KIT8020CRD8FF1217P-1 - CREE

KIT8020CRD8FF1217P-1

CREE Silicon Carbide MOSFET

Evaluation Kit

User’s Manual

This document is prepared as a user reference guide to install and operate CREE evaluation

hardware.

Safety Note: Cree designed evaluation hardware is meant to be an evaluation tool in a

lab setting for Cree components and to be handled and operated by highly qualified

technicians or engineers. The hardware is not designed to meet any particular safety

standards and the tool is not a production qualified assembly

Subject to change without notice.

www.cree.com

2KIT8020CRD8FF1217P-1_UM Rev -

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1. Introduction

This Evaluation kit is meant to demonstrate the high performance of CREE 1200V SiC

MOSFET and SiC Schottky diodes (SBD) in the standard TO-247 package. It can be

easily configured for several topologies from the basic phase-leg configuration. The

evaluation (EVL) board can be used for the following purposes:

 Evaluate the SiC MOSFET performance during switching events and steady

state operation.

 Easily configure different topologies with SiC MOSFET and SiC diodes

 Functional testing with SiC MOSFET, for example double pulse test to

measure switching losses (Eon and Eoff).

 PCB layout example for driving the Cree MOSFET.

 Gate drive reference design for a TO-247 packaged Cree MOSFET.

 Comparative testing between Cree devices and IGBTs.

This user manual will include information on the EVL board architecture, hardware

configuration, Cree SiC power devices and an example application when using this

board.

2. Package Contents

Item

No.

QTY P/N Description

1 1 CRD8FF1217P-1 Avago Driver version Eval board

2 4 AOS2182471 Ceramic isolation tile, 1.5mm

3 1 57908 Heat sink with mounting holes

5 2 C2M0080120D 80 mohm MOSFET

6 2 C4D20120D 20A Diode

7 1 Copper shorting strip

8 2 74270011 Ferrite Bead

9 8 91166a210 M3 washer, Zn-S, 7mm OD, 3.2mm ID

10 4 92005a129 M3x22mm, Zn-S, Board mounting Screw

11 4 94669a727 Stand offs, Al spacer, 6mm OD x 14mm

12 4 92005a120 M3x10mm, Zn-S, Device mounting screw

13 1 User Guide

3. EVL Board Overview

The EVL board’s general block diagram is shown in Figure 1. There is a phase-leg

which can include two SiC MOSFETs (Q1 and Q2) with half bridge phase-leg

configuration and two anti-parallel SiC schottky diodes (D1 and D3) with Q1 and Q2.

The gate drive block with electrical isolation is designed on the board to drive SiC

MOSFET Q1 and Q2. There are four power trace connectors (CON1, CON2, CON3

and CON5) and one 10 pin signal/supply voltage connector (CON4) on board.

3KIT8020CRD8FF1217P-1_UM Rev -

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Figure 1. General block diagram of Cree Discrete SiC EVL board

Please note that JM1 as shown in Figure 1 is open circuit. It is

necessary to short this with a wire or insert a shunt as shown in

section 6.2 to complete the circuit before operation.

CRD8FF1217P-1 includes two 2.5A gate driver integrating opto-coupler from Avago

ACPL-W346 and two 2W isolation DC/DC converters from Mornsun G1212S-2W for

both high side and low side isolated power. The 2W DC/DC converter with +12V Vcc

input generates +24V Vcc_out output voltage with 6KVDC isolation that is supplying

voltage to W346 on push-pull gate drive of the secondary side as shown in Figure 2.

In this circuit, a 5V zener in parallel with 1uF capacitor is used to generate -5V Vgs

voltage for the SiC MOSFET turn-off and turn-on Vgs voltage is equal to 24V-5V=19V.

Note that SiC MOSFET can be turned off with zero voltage, and the -5V turn-off

voltage helps with faster turn-off and lower turn-off losses and also improves dv/dt

induced self turn-on and noise immunity during transient periods with more margin for

Vgs turn-on threshold voltage. You can implement any PWM signal to drive the SiC

phase leg block, if the board is operating in synchronous mode with high side

MOSFET and low side MOSFET, the input signals must have additional dead time to

avoid shoot through.

