP1301 COTP13
COU1
PAD602 PAD601 PAU605PAU606 PAU607PAU608 PAC2001
PAR2301 PAR2302 PAC2301 PAD501
PAD702 PAD701 PAU604PAU603 PAU602PAU601
PAC402
PATP1201COTP12
PAU408
COTP11
COR24 COR21
PAR2401 PAR2402 PAR2101 PAR2102
COD6
PAU107
PAC1201PAC1202
PAU104
PAU10PAD
PAU108
PAU103
PAU102
COR1
PAU101
PAR101
PAC201COC2
PAC202 PAC102COC1
PAC101
PAR102
PAR602
PAC1101 PAC1102 PAJ501 PAJ502 PAJ503
COC11 PAJ1001 PAJ1002 PAJ1003
PAC302
COC3
COTP14PATP1601 PATP1401
COTP16
COR2 COLED1 PAC1901
COC19
PAC1902
PAR201 PALED101 PALED102
COR20
PAR2002
PAR2001
COC18
COR18
PAR1801
PAC301 PAR202 PAC1802
PAC1801 PAR1802
COR6
PAR1201
COR12PAR1202
PAR601
COJ5
COJ10
PAU504
PAU505
PAU506
PAU503
PAU502
PAU501
PAFID301
COPAR1401R14 COU5COFID3
PAR1402
COC10
COR10
PAR1002
PAC1001 PAC1002 PAR1001
Assembly drawing top side PCB
COJ12
PAFID201
COC21
COFID2 COD4
PAD401
PAJ1201 PAJ1202
PAC2102PAC2101
PAD402
COJ13
COJ7
PAJ1302
PAC802
PAC801
PATP101 PAC702 PAC701
COC6
PAC602
PAC601 PAU201
COR4
PAR401
PAR402 PAU202
PAR701
PAR702 PAU203
COR7
PAJ1301
PAU207
PAU206
PAU204
PATP401
PAJ702
PAJ701
PAU208
PAU205
COU2
COTP4
COTP2PATP201 PATP601COTP6
PAFID101
COC5PAC502
PAC501
COFID1
PATP301 PATP501
COTP3
COTP5
PAQ10G
PAQ10C
PAC902
PAC901
PAD101 PAR501 PAR502 COR5
PAD102 PAR301 PAR302 COR3
COC9
COD1
PAQ10E
PAJ102
COQ1
PAC401
PAJ101
COJ1
COC4
PAJ202
PAJ14010 PAJ1409
COJ8
PAJ1408 PAJ1407
PAJ1406 PAJ1405
COC25 COC24
PAJ1404 PAJ1403
PAJ1402 PAJ1401
PAC2502 PAC2401
PAJ802
PAJ801
COC15
COTP8
PAC2501 PAC2402 COJ6
PAJ601
COJ14
PAS101
COD7
PAS102
PAC2002
COC20
PAR2202
COR23 PAC2302
COC22 PAC2202PAC2201
PAJ1101 PAJ1102 PAJ1103
PAR2201
PAD502
COC23 COD5
PAU405
COU4
COTP10 COD2
PAQ20G
PAC1702
PAC1701
COC17
COR2
PAU106
COR15
PAU305
PAU306
PAU303
PAR1501 PAR1502
PAU307
PAU302
PAU308
PAU301
PAD302
COD3
PAC1302 PAC1301
PAU304
COU3
COC13
COJ11
PAR1902
PAQ20C
PAJ302
PAQ20E
PAJ301
COJ3
PAU105
PAD301
PAJ201
COJ2
PAR1901
PAU407
PAU404
COTP9 PATP901COC12PATP1301 COTP13
COU1
PAD602 PAD601 PAU605PAU606 PAU607PAU608 PAC2001
PAR2301 PAR2302 PAC2301 PAD501
PAD702 PAD701 PAU604PAU603 PAU602PAU601
COU6
COD6
PAR901 PAR902 COR9 COR19
PATP1001
PAD201 PAR1301 PAR1302 COR13 COQ2
PAU406
PAU408
COTP11
COR24 COR21
PAR2401 PAR2402 PAR2101 PAR2102
PAS103
PAC402
PATP1201COTP12
COC16 PAD202
COC14
PAC1402
PAC1401 PAU401
PAR1101
PAR1102 PAU402
COR11
COR16
PAR1601 PAR1602 PAU403
PATP1101
PAS104
PAC1602
PAC1601
PATP801 PAC1502 PAC1501
PAJ602
COTP15PATP1501 PAR1701
PAR1702
COR17
COS1
COC8COJ9
PAJ901 PAJ902 PAJ903
COJ4
PAJ401 PAJ402 PAJ403
COC7
COTP1
COTP7PATP701 PAR801COR8
PAR802
PAU107
PAC1201PAC1202
PAU104
PAU10PAD
PAU108
PAU103
PAU102
COR1
PAU101
PAR101
PAC201COC2
