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Log #2 Researching Firmware

A project log for Hoverboards for Assistive Devices

Want to motorize a wheeled assistive device? What better than a hacked hoverboard with brushless motors, electronics and power.

phil-malonePhil Malone 04/16/2020 at 14:280 Comments

Once I received my new HOVER-1 ULTRA, and discovered that it had two separate motor controller boards, I knew I had some research ahead of me.

To cut a long story short, I found two great projects that could help me with code.

The first source was a Software repo by Florian, a German Software and Hardware developer.

https://github.com/flo199213/Hoverboard-Firmware-Hack-Gen2

This appears to be the first code repository that deals with the Dual controller code.

An interesting adaption of Florian's code was made by Gaucho, in Rome.

https://github.com/gaucho1978/CHEAP-LAWNMOWER-ROBOT-FROM-HOVERBOARD

By combining information from both of these projects, I was able to establish a starting point for my own code.  I actually used Gaucho's code to verify that I could succesfuly build and deploy working code, but in the end I used Florians code as the basis for my own project.

The Florian Repo came with the following Flashing instructions

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The firmware is built with Keil (free up to 32KByte). To build the firmware, open the Keil project file which is includes in repository. Right to the STM32, there is a debugging header with GND, 3V3, SWDIO and SWCLK. Connect GND, SWDIO and SWCLK to your SWD programmer, like the ST-Link found on many STM devboards.

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So I ordered the ST-LINK interface from AdaFruit.com, and downloaded the Keil software from https://www.keil.com/demo/eval/arm.htm and the ST-LINK Utility from https://www.st.com/en/development-tools/stsw-link004.html

I mounted header pins for programming and serial debugging, and stared down the road of figuring out what the various elements did.

The following picture shows the two cables that I assembled for programming and debugging.  The ST-LINK module was connected to the programming header by 4 wires.  This provided the communications AND power for the processor.  Note: the processor runs on 3.3V (not 5V).  Also shown is the serial debugger cable that uses a USB-TTL Serial interface like this one.  Note that the power from the debugger cable is not used, and the interface is 3.3-5v compatible.

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