CON1

CON3

CON2

CON5

CON4

CRD8FF1217P-1

VCC, Input PWM Signal,

Enable

SiC

Phase-leg

block

ACPL-W346

DC/DC

ACPL-W346

DC/DC

Vcc

Vcc_out

Vg_HS

Vg_LS

HS_I/P

LS_I/P

Vs_LS

Figure 2. CRD8FF1217P-1 Block diagram with ACPL-W346

4KIT8020CRD8FF1217P-1_UM Rev -

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The EVL board size is 124mmx120mmx40mm (not including heatsink). Different

types of heatsinks can be assembled depending on your cooling requirements. Figure

3 shows the board attached with the heatsink provided in the kit. However, the users

can use any type of heatsink that can work with the standard TO-247 package.

Figure 3. Cree EVL board assembly (see Appendix for assembly instructions).

4. Configurations

The EVL board can be flexible to implement difference topologies when using the

different configurations of SiC MOSFETs and SiC diodes. It is possible to test several

topologies with this board: synchronous Buck, non-synchronous Buck (or high-side

Buck), synchronous Boost, non-synchronous Boost, half phase-leg bridge converter,

H bridge converter (2x EVL boards) and bi-directional buck-boost converters. Table 1

summarizes the possible topologies that can be implemented using this EVL board.

For the phase-leg configuration, it can either use discrete anti-parallel SiC SBD or

body diode of SiC MOSFET, thus body diode of SiC MOSFET can be evaluated

without anti-parallel diode with option one in the below table.

With double EVL boards, H-bridge converter and bi-directional DC/DC converter can

be configured. For H-bridge, with different control architecture, the phase shift full

bridge, resonant LLC ZVS converter and single phase DC/ AC converter can all be

achieved. For bi-directional DC/DC converter, it can achieve either Buck from port 1 to

port 2 or Boost from port2 to port 1. Furthermore, with three EVL boards, it can even

be set up as a three-phase DC/AC inverter for some motor drive or inverter

applications.

Table. 1 The EVL board topology configuration

Option One:

Syn. Buck converter or

Phase-leg bridge

topology without

anti-parallel diodes

CON1

CON3

CON2

CON5

HVDC

Cout RL

Cin

 Step down voltage or

phase leg topology w/o

anti-parallel diodes

 SiC Body diode used

 Connect inductor L with

CON3 as output

 CON1: INPUT

 CON3: OUTPUT

5KIT8020CRD8FF1217P-1_UM Rev -

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 CON2, CON5: GND

Option Two:

Phase-leg bridge

topology with

anti-parallel SiC SBD

CON1

CON3

CON2

CON5

 Phase-leg, switching

with external

anti-parallel diode

 SiC SBD used

 CON1, CON3:

Input/output depends on

which topology apply to

board

 CON2, CON5: GND

Option Three:

Non-syn Buck converter

CON1

CON3

CON2

CON5

HVDC

Cout RL

Cin

 Step down voltage

 Connect inductor L with

CON3 as output

 CON1: INPUT

 CON3: OUTPUT

 CON2, CON5: GND

Option Four:

Syn. Boost converter

Cin

Cout

HVDC

CON1

CON3

CON2

CON5

 Step up voltage

 Connect inductor L with

CON3 as input

 CON1: OUTPUT

 CON3: INPUT

 CON2, CON5: GND

Option Five:

Non-syn Boost

converter

Cin

Cout

HVDC

CON1

CON3

CON2

CON5

 Step up voltage

 Connect inductor L with

CON3 as input

 CON1: OUTPUT

 CON3: INPUT

 CON2, CcON5: GND

6KIT8020CRD8FF1217P-1_UM Rev -

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Option Six:

Diode bridge

CON1

CON3

CON2

CON5

 Bridge diode with SiC

SBD

 CON1: OUTPUT

(Positive)

 CON3: INPUT

 CON2, CON5: OUTPUT

(Negative)

Option Seven:

H bridge topology

configuration using two

EVL boards

CON1

CON3

CON2

CON5

HVDC

Cout RL

Cin

CON1

CON3

CON2

CON5

EVL1

EVL2

 Full bridge converter

with Phase shift or

resonant

 single phase DC/AC

inverter

Option Eight:

Bi-directional DC/DC

converter

CON1

CON3

CON2

CON5

CON1

CON3

CON2

CON5

EVL1 EVL2

Port1 Port2

 Port 1 is input and port 2

is output with Buck

converter, Q2 of EVL2 is

constantly turn-on, and

Q1 of EVL2 is constantly

turn-off

 Port 1 is output and port

2 is input with Boost

converter, Q2 of EVL1 is

constantly turn-on and

Q1 of EVL2 is constantly

turn-off

7KIT8020CRD8FF1217P-1_UM Rev -

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5. Hardware Description

Figure 4. EVL board showing key connectors and components.