PAC202 PAC102COC1
PAC101
PAR102
PAR602
PAC1101 PAC1102 PAJ501 PAJ502 PAJ503
COC11 PAJ1001 PAJ1002 PAJ1003
PAC302
COC3
COTP14PATP1601 PATP1401
COTP16
COR2 COLED1 PAC1901
COC19
PAC1902
PAR201 PALED101 PALED102
COR20
PAR2002
PAR2001
COC18
COR18
PAR1801
PAC301 PAR202 PAC1802
PAC1801 PAR1802
COR6
PAR1201
COR12PAR1202
PAR601
COJ5
COJ10
PAU504
PAU505
PAU506
PAU503
PAU502
PAU501
PAFID301
COPAR1401R14 COU5COFID3
PAR1402
COC10
COR10
PAR1002
PAC1001 PAC1002 PAR1001
PCB layer top
COJ12
PAFID201
COC21
COFID2 COD4
PAD401
PAJ1201 PAJ1202
PAC2102PAC2101
PAD402
COJ13
COJ7
COTP1
PAJ1302
PAC802
PAC801
PATP101 PAC702 PAC701
COC6
PAC602
PAC601 PAU201
COR4
PAR401
PAR402 PAU202
PAR701
PAR702 PAU203
COR7
PAJ1301
PAU207
PAU206
PAU204
PATP401
PAJ702
PAJ701
PAU208
PAU205
COU2
COTP4
COTP2PATP201 PATP601COTP6
PAFID101
COC5PAC502
PAC501
COFID1
PATP301 PATP501
COTP3
COTP5
PAQ10G
PAQ10C
PAC902
PAC901
PAD101 PAR501 PAR502 COR5
PAD102 PAR301 PAR302 COR3
COC9
COD1
PAQ10E
PAJ102
COQ1
PAC401
PAJ101
COJ1
COC4
PAJ202
PAJ14010 PAJ1409
COJ8
PAJ1408 PAJ1407
PAJ1406 PAJ1405
COC25 COC24
PAJ1404 PAJ1403
PAJ1402 PAJ1401
PAC2502 PAC2401
PAJ802
PAJ801
COC15
COTP8
PAC2501 PAC2402 COJ6
PAJ601
COJ14
PAS103
PAS101
PAS102
COD7
PAC2002
COC20
PAR2202
PAD702 PAD701 PAU604PAU603 PAU602PAU601
COR23 PAC2302
COC22 PAC2202PAC2201
PAJ1101 PAJ1102 PAJ1103
PAD502
COC23 COD5
COJ11
PAU405
COU4
COTP10 COD2
PAQ20G
PAC1702
PAC1701
COC17
PAR2201
COR2
PAU106
PAD302
COD3
COR15
PAU305
PAU306
PAU303
PAR1501 PAR1502
PAU307
PAU302
PAU308
PAU301
PAC1302 PAC1301
PAR1902
PAU304
COU3
COC13
PAQ20C
PAJ302
PAQ20E
PAJ301
COJ3
PAU105
PAD301
PAJ201
COJ2
PAR1901
PAU407
PAU404
COU1
PAD602 PAD601 PAU605PAU606 PAU607PAU608 PAC2001
PAR2301 PAR2302 PAC2301 PAD501
COU6
COD6
PAR901 PAR902 COR9 COR19
PATP1001
PAD201 PAR1301 PAR1302 COR13 COQ2
PAU406
PAU408
COTP11
COR24 COR21
PAR2401 PAR2402 PAR2101 PAR2102
PAC402
PATP1201COTP12
COC16 PAD202
COC14
PAC1402
PAC1401 PAU401
PAR1101
PAR1102 PAU402
COR11
COR16
PAR1601 PAR1602 PAU403
PATP1101
PAS104
PAC1602
PAC1601
PATP801 PAC1502 PAC1501
PAJ602
COTP15PATP1501 PAR1701
PAR1702
COR17
COS1
COC8COJ9
PAJ901 PAJ902 PAJ903
COJ4
PAJ401 PAJ402 PAJ403
COC7
COTP7PATP701 PAR801COR8
PAR802
Application Note
COTP5
COC16 PAD202
COC14
PAC1402
PAC1401 PAU401
PAR1101
PAR1102 PAU402
COR11
COR16
PAR1601 PAR1602 PAU403
PAJ601
COJ14
Figure 8
PAFID101
COC5PAC502
PAC501
PATP301 PATP501
COTP3
PAC902
PAC901
PAC1602
PAC1601
PATP801 PAC1502 PAC1501
PAJ602
PATP1101
Figure 7
PAU206
PAU205
COU2
COTP4
COTP15PATP1501 PAR1701
PAR1702
COR17
Figure 6
PAU207
PAU204
PATP401
PAJ702
PAJ701
PAU208
COTP2PATP201 PATP601COTP6
PAJ202
PAJ14010 PAJ1409
PAJ1408 PAJ1407
