The Arm Mbed OS OTA Requestor Example demonstrates how to remotely trigger update image downloading and apply it if needed. Full functionality of this examples can be obtained with the addition of a Mbed bootloader that allows launching the right application image form memory. The example takes advantage of the IO available on board:
You can use this example as a reference for creating your own application.
The example is based on Matter and Arm Mbed OS, and supports remote access and control of lock over a WiFi network.
The example behaves as a Matter accessory, in other words a device that can be paired into an existing Matter network and can be controlled by this network.
The Matter device that runs the lock application is controlled by the Matter controller device over WiFi. By default, the Matter device is disconnected , and it should be paired with Matter controller and get configuration from it. Actions required before establishing full communication are described below.
To commission the device onto a Matter network, the device must be discoverable over BLE. The BLE advertising starts automatically after device boot-up.
In Matter, the commissioning procedure (called rendezvous) is done over BLE between a Matter device and the Matter controller, where the controller has the commissioner role.
To start the rendezvous, the controller must get the commissioning information from the Matter device. The data payload is encoded within a QR code, printed to the UART console.
The last part of the rendezvous procedure, provisioning involves sending the network credentials from the Matter controller to the Matter device. As a result, device is able to join the network and communicate with other devices in the network.
Before building the example, check out the Matter repository and sync submodules using the following command:
$ git submodule update --init
Building the example application requires the use of ARM Mbed-OS sources and the arm-none-gnu-eabi toolchain.
The Cypress OpenOCD package is required for flashing purpose. Install the Cypress OpenOCD and set env var OPENOCD_PATH
before calling the flashing script.
cd ~ wget https://github.com/Infineon/openocd/releases/download/release-v4.3.0/openocd-4.3.0.1746-linux.tar.gz tar xzvf openocd-4.3.0.1746-linux.tar.gz export OPENOCD_PATH=$HOME/openocd
Some additional packages may be needed, depending on selected build target and its requirements.
The VSCode devcontainer has these components pre-installed. Using the VSCode devcontainer is the recommended way to interact with Arm Mbed-OS port of the Matter Project.
Please read this README.md for more information about using VSCode in container.
To initialize the development environment, download all registered sub-modules and activate the environment:
$ source ./scripts/bootstrap.sh $ source ./scripts/activate.sh
If packages are already installed then you just need to activate the development environment:
$ source ./scripts/activate.sh
The OTA Requestor application can be built in the same way as any other Matter example ported to the mbed-os platform.
Command Palette (F1) => Run Task... => Run Mbed Application => build => ota-requestor-app => (board name) => (build profile) => (build type)
${MATTER_ROOT}/scripts/examples/mbed_example.sh -c=build -a=ota-requestor-app -b=<board name> -p=<build profile> -T=<build type>
Both approaches are limited to supported evaluation boards which are listed in Supported devices paragraph.
Mbed OS defines three building profiles: develop, debug and release. For more details please visit ARM Mbed OS build profiles.
There are also three types of built application: simple, boot and upgrade:
When using the building script, it is possible expand the list of acceptable targets; this may be useful for rapid testing of a new mbed-targets.
The Lock application can be flashed in the same way as any other Matter example ported to mbed-os platform.
The Open On-Chip Debugger is used to upload a binary image and reset the device.
Command Palette (F1) => Run Task... -> Run Mbed Application => flash => ota-requestor-app => (board name) => (build profile)
${MATTER_ROOT}/scripts/examples/mbed_example.sh -c=flash -a=ota-requestor-app -b=<board name> -p=<build profile>
Run and Debug (Ctrl+Shift+D) => Flash Mbed examples => Start Debugging (F5) => (board name) => ota-requestor-app => (build profile)
The last option uses the Open On-Chip Debugger to open and manage the gdb-server session. Then gdb-client (arm-none-eabi-gdb) upload binary image and reset device.
It is possible to connect to an external gdb-server session by using specific ‘Flash Mbed examples [remote]’ task.
Debugging can be performed in the same was as with any other Matter example ported to mbed-os platform.
The Open On-Chip Debugger is used to to open and manage the gdb-server session. Then gdb-client (arm-none-eabi-gdb) connect the server to upload binary image and control debugging.
