Matter: Light switch

This light switch sample demonstrates the usage of the Matter application layer to build a switch device that binds with lighting devices and changes the state of their LEDs. You can use this sample as a reference for creating your own application.

When configured together with the Matter light bulb sample (or other lighting sample) and when using a Matter controller, the light switch can control one light bulb directly or a group of light bulbs remotely over a Matter network built on top of a low-power, 802.15.4 Thread, or on top of a Wi-Fi network. Support for both Thread and Wi-Fi is mutually exclusive and depends on the hardware platform, so only one protocol can be supported for a specific light switch device. Depending on the network you choose:

  • In case of Thread, this device works as a Thread Sleepy End Device.

  • In case of Wi-Fi, this device works in the Legacy Power Save mode. This means that the device sleeps most of the time and wakes up on each Delivery Traffic Indication Message (DTIM) interval to poll for pending messages.

Requirements

The sample supports the following development kits:

Hardware platforms

PCA

Board name

Board target

nRF7002 DK

PCA10143

nrf7002dk

nrf7002dk/nrf5340/cpuapp

nRF54L15 PDK

PCA10156

nrf54l15pdk

nrf54l15pdk/nrf54l15/cpuapp/ns

nRF54L15 DK

PCA10156

nrf54l15dk

nrf54l15dk/nrf54l15/cpuapp

nRF5340 DK

PCA10095

nrf5340dk

nrf5340dk/nrf5340/cpuapp

nRF52840 DK

PCA10056

nrf52840dk

nrf52840dk/nrf52840

For this sample to work, you also need at least one Matter light bulb sample programmed to another supported development kit.

To commission the device and run all required commands, you need also a Matter controller. By default, this sample is configured to use the CHIP Tool as Matter controller. See the Working with the CHIP Tool page in the Matter documentation for the CHIP Tool’s setup information.

If you decide to use Matter CLI commands, you also need a USB cable for the serial connection.

Note

Matter requires the GN tool. If you are updating from the nRF Connect SDK version earlier than v1.5.0, see the GN installation instructions.

IPv6 network support

The development kits for this sample offer the following IPv6 network support for Matter:

  • Matter over Thread is supported for nrf52840dk/nrf52840, nrf5340dk/nrf5340/cpuapp, nrf21540dk/nrf52840, and nrf54l15dk/nrf54l15/cpuapp.

  • Matter over Wi-Fi is supported for nrf5340dk/nrf5340/cpuapp with the nrf7002ek shield attached or for nrf7002dk/nrf5340/cpuapp.

Overview

The sample controls the state of the state-indication LED on connected light bulbs devices. After configuring the light switch sample, the lighting devices get proper Access Control List from the Matter controller to start receiving commands sent from the light switch. Then, the light switch device prepares a new binding table to be able to discover light bulb devices and perform Binding.

After the binding is complete, the application can control the state of the connected lighting devices in one of the following ways:

  • With a single light bulb, it uses a Certificate-Authenticated Session Establishment session (CASE session) for direct communication with the single light bulb.

  • With a group of light bulbs, it uses multicast messages sent through the IPv6 network using Group communication with all light bulbs in the group.

Access Control List

The Access Control List (ACL) is a list related to the Access Control cluster. The list contains rules for managing and enforcing access control for a node’s endpoints and their associated cluster instances. In this sample’s case, this allows the lighting devices to receive messages from the light switch and run them.

You can read more about ACLs on the Access Control Guide in the Matter documentation.

Group communication

Group communication (groupcast or multicast) refers to messages and commands sent to the address of a group that includes multiple devices with the same Groups cluster. The cluster manages the content of a node-wide Group Table that is part of the underlying interaction layer. This is done on per endpoint basis. After creating the Group cluster with specific ID and Name, a device gets its own IPv6 multicast address and is ready to receive groupcast commands.

In this sample, the light switch device is able to create a groupcast message and send it to the chosen IPv6 multicast address. This allows the light switch more than one lighting devices at the same time.

Note

Writing the groupcast table on the devices blocks sending unicast commands. If you want to go back to the original state, perform factory reset of the device.