The above figures give top view of the EVL board. The picture highlights key test

points and connectors on the boards.

5.1 Test points

To make testing more effective and easy, the BNC connectors are added on the

board to measure both Vgs and Vds waveforms for SiC MOSFET Q1 and Q2. A

current test point with two unpopulated through-hole contacts is available to measure

the drain current through the low side switch. A jumper wire (not provided in the kit)

with a short loop (JM1) can be inserted to the test point and measure current using

current probe. Another option is to use accurate coaxial shunt resistors, (not provided

in the kit) from T&M Research (www.tandmresearch.com) to make the measurement.

This option can minimize the stray inductance on the switching loops and achieve

accurate switching loss measurement. Lastly, one can also simply short JM1 with the

small shorting strips provided in the kit, if it’s not necessary to measure the current

waveform. Also, some test points are added between gate resistors for measuring the

voltage across the gate resistors. Thus it can estimate the gate current Ig to the SiC

MOSFET.

5.2 Connectors

For the connectors, CON1, CON2, CON3 and CON5 are power trace connectors, and

their definitions are depending on the different topology as described in table 1. CON4

CON3

CON5

CON2

CON1

CON4

G1212S-2W G1212S-2W

W346

8KIT8020CRD8FF1217P-1_UM Rev -

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is for the signal/logic inputs and supply voltage for ICs. The definition of CON4 for

each pin is shown in table 2.

Table. 2 Pin definitions for connector CON4

Connector CON4 Pin CRD8FF1217P-1

Pin1 N/A

Pin2 N/A

Pin3 N/A

Pin4 N/A

Pin5 VCC: +12Vdc

Pin6 VCC_RTN: GND for +12Vdc

Pin7 Input_HS: signal input for Q2

Pin8 Input_HS_RTN: signal ground for Q2

Pin9 Input_LS: signal input for Q1

Pin10 Input_LS_RTN: signal ground for Q1

5.3 Board design

SiC device is a fast switching device, and it is important to maximize SiC’s high

performance and minimize ringing with fast switching. The EVL board introduces

some design approaches to minimize the ringing on the board:

 The gate drive and logic signal are put on top of the PCB board, while the main

power trace and switching devices are put on the bottom layer. There is no

crossover or overlap between gate signal and switching power trace, which

can minimize high dv/dt and di/dt noise influence from the switching node to

gate signal.

 Four de-coupling film capacitors with value 10nF, 10nF, 0.1uF and 5uFare

placed close to the SiC devices, and it can reduce high frequency switching

loop and bypass noise within switching loop.

 The layout of gate drive circuitry is designed with symmetric trace distance,

which can introduce balance impendence on the gate drive. Also, the gate

drive is placed as close as possible to the SiC MOSFETs.

 The power trace layout is optimized to reduce the switching loops.

6. CREE Devices

SiC devices including SiC MOSFET and SiC Schottky diodes are recognized as next

generation wide bandgap devices. It can provide fast switching with less loss

compared to conventional Si devices. Cree is the world’s leading manufacturer of

silicon-carbide Schottky diodes and MOSFETs for efficient power conversion. Two

sample 20A, 1200V rated SiC MOSFET devices and two 20A, 1200V rated Schottky

diodes are provided in the kit. However, other samples ranging from 5A to 50A can be

ordered online ( ).

9KIT8020CRD8FF1217P-1_UM Rev -

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7. Example Application and Measurements

7.1 Board Setup

In order to demonstrate the EVL with SiC devices, a synchronous phase-leg Buck

converter configuration is used as an example to evaluate the performance of the SiC

EVL board. This is option one configuration on table 1. The table below gives the

electrical parameters. Please note the switching frequency is at 40KHZ in this case

due to the design limitation of the available inductor, but it does not mean the

switching frequency is limited to 40KHZ. Because of low switching losses of SiC

MOSFET, the switching frequency can increase to higher without sacrificing much

switching losses when using SiC MOSFET. The purpose of 40KHZ setting is

competing with 1200V Si IGBT for inverter application with this phase-leg

configuration, which frequency is normally ranged from 15KHZ to 20KHZ.