Run and Debug (Ctrl+Shift+D) => Debug Mbed examples => Start Debugging (F5) => (board name) => ota-requestor-app => (build profile)
It is possible to connect to an external gdb-server session by using specific ‘Debug Mbed examples [remote]’ task.
The provider application is required to transfer image file to OTA requestor. Mbed example is compatible with Linux version of OTA provider example. Read the OTAProvider to see how to build and run the OTA provider.
The application traces are streaming to serial output. To start communication open a terminal session and connect to the serial port of the device. You can use mbed-tools for this purpose (mbed-tools):
mbed-tools sterm -p /dev/ttyACM0 -b 115200 -e off
After device reset these lines should be visible:
[INFO][CHIP]: [-]Mbed ota-requestor-app example application start ... [INFO][chip]: [-]Mbed ota-requestor-app example application run
The ota-requestor-app application launched correctly and you can follow traces in the terminal.
Read the MbedCommissioning to see how to use different CHIP tools to commission and control the application within a WiFi network.
After commissioning is successful, announce OTA provider's presence using OtaSoftwareUpdateRequestor
cluster with AnnounceOtaProvider
command. On receiving this command OTA requestor will query for OTA image:
chip-device-ctrl > zcl OtaSoftwareUpdateRequestor AnnounceOtaProvider 1234 0 0 providerNodeId=1235 vendorId=9020 announcementReason=0
The OTA requestor should communicate with provider, download update image and apply it.
You have to provision the OTA Provider in the same Matter network. Use the connect -ip
command of Python Device Controller:
chip-device-ctrl > connect -ip 127.0.0.1 20202021 1235
POSIX CLI CHIPTool can be also used for testing this example. Use the correct chip-tool
arguments to perform above-mentioned steps.
The example supports building and running on the following mbed-enabled devices:
Manufacturer | Hardware platform | Build target | Platform image | Status | Platform components |
---|---|---|---|---|---|
Cypress Semiconductor | CY8CPROTO-062-4343W | CY8CPROTO_062_4343W | CY8CPROTO-062-4343W | :heavy_check_mark: | LEDsBoard has only one usable LED (LED4) which corresponds to USER LED from UI.Lock state LED should be an external component connected to PB9_6 pin (active high). ButtonsSW2 push-button is not used in this example due to its interaction with WIFI module interrupt line.Button 0 corresponds to BTN0 capacitive button.Button 1 corresponds to BTN1 capacitive button. SliderUnused |
ota-requestor-app/mbed/mbed_app.json
.This section lists the User Interface elements that you can use to control and monitor the state of the device. These correspond to PCB components on the platform image.
USER LED shows the overall state of the device and its connectivity. The following states are possible:
Short Flash On (50 ms on/950 ms off) — The device is in the unprovisioned (unpaired) state and is waiting for a commissioning application to connect.
Rapid Even Flashing (100 ms on/100 ms off) — The device is in the unprovisioned state and a commissioning application is connected through Bluetooth LE.
Short Flash Off (950ms on/50ms off) — The device is fully provisioned, but does not yet have full network or service connectivity.
Solid On — The device is fully provisioned and has full network and service connectivity.
Button 0 can be used for the following purposes:
Pressed for 6 s — Initiates the factory reset of the device. Releasing the button within the 6-second window cancels the factory reset procedure. LEDs 1-4 blink in unison when the factory reset procedure is initiated.
Pressed for less than 3 s — Trigger confirm user response.
Button 1 can be used for the following purposes:
Pressed for 6 s — Initiates the commissioning reset of the device. The fabric IDs are deleted and BLE advertising start. Releasing the button within the 6-second window cancels the commissioning reset procedure. LEDs 1-4 blink in unison when the commissioning reset procedure is initiated.
Pressed for less than 3 s — Trigger reject user response.
Button 1 — Pressing the button once delete all fabric IDs and start BLE advertising.
Some of the supported boards may not have sufficient number PCB components to follow above description. In that case please refer to Supported devices section and check board's ‘Platform components’ column for additional information about the limitation.