Binding

Binding refers to establishing a relationship between endpoints on the local and remote nodes. With binding, local endpoints are pointed and bound to the corresponding remote endpoints. Both must belong to the same cluster type. Binding lets the local endpoint know which endpoints are going to be the target for the client-generated actions on one or more remote nodes.

In this sample, the light switch controls one or more lighting devices, but does not know the remote endpoints of the lights (on remote nodes). Using binding, the light switch device updates its Binding cluster with all relevant information about the lighting devices, such as their IPv6 address, node ID, and the IDs of the remote endpoints that contains the On/Off cluster and the LevelControl cluster, respectively.

Configuration

See Configuring and building for information about how to permanently or temporarily change the configuration.

Matter light switch custom configurations

The sample uses a prj.conf configuration file located in the sample root directory for the default configuration. It also provides additional files for different custom configurations. When you build the sample, you can select one of these configurations using the FILE_SUFFIX variable.

See Custom configurations and Providing CMake options for more information.

The sample supports the following configurations:

Sample configurations

Configuration

File name

FILE_SUFFIX

Supported board

Description

Debug (default)

prj.conf

No suffix

All from Requirements

Debug version of the application.

Enables additional features for verifying the application behavior, such as logs.

Release

prj_release.conf

release

All from Requirements

Release version of the application.

Enables only the necessary application functionalities to optimize its performance.

Matter light switch with Trusted Firmware-M

The sample supports using Trusted Firmware-M on the nRF54L15 DK. The memory map of the sample has been aligned to meet the TF-M partition alignment requirements.

You can build the sample with Trusted Firmware-M support by adding the ns suffix to the nrf54l15pdk/nrf54l15/cpuapp build target.

For example:

west build -p -b nrf54l15pdk/nrf54l15/cpuapp/ns

Note

The firmware built for nrf54l15pdk/nrf54l15/cpuapp/ns will not work on the nRF54L15 DK.

Snippets

The sample provides predefined Snippets for typical use cases, and to activate sample extensions. You can find the snippets in the snippets directory of the sample.

Specify the corresponding snippet names in the light_switch_SNIPPET CMake option. For more information about using snippets, see Using Snippets in the Zephyr documentation.

The following snippet is available:

  • lit_icd - Enables experimental LIT ICD support.

    Note

    This snippet requires a custom ZAP configuration, located in the snippets/lit_icd directory. If you need a custom data model, you must configure and generate the correct ZAP files. To do this, run the west zap-generate command and choose the snippets/lit_icd/light_switch.zap file.

FEM support

You can add support for the nRF21540 front-end module to this sample by using one of the following options, depending on your hardware:

  • Build the sample for one board that contains the nRF21540 FEM, such as nrf21540dk/nrf52840.

  • Manually create a devicetree overlay file that describes how FEM is connected to the nRF5 SoC in your device. See Set devicetree overlays for different ways of adding the overlay file.

  • Provide nRF21540 FEM capabilities by using a shield, for example the Developing with the nRF21540 EK shield that is available in the nRF Connect SDK. In this case, build the project for a board connected to the shield you are using with an appropriate variable included in the build command, for example SHIELD=nrf21540ek. This variable instructs the build system to append the appropriate devicetree overlay file.

    To build the sample in the nRF Connect for VS Code IDE for an nRF52840 DK with the nRF21540 EK attached, add the shield variable in the build configuration’s Extra CMake arguments and rebuild the build configuration. For example: -DSHIELD=nrf21540ek.

    See nRF Connect for VS Code extension pack documentation for more information.

    See Programming nRF21540 EK for information about how to program when you are using a board with a network core, for example nRF5340 DK.

Each of these options adds the description of the nRF21540 FEM to the devicetree. See Developing with Front-End Modules for more information about FEM in the nRF Connect SDK.

To add support for other front-end modules, add the respective devicetree file entries to the board devicetree file or the devicetree overlay file.

Device Firmware Upgrade support

Note

You can enable over-the-air Device Firmware Upgrade only on hardware platforms that have external flash memory. Currently only nRF52840 DK, nRF5340 DK, nRF7002 DK and nRF54L15 DK support Device Firmware Upgrade feature.

