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Connecting a Silicon Labs SLWSTK6000B EFR32MG12 to Azure IoT using Azure RTOS |
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Total completion time: 30 minutes
In this tutorial you use Azure RTOS to connect the Silicon Labs EFR32MG12 MCU Starter Kit to Azure IoT. The article is part of the series Getting started with Azure RTOS. The series introduces device developers to Azure RTOS, and shows how to connect several device evaluation kits to Azure IoT.
You will complete the following tasks:
- Install a set of embedded development tools for programming the EFR32MG12 MCU Starter Kit in C
- Build an image and flash it onto the EFR32MG12 MCU Starter Kit
- Use Azure IoT Central to create cloud components, view properties, view device telemetry, and call direct commands
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A PC running Microsoft Windows 10
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Git for cloning the repository
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Hardware
- Silicon Labs Starter Kit: SLWSTK6000B
- Wi-Fi 2.4 GHz
- USB Mini-B male to USB male cable
To set up your development environment, first you clone a GitHub repo that contains all the assets you need for the tutorial. Then you install a set of programming tools.
Clone the following repo to download all sample device code, setup scripts, and offline versions of the documentation. If you previously cloned this repo in another tutorial, you don't need to do it again.
To clone the repo, run the following command:
git clone --recursive https://github.com/azure-rtos/getting-started.git
The cloned repo contains a setup script that installs and configures the required tools. If you installed these tools in another tutorial in the getting started guide, you don't need to do it again.
Note: The setup script installs the following tools:
To install the tools:
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From File Explorer, navigate to the following path in the repo and run the setup script named get-toolchain.bat:
getting-started\tools\get-toolchain.bat
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After the installation, open a new console window to recognize the configuration changes made by the setup script. Use this console to complete the remaining programming tasks in the tutorial. You can use Windows CMD, PowerShell, or Git Bash for Windows.
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Run the following code to confirm that CMake version 3.14 or later is installed.
cmake --version
There are several ways to connect devices to Azure IoT. In this section, you learn how to connect a device by using Azure IoT Central. IoT Central is an IoT application platform that reduces the cost and complexity of creating and managing IoT solutions.
To create a new application:
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From Azure IoT Central portal, select My apps on the side navigation menu.
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Select + New application.
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Select Custom apps.
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Add Application Name and a URL.
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Choose the Free Pricing plan to activate a 7-day trial.
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Select Create.
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After IoT Central provisions the application, it redirects you automatically to the new application dashboard.
Note: If you have an existing IoT Central application, you can use it to complete the steps in this article rather than create a new application.
In this section, you use the IoT Central application dashboard to create a new device. You will use the connection information for the newly created device to securely connect your physical device in a later section.
To create a device:
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From the application dashboard, select Devices on the side navigation menu.
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Select + New to bring up the Create a new device window.
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Leave Device template as Unassigned.
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Fill in the desired Device name and Device ID.
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Select the Create button.
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The newly created device will appear in the All devices list. Select on the device name to show details.
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Select Connect in the top right menu bar to display the connection information used to configure the device in the next section.
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Note the connection values for the following connection string parameters displayed in Connect dialog. You'll add these values to a configuration file in the next step:
ID scope
Device ID
Primary key
To connect the EFR32MG12 MCU Starter Kit to Azure, you'll modify a configuration file for Wi-Fi and Azure IoT settings, rebuild the image, and flash the image to the device.
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Open the following file in a text editor:
getting-started\SiliconLabs\EFR32MG12\app\azure_config.h
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Set the Wi-Fi constants to the following values from your local environment.
Constant name Value WIFI_SSID
{Your Wi-Fi ssid} WIFI_PASSWORD
{Your Wi-Fi password} WIFI_MODE
{One of the enumerated Wi-Fi mode values in enum sl_wfx_security_mode_t.} -
Set the Azure IoT device information constants to the values that you saved after you created Azure resources.
Constant name Value IOT_DPS_ID_SCOPE
{Your ID scope value} IOT_DPS_REGISTRATION_ID
{Your Device ID value} IOT_DEVICE_SAS_KEY
{Your Primary key value} -
Save and close the file.
In your console or in File Explorer, run the script rebuild.bat at the following path to build the image:
getting-started\SiliconLabs\EFR32MG12\tools\rebuild.bat
After the build completes, confirm that the binary file was created in the following path:
getting-started\SiliconLabs\EFR32MG12\build\app\efm32mg12_azure_iot.bin
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Connect the Mighty Gecko radio board to the EFR32MG12 MCU Starter Kit
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Connect the WF200 Wi-Fi EXP Board to the EFR32MG12 MCU Starter Kit
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Ensure that the power selector switch on the EFR32MG12 MCU Starter Kit is in the [AEM] position.
