John-Mark Gurney fbe09e92b7 | 3 years ago | |
---|---|---|
loramac | 3 years ago | |
stm32 | 3 years ago | |
strobe | 3 years ago | |
.gitignore | 3 years ago | |
LICENSE.txt | 3 years ago | |
Makefile | 3 years ago | |
NOTES.md | 3 years ago | |
PROTOCOL.md | 3 years ago | |
README.md | 3 years ago | |
board-config.h | 3 years ago | |
board.c | 3 years ago | |
comms.c | 3 years ago | |
comms.h | 3 years ago | |
lora.py | 3 years ago | |
lora_comms.py | 3 years ago | |
main.c | 3 years ago | |
misc.c | 3 years ago | |
misc.h | 3 years ago | |
requirements.txt | 3 years ago | |
strobe_rng_init.c | 3 years ago | |
strobe_rng_init.h | 3 years ago | |
sysIrqHandlers.h | 3 years ago |
This project is to build an irrigation system from LoRa capable microcontrollers. The Heltec Node151 was chosen due to it’s small size and inexpensive cost.
While investigating this, the LoraWAN protocol was investigated, but after looking at the code complexity and other operational requirements, if was decided that for this project, it was safer to target a direct Node to Node style communication system. This would allow the implementation to be more simple, and security to be built in. It could also be used for other projects that need security.
One of the other requirements is that the code be 100% open sourced, not GPL licensed, and no proprietary components. This meant that using IDE’s like ST’s STM32CubeIDE which is only available in binary form was not a choice, as that would preclude building on an operating system other than Windows/MaxOS/Linux.
The build system uses the BSD flavor of make. This is the default make on the BSDs, originally called pmake, but also available as bsdmake for MacOSX, and likely other operating systems as well.
It also depends upon ARM’s GNU Arm Embedded
Toolchain
which uses gcc as the compiler. It would be good to get it to
cross-compile with clang as well, but that requires finding a libc like
the nano libc that nano.specs
in the above toolchain provides.
Once ARM’s toolchain is in your path, the following should work:
export MAKEOBJDIR=build
mkdir $MAKEOBJDIR
bsdmake all
And in the directory build
, a file lora.irr.elf
should be present.
Flashing can be done via the open source tool
OpenOCD. For this, I use
a Digilent HS1 JTAG programmer utilizing the resistor
hack
to allow an FTDI JTAG programmer to control the bi-directional SWIO
pin.
One caveat w/ MacOSX, is that it may be necessary to unload the kext
com.apple.driver.AppleUSBFTDI
via the command:
sudo kextunload -b com.apple.driver.AppleUSBFTDI
as OpenOCD wants direct access to the FTDI driver.
Once that happens, the device can be programmed using the following command:
sudo openocd -f interface/ftdi/digilent-hs1.cfg -f interface/ftdi/swd-resistor-hack.cfg -f target/stm32l1.cfg -c "init" -c "reset init" -c "program build/lora.irr.elf verify reset exit"