COS1
PAC802
PAC801
PATP101 PAC702 PAC701
COTP7PATP701 PAR801COR8
PAR802
COJ7
COC8COJ9
PAJ901 PAJ902 PAJ903
COJ4
PAJ401 PAJ402 PAJ403
COC7
PAU107
PAU108
PAU104
PAU10PAD
PAU103
PAU102
COTP13
PAC1201PAC1202
PATP1601 PATP1401
COTP9 PATP901COC12PATP1301
COR1
COR2 COLED1 PAC1901
PAC302
COC19
PAC1902
PAU101
PAR101
PAC201COC2
PAC202 PAC102COC1
PAC101
PAR102
PAR602
PAC1101 PAC1102 PAJ501 PAJ502 PAJ503
COC11 PAJ1001 PAJ1002 PAJ1003
COR6
PAR601
COJ5
COTP14
COTP16
PAR201 PALED101 PALED102
COR20
PAR2002
PAR2001
COC18
COR18
PAR1801
PAC301 PAR202 PAC1802
PAC1801 PAR1802
PAR1201 PAU504 PAU503 PAR1401
COU5COFID3
PAU505
PAU502
PAFID301
PAR1202 PAU506 PAU501 PAR1402
COC3
COJ10
COR12
COR14
COC10
COR10
PAR1002
PAC1001 PAC1002 PAR1001
PCB layer bottom
10
v1.0
2019-11-06
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
4 Bill of material
4
Bill of material
The BOM lists all components used for the PCB.
Table 4
Designator
Bill of material
Quantity Description
Manufacturer
Part number
C1, C8, C9, C16, 7
C17, C21, C22
CAP, CERM, 4.7µF, 25V, +/- 10%,
X7R, 0805
Samsung
CL21B475KAFNNNE
C2, C7, C10,
C11, C13, C15,
C20, C25
8
CAP, CERM, 0.1µF, 50V, +/- 10%,
X7R, 0805
Wurth Electronics
885012207098
C3
1
CAP, CERM, 10µF, 25V, +/- 10%,
X7R, 1206
Wurth Electronics
885012208069
C4
1
CAP, CERM, 0.25uF, 900V, 20%,
CeraLink
TDK
B58031I9254M062
C18, C23
2
CAP, CERM, 100pF, 50V, +/- 5%,
NP0, 0805
Wurth Electronics
885012007057
C19
1
CAP, CERM, 0.001µF, 50V, +/10%, X7R, 0603
Wurth Electronics
885012206083
C24
1
CAP, CERM, 1µF, 50V, +/- 10%,
X7R, 0805
Wurth Electronics
885012207103
D1, D2
2
Diode, 50 V, DO214AC
Diodes Incorporated
ES2AA-13-F
D3, D5
2
Diode, Schottky, 40 V, 0.75 A,
AEC-Q101, SOD-323
Infineon Technologies
BAT165
D4
1
Diode, Schottky, 30V, 1A, AECQ101, SOD-323
Infineon Technologies
BAS3010B-03W
D6, LED1
2
LED, Green, SMD
Lite-On
LTST-C190GKT
D7
1
LED, Red, SMD
Lite-On
LTST-C190CKT
J1, J2, J3
3
TERM BLOCK 2POS 5mm, TH
Phoenix Contact
MKDSN 1,5/ 2-5,08
J6, J7, J8, J13
4
Header, 100mil, 2x1, Gold, TH
Samtec
TSW-102-07-G-S
J9, J10, J11
3
Receptacle, 2.54mm, 3x1, Gold, Samtec
TH
SSW-103-01-G-S
J12
1
Receptacle, 2x1, 2.54mm, Gold, Samtec
TH
SSW-102-01-G-S
J14
1
Header (shrouded), 100mil, 5x2, 3M
Gold, TH
N2510-6002-RB
Q1, Q2
2
HIGH SPEED IGBT 1200V
Infineon Technologies
IKQ75N120CH3
R1, R10, R21
3
RES, 10k, 1%, 0.1W, 0603
Vishay-Dale
CRCW060310K0FKEA
R2, R18, R20
3
RES, 1k, 1%, 0.1W, 0603
Vishay-Dale
CRCW06031K00FKEA
R3, R9
2
RES, 4R7, 1%, 0.25W, 1206
Vishay-Dale
CRCW12064R70FKEA
R4, R7, R11, R16 4
RES, 0R, 1%, 0.1W, 0603
Vishay-Dale
CRCW0603000Z0EA
R5, R13
RES, 10R, 1%, 0.25W, 1206