In the testing, two 25mohm SiC MOSFETs are assembled on the PCB board with

heatsink for both high side Q2 and low side Q1. The figure gives the test setup with

EVL boards. The signal generators are used to generate high side and low side PWM

signals with Input_HS and Input_LS. Note that the dead time period must be applied

to the input signal between Input_HS and Input_LS.

Table. 3 Electrical parameters

Items Parameters

Input Voltage 600Vdc

Output Voltage 300Vdc

Output RMS Current 30A

Output Power 9KW

Peak MOS current 40A

Switching Frequency 40KHZ

Duty Cycle 50%

Dead time ~450ns

Inductor 400uH

Output Capacitors 300uF

Cree Discrete SiC EVL Board

Gate drive

CON1

CON3

CON2

CON5

600V

DC source

400uH

300uF

Cin

Input_LS_RTN

VCC

VCC_RTN

Input_HS

Input_HS_RTN

Input_LS

4.10

4.9

4.8

4.7

4.6

4.5

CON4

PWM signal

generator

+12V

DC supply

CRD8FF1217P-1

Figure 5. Test setup for the EVL boards with CRD8FF1217P-1

10 KIT8020CRD8FF1217P-1_UM Rev -

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Figure 6. Bench test setup of the EVL boards

7.2 Measurements

To maximize the accuracy of the measurements when using the EVL board, some

suggestions are listed below:

 Use a highly accurate 0.0131ohm shunt (not provided in the kit) to measure

the low side current waveform as shown below in Figure 7. This can help to

shorten the current sense loop.

Figure 7. Low side current measurement

 A BNC probe is connected to measure low-side Vgs waveform, a x100 HV

probe is used to measure low side Vds waveform, and a differential probe is

used to measure high-side Vgs waveform. All probes must be placed as close

as possible to reduce incorrect ringing due to probe placement.

 Place the power inductor as close as possible to connect at CON3 to reduce

the switching node loop area, and a 1uF 1200V film capacitors is connected

between the output of inductor and ground connector CON5.

 A 12W AC fan is used to cool the heatsink and inductor when measuring

waveforms and taking thermal measurements.

 A RC snubber is added on the drain to source to damp high dv/dt ringing on

the switching node and slow the high dv/dt.

 A capacitance (1nF) is added between gate to source terminal to shunt the

miller current from drain to gate. This external capacitor will introduce low

impedance path for Cdv/dt from miller capacitance effect and reduce the

ringing on the gate pins.

11 KIT8020CRD8FF1217P-1_UM Rev -

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 Use of a ferrite bead (FB) on the gate pin of TO-247 MOSFETs will introduce

high impedance on the gate path for MHz high frequency and reduce the Vgs

ringing.

 Reduce the stray capacitance of inductor with single layer structure.

TO-247

5ohm

1N5819HW

1nF

12ohm

220pF

12ohm

220pF

5ohm

1nF

1N5819HW

Figure 8. Gate drive and RC snubber configuration

7.3 Test data

The switching waveforms are shown in the below figures. In the operation of the

synchronous Buck converter, the low-side body diode conducts before low-side

MOSFET is turned on, thus this low-side MOSFET operates in Zero Voltage

Switching (ZVS) mode and high-side MOSFET operates in hard-switching mode.

However, high dv/dt during fast transient of high-side MOSFET will affect the

operational behavior of the low-side MOSFET, and the charge stored in miller

capacitance will be transferred via its gate loop, inducing some spurious gate voltage

in this topology. The above methods mentioned in section 6.2 will help to damp this

noise and reduce the ringing on the gate and drain to source. Note that the incorrect

test method itself may also introduce some noises from oscilloscope measurement,

but it is sometimes not a true representation of the actual transient events on the

switching devices.

