This repo contains a collection of BLE example applications based on mbed OS and built with mbed-cli. Each example subdirectory contains a separate mbed-cli module meant for building an executable.
Please browse to subdirectories for specific documentation.
To build these examples, you need to have a computer with the following software installed:
- CMake.
- mbed-cli. Please note that mbed-cli has its own set of dependencies, listed in the installation instructions.
- Python.
- ARM GCC toolchain.
- A serial terminal emulator (e.g. screen, pySerial, cu).
- If the OS used is Windows, the serial driver of the board has to be correctly installed.
- For boards with mbed interface firmware the installation instructions are located (here)[https://developer.mbed.org/handbook/Windows-serial-configuration]
- For nrf51-based board with a J-Link interface please install the J-Link software and documentation pack available (here)[https://www.segger.com/jlink-software.html]
In order to use BLE in mbed OS you need one of the following hardware combinations:
- A Nordic nRF51-based board such as nrf51dk or mkit.
- A supported target, such as the NUCLEO-F411RE, with a BLE shield or an external BLE peripheral, such as an ST shield.
The ble
module provides the BLE APIs on mbed OS.
The following targets have been tested and work with these examples:
-
Nordic:
- NRF51_DK
- NRF52_DK
-
Boards with an ST shield plugged in:
- K64F
- NUCLEO_F401RE
Important: if an ST shield is used with the K64F board, an hardware is patch required. Check out https://developer.mbed.org/teams/ST/code/X_NUCLEO_IDB0XA1/ for more information.
It is possible to use the ST Nucleo shield on boards not directly supported by these examples as long as the board has an Arduino UNO R3 connector.
To makes the board compatible with the ST shield three things are required:
- Add the BLE feature to your target.
- Add the BLE implementation for the ST shield to the list of modules which have to be compiled.
- Indicate to the BLE implementation that your board use an Arduino connector.
All these operations can be done in the file mbed_app.json
present in every example.
In the section target_overrides
add a new object named after your target.
In this object three fields are required:
"target.features_add": ["BLE"]
Add the BLE feature to the target."target.extra_labels_add": ["ST_BLUENRG"]
: Add the BLE implementation of the ST shield to the list of the application modules."target.macros_add": ["IDB0XA1_D13_PATCH"]
: Indicate the BLE implementation that the target use an arduino connector.
As an example, this is the JSON bit which has to be added in the target_overrides
section of mbed_app.json
for a NUCLEO_F411RE
board.
"NUCLEO_F411RE": {
"target.features_add": ["BLE"],
"target.extra_labels_add": ["ST_BLUENRG"],
"target.macros_add": ["IDB0XA1_D13_PATCH"]
},
Note: You can get more informations about the configuration system in the documentation
Important: It is required to apply an hardware patch to the ST shield if it is used on a board with an Arduino connector. Check out https://developer.mbed.org/teams/ST/code/X_NUCLEO_IDB0XA1/ for more information.
To build an example:
-
Clone the repository containing the collection of examples:
$ git clone https://github.com/ARMmbed/mbed-os-example-ble.git
Tip: If you don't have GitHub installed, you can download a zip file of the repository.
-
Using a command-line tool, navigate to any of the example directories, like BLE_Beacon:
$ cd mbed-os-example-ble $ cd BLE_Beacon
-
Update the source tree:
mbed update
-
Run the build:
mbed compile -t <ARM | GCC_ARM> -m <YOUR_TARGET>
To run the application on your board:
-
Connect your mbed board to your computer over USB. It appears as removable storage.
-
When you run the
mbed compile
command, as you did above, mbed cli creates a BIN or an HEX file in a.build/<target-name>/<toolchain>
directory under the example's directory. Drag and drop the file to the removable storage.
Exactly which executables are generated depends on the target that you have chosen. For Nordic Semiconductor targets, the following .hex files will be present:
<module_name>.hex
is the one which can be flashed to the target.<module_name>.elf
is an ELF binary containing symbols (useful for debugging).
If you're interested in creating BLE applications for mbed OS, or porting existing applications from mbed Classic to mbed OS, please see our Introduction to mbed BLE.