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Ensure the WF200 EXP Board is switched to SPI mode
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Connect EFR32MG12 MCU Starter Kit to the PC using the USB Mini-B cable.
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Click [Tools] on toolbar of Simplicity Studio to open Simplicity Commander.
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Simplicity Commander opens in a disconnected state. Click [Connect] to connect to the target device, then click [Flash] icon as step 1, 2 in image below.
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Browse to the image file (efm32mg12_azure_iot.bin) that you created in the previous section, and click [Flash] button on Simplicity Commander Window as step 3, 4 in image below. The flashing process starts automatically.
You can use the Termite utility to monitor communication and confirm that your device is set up correctly.
Note: If you have issues getting your device to initialize or connect after flashing, see Troubleshooting.
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Start Termite.
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Select Settings.
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In the Serial port settings dialog, check the following settings and update if needed:
- Baud rate: 115,200
- Port: The port that your EFR32MG12 MCU Starter Kit is connected to. If there are multiple port options in the dropdown, you can find the correct port to use. Open Windows Device Manager, and view Ports to identify which port to use.
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Select OK.
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Press the Reset button on the device.
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In the Termite console, check the following checkpoint values to confirm that the device is initialized and connected to Azure IoT.
Starting Azure thread WF200 Firmware version 3.7.0 WF200 initialization successful Connecting to SSID: *** Connected Initializing DHCP IP address: 10.0.0.73 Mask: 255.255.255.0 Gateway: 10.0.0.1 SUCCESS: DHCP initialized Initializing DNS client DNS address: 10.0.0.1 SUCCESS: DNS client initialized Initializing SNTP client SNTP server 0.pool.ntp.org SNTP IP address: 23.157.160.168 SNTP time update: Aud 13, 2021 5:14:13.903 UTC SUCCESS: SNTP initialized Initializing Azure IoT DPS client DPS endpoint: global.azure-devices-provisioning.net DPS ID scope: *** Registration ID: *** SUCCESS: Azure IoT DPS client initialized Initializing Azure IoT Hub client Hub hostname: *** Device id: *** Model id: dtmi:azurertos:devkit:gsg;2 Connected to IoT Hub SUCCESS: Azure IoT Hub client initialized Starting Main loop
Keep Termite open to monitor device output in the following steps.
To view the device status in IoT Central portal:
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From the application dashboard, select Devices on the side navigation menu.
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Check the Device status of the device is updated to Provisioned.
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Check the Device template of the device has updated to Getting Stared Guide.
With IoT Central, you can view the flow of telemetry from your device to the cloud.
To view telemetry in IoT Central portal:
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From the application dashboard, select Devices on the side navigation menu.
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Select the device from the device list.
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View the telemetry as the device sends messages to the cloud in the Overview tab.
Note: You can also monitor telemetry from the device by using the Termite terminal.
You can also use IoT Central to call a direct method that you have implemented on your device. Direct methods have a name, and can optionally have a JSON payload, configurable connection, and method timeout. In this section, you call a method that enables you to turn an LED on or off.
To call a method in IoT Central portal:
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Select Command tab from the device page.
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Select State and select Run. The LED light should turn on.
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Unselect State and select Run. The LED light should turn off.
You can view the device information from IoT Central.
Select About tab from the device page.
For debugging the application, see Debugging with Visual Studio Code.
If you no longer need the Azure resources created in this tutorial, you can delete them from the IoT Central portal. Optionally, if you continue to another tutorial in this Getting Started guide, you can keep the resources you've already created and reuse them.
To keep the Azure IoT Central sample application but remove only specific devices:
- Select the Devices tab for your application.
- Select the device from the device list.
- Select Delete.
To remove the entire Azure IoT Central sample application and all its devices and resources:
- Select Administration > Your application.
- Select Delete.
In this tutorial you built a custom image that contains Azure RTOS sample code, and then flashed the image to the EFR32MG12 MCU Starter Kit. You also used the IoT Central portal to create Azure resources, connect the EFR32MG12 MCU Starter Kit securely to Azure, view telemetry, and send messages.
- For device developers, the suggested next step is to see the other tutorials in the series Getting started with Azure RTOS.
- If you have issues getting your device to initialize or connect after following the steps in this guide, see Troubleshooting.
- To learn more about how Azure RTOS components are used in the sample code for this tutorial, see Using Azure RTOS in the Getting Started Guides.
Note: Azure RTOS provides OEMs with components to secure communication and to create code and data isolation using underlying MCU/MPU hardware protection mechanisms. However, each OEM is ultimately responsible for ensuring that their device meets evolving security requirements.