12 KIT8020CRD8FF1217P-1_UM Rev -

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Figure 9. Vgs, Id and Vds waveforms at 9KW loading

(Ch1: low-side Vds yellow 200v/div); (Ch2: low-side Id blue 100mv/0.0131ohm/div);

(Ch3: low-side Vgs pink 10v/div); (Ch4: high-side Vgs green 10v/div)

13 KIT8020CRD8FF1217P-1_UM Rev -

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Figure 10. Vgs, Inductor current IL and Vds waveforms at 9KW loading

(Ch1: low-side Vds yellow 200v/div); (Ch2: inductor current IL 10A/div);

(Ch3: low-side Vgs pink 10v/div); (Ch4: high-side Vgs green 10v/div)

The EVL board’s maximum efficiency in this configuration is around 98.9% at 4KW

half load using the Yokogawa WT3000 to measure it. It includes losses from the

inductor, switching devices, and capacitors. Considering the high switching frequency

(40kHz) and high duty cycle (50%), the efficiency is high compared to conventional Si

IGBT solutions.

Figure 11. Efficiency data for this EVL board

Figure 12 shows the thermal performance for this EVL board at full load 9KW after 30

minutes of continuous operation. The test condition is at room temperature with open

frame and 12W fan cooling the heatsink and inductor. It demonstrates high

performance of SiC MOSFET with low temperature, low losses and high switching

frequency.

Figure 12. Thermal imaging of the EVL board while under test.

14 KIT8020CRD8FF1217P-1_UM Rev -

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8. Reference

1. C2M0025120D datasheet, Cree Inc

2. C4D20120D datasheet, Cree Inc

3. ‘Performance Evaluations of Hard-Switching Interleaved DC/DC Boost Converter with New

Generation Silicon Carbide MOSFETs’ Available in Cree website:

http://www.cree.com/Power/Document-Library

4. ‘Design Considerations for Designing with Cree SiC Modules Part 1. Understanding the

Effects of Parasitic Inductance’ Available in Cree website:

http://www.cree.com/Power/Document-Library

5. ‘Design Considerations for Designing with Cree SiC Modules Part 2. Understanding the

Effects of Parasitic Inductance’ Available in Cree website:

http://www.cree.com/Power/Document-Library

15 KIT8020CRD8FF1217P-1_UM Rev -

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9. Appendix

Heatsink assembly instructions:

1. Apply thermal grease to the AlN thermal isolator and place it on the heatsink to

align with the mounting hole.

2. Apply thermal grease to the back side of the device package and align

mounting hole to the thermal isolator and heatsink.

3. Use the M3x10mm screw to secure (0.8 Nm) the device to the heatsink.

4. Attach the EVL board to the heatsink using the 4x standoffs, 4x M3x21mm

mounting screws and 4x washers (1Nm).

5. Solder the MOSFET and Diode devices to the EVL board.

(Reference table for package contents on page 1)

16 KIT8020CRD8FF1217P-1_UM Rev -

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ZD4

24V

SOD-123

R13

5R1 R0603

R14

5R1 R0603

ZD5

5V1

SOD-123

R15

5R1 R0603

R16

5R1 R0603

ZD1

24V

SOD-123

ZD2

5V1

SOD-123

ZD7

25V

SOD-123

TP6

Vd_LS

ZD6

5V1

SOD-123

ZD3

5V1

SOD-123

ZD8

25V SOD-123

R24

R0603

Title

Size Document Number Rev

Date: Sheet of

SiC MOSFET EVL Board (CRD 8FF1217P-1) 1v0

Main board - Avago

1 1

Sunday, September 21, 2014

R11

240

R0603

5R1

R1206

R12

R1206

R10

130

R0603

SiC MOSFET

TO-247

5R1

R1206

TP7

V_Ig_HS1

0.1uF

C0603

33pF

C0603

JM1

2.2uF

C0603

130

R0603

10k

R1206

1uF C1206

TP2

V_Ig_LS1

C4D20120D

TO-247

R1206

10k

R1206

C11

4.7uF

C1206

1nF

C1206

TP9

GND

TP8

V_Ig_HS2

ACPL-W346

Anode

Cathode

3Gnd 4

Vout 5

Vcc 6

0.1uF

C0603

1N5819HW

SOD-123

C16

1uF

C0603

TP3

V_Ig_LS2

5R1

R1206

C15

2.2uF

C0603

240

R0603

SiC MOSFET

TO-247

Input_LS_RTN

Input_LS

C4D20120D

TO-247

1nF

C1206

1N5819HW

SOD-123

CON3

MID-PT

CON1

HVDC

1uF C1206

CON2

GND

5R1

R1206

C12

4.7uF

C1206

C10

0.1uF

C0603

C13

33pF

C0603

ACPL-W346

Anode

Cathode

3Gnd 4

Vout 5

Vcc 6

C14

0.1uF

C0603

VCC_RTN

VCC

Input_LS_RTN

Input_LS

VCC_RTN

VCC

Input_HS_RTN

Input_HS

Input_HS_RTN

Input_HS

GND

+22V_VCC_LS

VCC

-VEE_LS

VCC_RTN

+22V_VCC_HS

-VEE_LS

-VEE_mid_HS

Circuit in

this area,

the ground

isolated.