Vishay-Dale
CRCW120610R0FKEA
Application Note
2
11
v1.0
2019-11-06
AN2019-22 EVAL-1ED3122Mx12H
Evaluation board description
4 Bill of material
Table 4
Bill of material (continued)
Designator
Quantity Description
Manufacturer
Part number
R6
1
RES, 100R, 1%, 0.1W, 0603
Vishay-Dale
CRCW0603100RFKEA
R12
1
RES, 51k, 1%, 0.1W, 0603
Vishay-Dale
CRCW060351K0FKEA
R14
1
RES, 1M, 1%, 0.1W, 0603
Vishay-Dale
CRCW06031M00FKEA
R15
1
RES, 4k7, 1%, 0.1W, 0603
Vishay-Dale
CRCW06034K70FKEA
R19
1
RES, 0R003, 1%, 3W, 2512
Bourns Inc.
CRE2512-FZ-R003E-3
R22
1
RES, 47k, 1%, 0.1W, 0603
Vishay-Dale
CRCW060347K0FKEA
R23, R24
2
RES, 270R, 1%, 0.1W, 0603
Vishay-Dale
CRCW0603270RFKEA
S1
1
Switch, Tactile, SPST-NO, 0.1A,
16V, SMT
Bourns
7914G-1-000E
U1
1
Linear Voltage Regulator 5V
Infineon Technologies
TLS810D1EJV50
U2, U3, U4
3
Single channel IGBT gate driver Infineon Technologies
IC in wide body package
1ED3122MC12H
U5
1
Rail-to-Rail Input and Output,
0.95nV/√Hz Low Noise Op Amp
Linear Technology
LT6200CS6-10#TRMPBF
U6
1
Dual 2-Input NAND Gate with
Schmitt-Trigger Inputs
Texas Instruments
SN74LVC2G132DCUR
Application Note
12
v1.0
2019-11-06
Trademarks
All referenced product or service names and trademarks are the property of their respective owners.
Edition 2019-11-06
Published by
Infineon Technologies AG
81726 Munich, Germany
© 2019 Infineon Technologies AG
All Rights Reserved.
Do you have a question about any
aspect of this document?
Email: erratum@infineon.com
Document reference
IFX-jqr1566804761252
IMPORTANT NOTICE
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given as a hint for the implementation of the product
only and shall in no event be regarded as a description
or warranty of a certain functionality, condition or
quality of the product. Before implementation of the
product, the recipient of this application note must
verify any function and other technical information
given herein in the real application. Infineon
Technologies hereby disclaims any and all warranties
and liabilities of any kind (including without limitation
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information given in this application note.
The data contained in this document is exclusively
intended for technically trained staff. It is the
responsibility of customer’s technical departments to
evaluate the suitability of the product for the intended
application and the completeness of the product
information given in this document with respect to such
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in question please contact your nearest Infineon
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