The sample supports over-the-air (OTA) device firmware upgrade (DFU) using one of the two following protocols:

  • Matter OTA update protocol that uses the Matter operational network for querying and downloading a new firmware image.

  • Simple Management Protocol (SMP) over Bluetooth® LE. In this case, the DFU can be done either using a smartphone application or a PC command line tool. Note that this protocol is not part of the Matter specification.

In both cases, MCUboot secure bootloader is used to apply the new firmware image.

The DFU over Matter is enabled by default. The following configuration arguments are available during the build process for configuring DFU:

  • To configure the sample to support the DFU over Matter and SMP, use the -DCONFIG_CHIP_DFU_OVER_BT_SMP=y build flag.

See Providing CMake options for instructions on how to add these options to your build.

When building on the command line, run the following command with board_target replaced with the board target name of the hardware platform you are using (see Requirements), and dfu_build_flag replaced with the desired DFU build flag:

west build -b board_target -- dfu_build_flag

For example:

west build -b nrf52840dk/nrf52840 -- -DCONFIG_CHIP_DFU_OVER_BT_SMP=y

Factory data support

In this sample, the factory data support is enabled by default for all configurations except for the target board nRF21540 DK. This means that a new factory data set will be automatically generated when building for the target board.

To disable factory data support, set the following Kconfig options to n:

To learn more about factory data, read the Configuring factory data for the nRF Connect examples page in the Matter documentation.

User interface

LED 1:

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 over Bluetooth LE.

  • Solid On - The device is fully provisioned.

LED 2:

The LED starts blinking evenly (500 ms on/500 ms off) when the Identify command of the Identify cluster is received on the endpoint 1. The command’s argument can be used to specify the duration of the effect.

All LEDs:

Blink in unison when the factory reset procedure is initiated.

Button 1:

Depending on how long you press the button:

  • If pressed for less than three seconds:

    • If the device is not provisioned to the Matter network, it initiates the SMP server (Simple Management Protocol) and Bluetooth LE advertising for Matter commissioning. After that, the Device Firmware Update (DFU) over Bluetooth Low Energy can be started. (See Upgrading the device firmware.) Bluetooth LE advertising makes the device discoverable over Bluetooth LE for the predefined period of time (1 hour by default).

    • If the device is already provisioned to the Matter network, it re-enables the SMP server. After that, the DFU over Bluetooth Low Energy can be started. (See Upgrading the device firmware.)

  • If pressed for more than three seconds, it initiates the factory reset of the device. Releasing the button within a 3-second window of the initiation cancels the factory reset procedure.

Button 2:

Controls the light on the bound lighting device. Depending on how long you press the button:

  • If pressed for less than 0.5 seconds, it changes the light state to the opposite one on the bound lighting device (light bulb).

  • If pressed for more than 0.5 seconds, it changes the brightness of the light on the bound lighting bulb device (light bulb). The brightness is changing from 0% to 100% with 1% increments every 300 milliseconds as long as Button 2 is pressed.

Button 3:

Functions as the User Active Mode Trigger (UAT) button. For more information about Intermittently Connected Devices (ICD) and User Active Mode Trigger, see the Enable Matter Intermittently Connected Devices support documentation section.

Note

To enable this functionality, activate the lit_icd snippet. ICD and UAT functionality is currently supported only for Matter over Thread.

SEGGER J-Link USB Port:

Used for getting logs from the device or for communicating with it through the command-line interface.

NFC port with antenna attached:

Optionally used for obtaining the Onboarding information from the Matter accessory device to start the commissioning procedure.

Matter CLI commands

If you build the application with the debug configuration, you can use a series of commands to control the light switch device. These commands can be sent to one device (unicast) or a group of devices (groupcast).