TP1 0

HV_VCC

R17

R1206

R18

R1206

R20

R1206

R21

R1206

GND

CON5

GND

C19

0.1uF

C17

10nF

C18

10nF

R19

R1206

R22

R1206

C20

5uF

G1212S-2W

+Vin

-Vin

+Vout 7

COM 6

-Vout 5

C21

1uF

C0603

G1212S-2W

+Vin

-Vin

+Vout 7

COM 6

-Vout 5

1uF

C0603

C22

1uF

C0603

TP1

Vg_LS

CON4

Gate Driver input

VS_LS

CHOKE CM

TP5

Vg_HS

VS_HS

R23

R0603

R25

10R

R4524

C23

220pF

C1210

TP4

Vd_HS

R26

10R

R4524

C24

220pF

C1210

BOM Ver.: A

PCB Ver.: A

BD1

BEAD

Schematic of CRD 8FF1217P-1

17 KIT8020CRD8FF1217P-1_UM Rev -

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Component list of CRD 8FF1217P-1

Part

Ref.

Value Part number Brand Description Type

PCB

Footprint

1 BD1 Bead 74270011 Wurth ferrite bead THR

2 C1 1nF

Ceramic, C0G, 10% SMD C1206

3 C2 1uF

Ceramic, X7R, 10% SMD C1206

4 C3 0.1uF

Ceramic, X7R, 10% SMD C0603

5 C4 1nF

Ceramic, C0G, 10% SMD C1206

6 C5 1uF

Ceramic, C0G, 10% SMD C0603

7 C6 1uF

Ceramic, X7R, 10% SMD C1206

8 C7 2.2uF

Ceramic, X7R, 10% SMD C0603

9 C8 0.1uF

Ceramic, X7R, 10% SMD C0603

10 C9 33pF

Ceramic, C0G, 10% SMD C0603

11 C10 0.1uF

Ceramic, X7R, 10% SMD C0603

12 C11 4.7uF

Ceramic, X7R, 10% SMD C1206

13 C12 4.7uF

Ceramic, X7R, 10% SMD C1206

14 C13 33pF

Ceramic, C0G, 10% SMD C0603

15 C14 0.1uF

Ceramic, X7R, 10% SMD C0603

16 C15 2.2uF

Ceramic, X7R, 10% SMD C0603

17 C16 1uF

Ceramic, X7R, 10% SMD C0603

18 C17 10nF B32653A1103K EPCOS CAP FILM 10nF 1.6KVDC RADIAL, PP THR

19 C18 10nF B32653A1103K EPCOS CAP FILM 10nF 1.6KVDC RADIAL, PP THR

20 C19 0.1uF B32654A1104K EPCOS CAP FILM 0.1UF 1.6KVDC RADIAL, PP

THR

21 C20 5uF B32774D1505K EPCOS CAP FILM 5UF 1.3KVDC RADIAL, PP THR

22 C21 1uF

Ceramic, X7R, 10% SMD C0603

23 C22 1uF

Ceramic, X7R, 10% SMD C0603

24 C23 220pF C1210C221JGGACTU Kemet CAP CER 220PF 2KV 5% NP0 1210 SMD C1210

25 C24 220pF C1210C221JGGACTU Kemet CAP CER 220PF 2KV 5% NP0 1210 SMD C1210

26 CON1 HVDC 7808 Skystone female, M5, 30A, 6P MECH

27 CON2 GND 7808 Skystone female, M5, 30A, 6P MECH

28 CON3 MID-PT 7808 Skystone female, M5, 30A, 6P MECH

29 CON4 Gate Driver input 22-27-2101 Molex 10pin, 2.54mm, male MECH

30 CON5 GND 7808 Skystone female, M5, 30A, 6P MECH

31 D1 C4D20120D C4D20120D CREE 1200V, 20A THR TO-247

32 D2 1N5819HW 1N5819HW-7-F Diodes DIODE SCHOTTKY 40V 1A SOD123 SMD SOD-123

