nRF Toolbox

The nRF Toolbox is a container app that stores your Nordic Semiconductor apps for Bluetooth Low Energy in one location.

It contains applications demonstrating standard Bluetooth LE profiles:

Since version 1.10.0 the nRF Toolbox also supports the Nordic UART Service which may be used for bidirectional text communication between devices.

Note: To get a smaller version, with only the DFU profile, switch to the only_dfu branch (this branch is not maintained anymore, so you have to update it on your own).

How to import to Android Studio

The production version of nRF Toolbox depends on Android BLE Library and demonstrates use of the Android BLE Common Library (ble-common module), which provides parsers for common profiles adopted by Bluetooth SIG. Both libraries are available on jcenter.

You may also include the BLE Library and BLE Common Library as modules. Clone the library project to the same root folder.

If you are having issue like #40 or #41, the correct folders structure should look like this:

Folders structure

If you prefer a different name for BLE library, update the settings.gradle file.

DFULibrary folder is optional, as the library is downloaded from jcenter repository automatically. Clone it only when you want to modify the code (not recommended).

If you get "Missing Feature Watch" error, switch the configuration to 'app'.

BleManager and how to use it

There are 4 different solutions how to use the manager shown in different profiles. The very basic approach is used by the BPM, HRM and GLS profiles. Each of those activities holds a static reference to the manager. Keeping the manager as a static object protects from disposing it when device orientation changes and the activities are being destroyed and recreated. However, this approach does not allow to keep the connections in background mode and therefore is not a solution that should be used in any production-ready application.

A better implementation may be found in CSC, RSC, HTM and CGM. The BleManager instance is maintained by the running service. The service is started in order to connect to a device and stopped when user decides to disconnect from it. When an activity is destroyed it unbinds from the service, but the service is still running, so the incoming data may continue to be handled. All device-related data are kept be the service and may be obtained by a new activity when it binds to it in order to be shown to the user.

As a third, the Proximity profile allows to connect to multiple sensors at the same time. It uses a different service implementation but still the BleManager is used to manage each connection. If the useAutoConnect(boolean) method returns true for a connection, the manager will try to reconnect automatically to the device if a link was lost. You will also be notified about a device that got away using onDeviceDisconnected(ConnectionObserver.REASON_LINK_LOSS).

The BleMulticonnectProfileService implementation, used by Proximity profile, does not save addresses of connected devices. When the service is killed it will not be able to reconnect to them after it's restarted, so this feature has been disabled. Also, when user removes the nRF Toolbox app from Recents, the service will be killed and all devices will be disconnected automatically. To change this behaviour a service would have to either save the addresses and reconnect to devices after it has restarted (but then removing the app from Recents would cause disconnection and immediate reconnection as the service is then killed and moved to another process), or would have to be implemented in a way that is using another process. Then, however, it is not possible to bind to such service and data must be exchanged using a Messenger. Such approach is not demonstrated in nRF Toolbox.

At last, the BleManager can be accessed from a ViewModel (see Architecture Components). Check out the Android nRF Blinky app for sample code.

Nordic UART Service

The UART profile allows for fast prototyping of devices. The service itself it very simple, having just 2 characteristics, one for sending data and one for receiving. The data may be any byte array but it is very often used with just text. Each UART configuration in the nRF Toolbox consists of 9 programmable buttons. Each of them, when pressed, will send the stored command to the device. You may export your configuration to XML and share between other devices. Swipe the screen to right to show the log with all events.

Since nRF Toolbox version 1.16.0 the UART profile supports also Google Wear OS devices (watches). If you have a Wear OS watch, the application will automatically be installed on it after you install or update the application on the phone. Before you start playing with the watch, please open the UART profile on the phone so it could share your configurations to all wearables.

Android Wear 2.0 support has been added in nRF Toolbox version 2.2.2. Now, after installing the app on the phone, you will be notified on the watch to download the watch-APK onto the watch. The app on the watch is not standalone. UART configurations must be configured on the phone.

The wearable application may work in 2 modes: as a remote control of the phone, or directly connected to a UART device.

  1. Connect your phone to the UART device. After few seconds you should get a notification on the watch that your device is now connected. Swipe it left to see Disconnect button (will send a message to the phone to terminate the connection with UART target) and Open button. Click the Open button to see a list of your UART configurations. Click one and see the list of active buttons. When pressed the button will send a message to the phone using Google Play Services and the phone will send the command to the target device. In this mode you may have more than one watch connected to the phone and use both as remote controls.

    Scenario 1

  2. Open the applications menu on Android Wear watch and click nRF Toolbox. The watch will now scan for all nearby Bluetooth LE devices and show you them on a list. Select your UART device to connect to it. A list of your configurations will be shown, like in 1. As that was a direct connection from the watch to the UART target the phone, or any other watch will not be notified about it.

