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CW303 Arm Target

The ChipWhisperer-Lite board has a break-away target board section. This target can be used attached to the CW-Lite or separated and connected via ribbon cable. The breakaway target board has a slightly different feature set than the CW308T-STM32F3 target board. For more info, see the CW308T-STM32F documentation.


Feature Notes/Range
Target Device STM32F303RCT6
Target Architecture 32-bit Arm Cortex-M4
Vcc 3.3V
Programming STM32F Serial Bootloader, JTAG, SWD
Hardware Crypto No
Availability ChipWhisperer-Lite 32-bit
Status Released
Shunt 12Ω

Available with the ChipWhisperer-Lite 32-bit starter kit


The two LEDs on the STM32 board are active-low, which is done to reduce the impact on power consumption in the VCC power signature. The connections are as follows:

Item Connection Note
LED9 PC14 Active low
LED10 PC13 Active low


Building Firmware

Building Firmware for this target requires make and arm-none-eabi-gcc. Installation of both these are covered in

If you have make and arm-none-eabi-gcc, you can build firmware by navigating via command line to the relevant build directory and running:



If you're running a Jupyter Notebook lab, typically this step will be contained within one of the code blocks.

Programming Firmware

The ChipWhisperer-Lite and ChipWhisperer-Pro have integrated STM32F UART programmers, meaning there's no need to use an external one if you're using either. To program via the ChipWhisperer API:

# ...assuming scope is setup
# ensure device has clock and IO is setup, typically via scope.default_setup()
prog = cw.programmers.STM32FProgrammer
cw.program_target(scope, prog, "<path/to/firmware.hex>")

Increasing CLKIN

The STM32F303 has a max CLKIN input of 32MHz; however, to increase it above 24MHz, the flash latency must be increased. Note that this may adversely affect clock glitching in particular. Flash latency can be increased in hardware/victims/firmware/hal/stm32f3/stm32f3_hal.c


The following shows several of the connectors available on the CW301.

20-Pin Connector

J2 is a 20-pin connector, which uses the standard NewAE 20-pin
connector pinout. See the ChipWhisperer-Lite documentation for

SMA Glitch

The SMA glitch connector allows VCC glitches be inserted into the
VCC pin. This is done by shorting the resistive shunt R66. By
default it connects to the SMA measure connector, but can be
disconnected with the solder jumpers.

SMA Measure

The SMA measure connector allows power measurements to be taken
across resistive shunt R66. By default it connects to the SMA glitch
connector, but can be disconnected with the solder jumpers.


JP13 provides a pinout with a few extra IO pins,
as well as JTAG/SWD debug pins.

Solder Jumpers


Connects the output of the VCC filter to the STM32F3 VCC network.
Soldered by default.


Connects the SMA Measure header to the resistive shunt. Soldered by


Connects the SMA Glitch header to the resistive shunt. Soldered by


Connects the VCC of the STM32F3 board to VREF on 20-pin header.
Soldered by default.

Mounting Jumpers

Note the ChipWhisperer-Lite main board and target section contain a number of jumper options. By default these are not mounted, and solder jumper bridges on the PCB have been bridged to select the appropriate options when required. Some options are only solder jumpers, which to move the jumper requires a soldering iron to bridge or clear the appropriate connections.

The following lists jumpers on the ChipWhisperer-Lite / Target Section:

  • JP7 connects the "MEASURE" SMA to the STM32F3 VCC Rail. Shorted by default with SJ4
  • JP6 connects the "GLITCH" SMA to the STM32F3 VCC rail. Shorted by default with SJ5
  • JP12 can be used to feed an external voltage into the XMEGA VCC rail. By default SJ3 connects this to 3.3V
  • SJ2 selects if the 3.3V rail comes from the 20-pin IDC connector (i.e. ChipWhisperer-Lite board) or via an optional LDO and USB connector