Unicast commands

You can use the following commands for direct communication with the single lighting device:

switch onoff on

This command turns on the state-indication LED on the bound lighting device. For example:

uart:~$ matter switch onoff on
switch onoff off

This command turns off the state-indication LED on the bound lighting device. For example:

uart:~$ matter switch onoff off
switch onoff toggle

This command changes the state of the state-indication LED to the opposite state on the bound lighting device. For example:

uart:~$ matter switch onoff toggle

Groupcast commands

You can use the following commands a group of devices that are programmed with the Light Switch Example application by using the Matter CLI:

switch groups onoff on

This command turns on the state-indication LED on each bound lighting device connected to the same group. For example:

uart:~$ matter switch groups onoff on
switch groups onoff off

This command turns off the state-indication LED on each bound lighting device connected to the same group. For example:

uart:~$ matter switch groups onoff off
switch groups onoff toggle

This command changes the state of the state-indication LED to the opposite state on each bound lighting device connected to the same group. For example:

uart:~$ matter switch groups onoff toggle

Building and running

This sample can be found under samples/matter/light_switch in the nRF Connect SDK folder structure.

To build the sample, follow the instructions in Building an application for your preferred building environment. See also Programming an application for programming steps and Testing and optimization for general information about testing and debugging in the nRF Connect SDK.

Note

When building repository applications in the SDK repositories, building with sysbuild is enabled by default. If you work with out-of-tree freestanding applications, you need to manually pass the --sysbuild parameter to every build command or configure west to always use it.

See Configuration for information about building the sample with the DFU support.

Selecting a configuration

Before you start testing the application, you can select one of the Matter light switch custom configurations. See Custom configurations and Providing CMake options for more information how to select a configuration.

Testing

After building the sample and programming it to your development kit, complete the steps in the following sections.

Prepare for testing

After building this and the Matter Light Bulb samples, and programming them to the development kits, complete the following steps:

Note

In both samples (light switch and light bulb), a Bluetooth LE discriminator is set with the same value by default (hexadecimal: 0xF00; decimal: 3840). This means that only one uncommissioned device can be powered up before commissioning. If both are powered up at the same time, the CHIP Tool can commission a random device and the node ID assignment is also random. When one device is commissioned, power up the next device and perform the commissioning.

To avoid this unclear situation, you can set up your unique discriminator in the src/chip_project_config.h file by changing the CHIP_DEVICE_CONFIG_USE_TEST_SETUP_DISCRIMINATOR value. Then build an example and commission with your unique discriminator.

  1. Connect the kit to the computer using a USB cable. The kit is assigned a COM port (Windows) or ttyACM device (Linux), which is visible in the Device Manager.

  2. Open a serial port connection to the kit using a terminal emulator that supports VT100/ANSI escape characters (for example, nRF Connect Serial Terminal). See Testing and optimization for the required settings and steps.

  3. If the devices were not erased during the programming, press and hold Button 1 on each device until the factory reset takes place.

  4. On each device, press Button 1 to start the Bluetooth LE advertising.

  5. Commission devices to the Matter network. See Commissioning the device for more information.

    During the commissioning process, write down the values for the light switch node ID and the light bulb node ID (or IDs, if you are using more than one light bulb). These IDs are going to be used in the next steps (<light_switch_node_ID> and <light_bulb_node_ID>, respectively).

  6. Use the CHIP Tool (“Writing ACL to the accesscontrol cluster” section) to add proper ACL for the light bulb device. Depending on the number of the light bulb devices you are using, use one of the following commands, with <light_switch_node_ID> and <light_bulb_node_ID> values from the previous step about commissioning:

    • If you are using only one light bulb device, run the following command for the light bulb device:

      chip-tool accesscontrol write acl '[{"fabricIndex": 1, "privilege": 5, "authMode": 2, "subjects": [112233], "targets": null}, {"fabricIndex": 1, "privilege": 3, "authMode": 2, "subjects": [<light_switch_node_ID>], "targets": [{"cluster": 6, "endpoint": 1, "deviceType": null}, {"cluster": 8, "endpoint": 1, "deviceType": null}]}]' <light_bulb_node_ID> 0
      
    • If you are using more than one light bulb device, connect all devices to the multicast group by running the following command for each device, including the light switch:

      chip-tool tests TestGroupDemoConfig --nodeId <node_ID>
      

      Use the <node_ID> values from the commissioning step.