    Scenario 2

Device Firmware Update

The Device Firmware Update (DFU) profile allows you to update the application, bootloader and/or the Soft Device image over-the-air (OTA). It is compatible with Nordic Semiconductor nRF5 devices that have the SoftDevice and DFU Bootloader flashed. From version 1.11.0 onward, the nRF Toolbox has allowed to send the init packet (required since SDK 7.0). More information about the init packet may be found here: init packet handling.

The DFU has the following features:

DFU Settings

To open the DFU settings click the Settings button in the top toolbar when on DFU profile.

Packet receipt notification procedure - This switch allows you to turn on and off the packet receipt notification procedure. During the DFU operation the phone sends 20-bytes size packets to t he DFU target. It may be configured that once every N packets the phone stops sending and awaits for the Packet Receipt Notification from the device. This feature is required by Android to sync sending data with the remote device, as the callback onCharacteristicWrite(...) that follows calling method gatt.writeCharacteristic(...) is invoked when the packet is written to the outgoing queue, not when physically transmitted. With this procedure disabled it may happen that the outgoing buffer will be overloaded and the communication stops. The same error may happen when the N number is too big, about 300-400. The receipt notification ensures that the outgoing queue is empty and the DFU target received all packets successfully.

Note: Android 6.0 and newer does not require this option to be enabled. The buffer overflow is now handled correctly and the upload speed is much higher with this option disabled.

Number of packets - This field allows you to set the N number describe above. By default it is set to 12. Depending on the phone model, devices may send and receive different number of packets in each connection interval. Nexus 4, for instance, may send just 1 packet (and receive 3 notifications) while Nexus 5 or 6 send and receive up to 4 packets. By customizing this value you may check which value allows for the fastest transmission on your phone/tablet.

MBR size - This value is used only to convert HEX files into BIN files. If your packet is already in the BIN format, this value is ignored. The data from addresses lower then this value are being skipped while converting HEX to BIN. This is to prevent from sending the MBR (Master Boot Record) part from the HEX file that contains the Soft Device. The compiled Soft Device contains data that starts at address 0x0000 and contains the MBR. It is followed by the jump to address 0x1000 (default MBR size) where the Soft Device firmware starts. Only the Soft Device part must be sent over DFU.

Keep bond information - When upgrading the application on a bonded device the DFU bootloader may be configured to preserve some pages of the application's memory intact, so that the new application may read them. The new application must know the old data format in order to read them correctly. Our HRS DFU sample stores the Long Term Key (LTK) and the Service Attributes in two first pages. However, the DFU Bootloader, by default, clears the whole application's memory when the new application upload completes, and the bond information is lost. In order to configure the number of pages to be preserved set the DFU_APP_DATA_RESERVED value in the dfu_types.h file in the DFU bootloader code (line ~56). To preserve two pages the value should be set to 0x0800. When your DFU bootloader has been modified to keep the bond information after updating the application set the switch to ON. Otherwise the bond information will be removed from the phone.

External MCU DFU - The DFU service from the library, when connected to a DFU target, will check whether it is in application or in DFU bootloader mode. For DFU implementations from SDK 7.0 or newer this is done by reading the value of DFU Version characteristic. If the returned value is equal to 0x0100 (major = 0, minor = 1) it means that we are in the application mode and jump to the bootloader mode is required.

However, for DFU implementations from older SDKs, where there was no DFU Version characteristic, the service must guess. If this option is set to false (default) it will count number of device's services. If the count is equal to 3 (Generic Access, Generic Attribute, DFU Service) it will assume that it's in DFU mode. If greater than 3 - in app mode.

This guessing may not be always correct. One situation may be when the nRF chip is used to flash update on an external MCU using DFU. The DFU procedure may be implemented in the application, which may (and usually does) have more services. In such case set the value of this property to true.


nRF Toolbox depends on Android BLE Library which has to be cloned into the same root folder as this app. If you prefer a different name, update the settings.gradle file.

In order to compile the project the DFU Library is required. This project may be found here: Since version 1.16.1 it is imported automatically from jcenter repository and no special configuration is needed. If you want to make some modifications in the DFU Library, please clone the DFU Library to the same root as nRF Toolbox is cloned and name the library's folder DFULibrary. Add the dfu module in Project Structure and edit app/build.gradle file and settings.gradle files as describe in them.

The nRF Toolbox also uses the nRF Logger API library which may be found here: The library is included in dependencies in build.gradle file. This library allows the app to create log entries in the nRF Logger application. Please, read the library documentation on GitHub for more information about the usage and permissions.

The graph in HRM profile is created using the AChartEngine v1.1.0 contributed based on the Apache 2.0 license.