33 D3 C4D20120D C4D20120D CREE 1200V, 20A THR TO-247

34 D4 1N5819HW 1N5819HW-7-F Diodes DIODE SCHOTTKY 40V 1A SOD123 SMD SOD-123

35 JM1 Id

dim. 1.75mm jumper wire x2 for Id

connect to GND

MECH

36 L1 CM CHOKE ACM4520-142-2P-T000 TDK CM choke SMD

37 Q1 SiC MOSFET C2M0025120D CREE 25-mΩ, 1200-V, SiC MOSFET THR TO-247

38 Q2 SiC MOSFET C2M0025120D CREE 25-mΩ, 1200-V, SiC MOSFET THR TO-247

39 R1 5R1

Res, 1% SMD R1206

18 KIT8020CRD8FF1217P-1_UM Rev -

User Manual

40 R2 5R1

Res, 1% SMD R1206

41 R3 10k

Res, 1% SMD R1206

42 R4 130

Res, 1% SMD R0603

43 R5 240

Res, 1% SMD R0603

44 R6 5R1

Res, 1% SMD R1206

45 R7 5R1

Res, 1% SMD R1206

46 R8 10k

Res, 1% SMD R1206

47 R9 1k

Res, 1% SMD R1206

48 R10 130

Res, 1% SMD R0603

49 R11 240

Res, 1% SMD R0603

50 R12 1k

Res, 1% SMD R1206

51 R13 5R1

Res, 1% SMD R0603

52 R14 5R1

Res, 1% SMD R0603

53 R15 5R1

Res, 1% SMD R0603

54 R16 5R1

Res, 1% SMD R0603

55 R17 1M

Res, 1% SMD R1206

56 R18 1M

Res, 1% SMD R1206

57 R19 1M

Res, 1% SMD R1206

58 R20 1M

Res, 1% SMD R1206

59 R21 1M

Res, 1% SMD R1206

60 R22 1M

Res, 1% SMD R1206

61 R23 1k

Res, 1% SMD R0603

62 R24 1k

Res, 1% SMD R0603

63 R25 10R S4-10RF1 Riedon RES 10 OHM 2W 1% WW SMD SMD R4524

64 R26 10R S4-10RF1 Riedon RES 10 OHM 2W 1% WW SMD SMD R4524

65 TP1 Vg_LS 546-4027 RS BNC socket, female MECH

66 TP2 V_Ig_LS1 5020 keystone round, 1pin, test point MECH

67 TP3 V_Ig_LS2 5020 keystone round, 1pin, test point MECH

68 TP4 Vd_HS 546-4027 RS BNC socket, female MECH

69 TP5 Vg_HS 546-4027 RS BNC socket, female MECH

70 TP6 Vd_LS 546-4027 RS BNC socket, female MECH

71 TP7 V_Ig_HS1 5020 keystone round, 1pin, test point MECH

72 TP8 V_Ig_HS2 5020 keystone round, 1pin, test point MECH

73 TP9 GND 5020 keystone round, 1pin, test point MECH

74 TP10 HV_VCC 5020 keystone round, 1pin, test point MECH

75 U1 ACPL-W346 ACPL-W346-060E Avago

SMD

76 U2 ACPL-W346 ACPL-W346-060E Avago

SMD

77 U3 G1212S-2W G1212S-2W Mornsun

THR

78 U4 G1212S-2W G1212S-2W Mornsun

THR

79 ZD1 24V

24V, 350mW, 1% SMD SOD-123

80 ZD2 5.1V

5.1V, 350mW, 1% SMD SOD-123

81 ZD3 5.1V

5.1V, 350mW, 1% SMD SOD-123

82 ZD4 24V

24V, 350mW, 1% SMD SOD-123

19 KIT8020CRD8FF1217P-1_UM Rev -

User Manual

83 ZD5 5.1V

5.1V, 350mW, 1% SMD SOD-123

84 ZD6 5.1V

5.1V, 350mW, 1% SMD SOD-123

85 ZD7 25V

25V, 350mW, 2% SMD SOD-123

86 ZD8 25V

25V, 350mW, 2% SMD SOD-123