  7. Write a binding table to the light switch to inform the device about all endpoints by running this command (only for light switch):

    • For unicast binding to bind the light switch with only one light Bulb:

      chip-tool binding write binding '[{"fabricIndex": 1, "node": <light bulb node id>, "endpoint": 1, "cluster": 6}, {"fabricIndex": 1, "node": <light bulb node id>, "endpoint": 1, "cluster": 8}]' <light switch node id> 1
      
    • For groupcast binding to bind the light switch with multiple light bulbs:

      chip-tool binding write binding '[{"fabricIndex": 1, "group": 257}]' <light_switch_node_ID> 1
      

All devices are now bound and ready for testing communication.

Note

In this sample, the ACL cluster is inserted into the light bulb’s endpoint 0, and the Binding cluster is inserted into the light switch’s endpoint 1.

Testing with bound light bulbs devices

After preparing devices for testing, you can test the communication of either a single light bulb or of a group of light bulbs with the light switch (but not both a single device and a group at the same time).

Complete the following steps using the light switch device:

  1. On the light switch device, use the buttons to control the bound light bulbs:

    1. Press Button 2 to turn off the state-indication LED located on the bound light bulb device.

    2. Press Button 2 to turn the LED on again.

    3. Press Button 2 and hold it for more than 0.5 seconds to test the dimmer functionality.

      The state-indication LED on the bound light bulb device changes its brightness from 0% to 100% with 1% increments every 300 milliseconds as long as Button 2 is pressed.

  2. Using the terminal emulator connected to the light switch, run the following Matter CLI commands:

    1. Write the following command to turn on state-indication LED located on the bound light bulb device:

      • For a single bound light bulb:

        matter switch onoff on
        
      • For a group of light bulbs:

        matter switch groups onoff on
        
    2. Write the following command to turn off the state-indication LED located on the bound light bulb device:

      • For a single bound light bulb:

        matter switch onoff off
        
      • For a group of light bulbs:

        matter switch groups onoff off
        

Commissioning the device

To commission the device, go to the Testing Matter in the nRF Connect SDK page and complete the steps for the Matter network environment and the Matter controller you want to use. After choosing the configuration, the guide walks you through the following steps:

  • Only if you are configuring Matter over Thread: Configure the Thread Border Router.

  • Build and install the Matter controller.

  • Commission the device.

  • Send Matter commands that cover scenarios described in the Testing section.

If you are new to Matter, the recommended approach is to use CHIP Tool for Linux or macOS.

Before starting the commissioning procedure, the device must be made discoverable over Bluetooth LE. The device becomes discoverable automatically upon the device startup, but only for a predefined period of time (1 hour by default). If the Bluetooth LE advertising times out, enable it again.

Onboarding information

When you start the commissioning procedure, the controller must get the onboarding information from the Matter accessory device. The onboarding information representation depends on your commissioner setup.

For this sample, you can use one of the following onboarding information formats to provide the commissioner with the data payload that includes the device discriminator and the setup PIN code:

Light switch sample onboarding information

QR Code

QR Code Payload

Manual pairing code

Scan the following QR code with the app for your ecosystem:

QR code for commissioning the light switch device

MT:4CT9142C00KA0648G00

34970112332

When the factory data support is enabled, the onboarding information will be stored in the build directory in the following files:

  • The factory_data.png file includes the generated QR code.

  • The factory_data.txt file includes the QR Code Payload and the manual pairing code.

This data payload also includes test Device Attestation, with test Certification Declaration, Product ID, and Vendor ID. These are used for Device Attestation within commissioning, and you can generate your own test Certification Declaration when you work on Matter end product.

Upgrading the device firmware

To upgrade the device firmware, complete the steps listed for the selected method in the Performing Device Firmware Upgrade in the nRF Connect examples tutorial in the Matter documentation.

Dependencies

This sample uses the Matter library that includes the nRF Connect SDK platform integration layer:

In addition, the sample uses the following nRF Connect SDK components:

The sample depends on the following Zephyr libraries: