I finally got revision 1.1 of these boards yesterday, so I can get on with this adapter. The main error on 1.1 was lack of crystal and I realized I needed the crystal for USB as I tested.

I like CubeMX, but I fail to undestand “designers” that want to create a “HAL” and only do low level, MCU specific interface. In this example I would have liked a function to select bitrate, but are left with setting up loads of timing details.

Even more annoying was that the generated project for STM32F105RB do not want to compile due to lack of files. This is where auto-generation and I usually separate.

The config system in CubeMX allows you to configure and generate code for all components you have included, including FreeRTOS and libraries. This page show the config for FreeRTOS and it allows you to create a list of Tasks as well as message queues.

The folders on top are

• Config Parameters
• Include Parameters
• User Constants
• Task & Queues (shown here)
• Timers and Semaphores
• FreeRTOS Heap Usage

The reason why I like this is because I don’t know FreeRTOS and within a few clicks I am using it and on my way into functionality. FreeRTOS is also included in ESP32 IDE supporting multiple cores and have been around for years.

This shows the STM32CubeMX for my 3 x RS-X PLC Module. I find this tool to be quite usefully as it allow you to set up the clock, configure each function and wire the MCU. It also generate a nice PDF document with all details as well as a starting project with all init code as well as FreeRTOS should you want it.

The generated code opens in System Workbench for STM32 and the only complain is that they only support C. But, you should be able to get C++ with a bit of manual work.

It all works well with a low cost ST-Link, so you are on your way blinking a status led within minutes.

System Workbench for STM32 is far behind CoIDE and CooCox, but I still use CoIDE 1.7.8 and as CooCox seems to be down (?) I need to move on. My main concern is lack of C++ support which sadly is very common in many embedded IDE’s. Returning to STM32CumeMX, this tools is free from ST and a big time saver. It download latest drivers and give you working examples on how to initialize the MCU. It also warns you about wiring conflicts and does the job of setting up the complex clock.

Every year around christmas I tell myself that next year I will have electronic christmas decorations, and as next year arrive it’s forgotten until it’s to late. A combination of STM32F030 and ULN2003 is excellent for a very small x-mas tree PCB with blinking LEDS and home made tree lights. In fact I have done this circuit before as a PWM driver with a single ULN2003, so what I will do is to make multiple PCB’s with LED strings connected through a RS-X (12V + RS485). These can then be wired in the x-mas tree and controlled by RS485 connection and 12V LED driver.

STM32F030F4 is excellent for this purpose, it cost 0.4 USD from AliExpress and all I need are sufficient to cover 20-40 of these. A 5A LED Driver should be more than sufficient. We make a harness with connectors up the tree where each decoration connect to this is a star network.

Application can be constant or random patterns as a start to make it simple. In fact I could make a small ESP32 control system with RS485 at bottom so I get the entire c-mas tree on Wifi or bluetooth. This could be a lot of fun.

The cost of this will be 2-4.- USD per PCB, around 10.- for the control system and a bit for the wiring. I probably end up spending around 100.- USD for a very attractive x-mas tree light system.

I can probably use up to 200mA per ULN2003 and a quick calc is that a single LED uses around 5mA, so in short – I will run out of space and LED’s before I run out of power. But, we should limit each decoration to ca 250mA max – I will probably need far less.

I decided to remove some of the PCB lanes and replace them with high current wires to support 50A currents. I had to extend the board ca 1.5mm at right, but to compensate I also remove the connectors because I need high current support all the way. I like having connectors for <10A solutions and playing in the lab, so will see what I can do. This will also free up 2-3mm that I desperately need at left.

At the end it simply made no sense to continue with 15A limit as I realized I would be using the same components and same space for a 50A design. And yes – this is a 50A design. The power wires are 3mm in diameter that actually is something like 64A while the 2mm wire for each channel is ca 41A. But, in addition to this you also have heat-sink at bottom as I connect the PCB itself to the heat-sink. I am confident that I will get sufficient out of this board.