How to read data from micro:bit via Bluetooth on Linux.
Maybe due to the Bluetooth Low Energy protocol or implementation, I have not found the possibility to create a serial device in Linux. So the simplest way to read data from the micro:bit is Python. In this case I use bluepy https://github.com/IanHarvey/bluepy
For testing purposes, you can use the bluetoothctl
, hcidump
(to sniff the bluetooth communication) and gatttool
commands from bluez package.
In the micro:bit device, using MakeCode, it is possible to enable UART in order to send and receive arbitrary data to and from the connected device. In order to get data from UART, you have to enable notification, writing "0200" on the Client Characteristic Configuration Descriptor (CCCD) of the UART Service Characteristic. The CCCD is 2902.
Using UART there is a known issue: https://lancaster-university.github.io/microbit-docs/ble/uart-service/#example-microbit-application-animal-vegetable-mineral-game [...] This prevents the event handler from exiting. Under normal circumstances this is fine. If however the connected application loses its connection and then reconnects, the onConnected method will not execute and therefore the 'connected' variable which tracks the Bluetooth connection state will not update. The micro:bit application will now behave as though it is not in a connection and therefore functions such as sending text by pressing a button will not work. In this situation the user should simply reset their micro:bit and reconnect their smartphone application. An API which allows serial reads to unblock or perhaps threads to be terminated is under consideration for a future release of the micro:bit runtime."
In short: if the connection is interrupted, or the Phyton program exits without sending the disconnection message, the "forever block" containing the "Bluetooth UART write" block seems to get stuck. Even after reconnection (or rather starting the Python program again), there is no way to read any data. This lead to the need to reset the micro:bit.
Please remember that, every time you upload new code to the micro:bit, you have to pair again the device.
Link to the MakeCode project: https://makecode.microbit.org/_XXD3iuF36HCF.
Please note the reset block. In the Python program, if we will not receive any notification (aka data from UART) for a while, we will reset the device, then try to reconnect: this is a kind of workaround for the known issue described before.
Link to the MakeCode project: https://makecode.microbit.org/_6fT9haLmrFkC.
See MakeCode Bluetooth Pairing for instructions on how to put the micro:bit pairing mode (A+B, + reset, release reset, release A+B).
$ bluetoothctl [NEW] Controller YY:YY:YY:YY:YY:YY pc [default] Agent registered [bluetooth]# scan on Discovery started [CHG] Controller YY:YY:YY:YY:YY:YY Discovering: yes [NEW] Device XX:XX:XX:XX:XX:XX BBC micro:bit [pogeg] [bluetooth]# pair XX:XX:XX:XX:XX:XX Attempting to pair with XX:XX:XX:XX:XX:XX ... [bluetooth]# scan off
Usage examples
[bluetooth]# connect XX:XX:XX:XX:XX:XX Attempting to connect to XX:XX:XX:XX:XX:XX [CHG] Device XX:XX:XX:XX:XX:XX Connected: yes [CHG] Device XX:XX:XX:XX:XX:XX Name: BBC micro:bit [CHG] Device XX:XX:XX:XX:XX:XX Alias: BBC micro:bit Connection successful ... [BBC micro:bit]# list-attributes ... [BBC micro:bit]# select-attribute 00002a26-0000-1000-8000-00805f9b34fb [BBC micro:bit:/service000f/char0014]# read Attempting to read /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/service000f/char0014 [CHG] Attribute /org/bluez/hci0/dev_XX_XX_XX_XX_XX_XX/service000f/char0014 Value: 32 2e 30 2e 30 2d 72 63 39 2d 2d 67 2.0.0-rc9--g 32 2e 30 2e 30 2d 72 63 39 2d 2d 67 2.0.0-rc9--g [BBC micro:bit:/service000f/char0014]# disconnect Attempting to disconnect from XX:XX:XX:XX:XX:XX [CHG] Device XX:XX:XX:XX:XX:XX ServicesResolved: no Successful disconnected [CHG] Device XX:XX:XX:XX:XX:XX Connected: no [CHG] Device YY:YY:YY:YY:YY:YY RSSI: -71
Test UART data (we have to select TX characteristic). Note that read method is pointless, we have to use notification in order to get useful data. Conversely, in order to get temperature data, we can use read or notification. This is valid also for the Python programs.
[BBC micro:bit]# select-attribute 6e400002-b5a3-f393-e0a9-e50e24dcca9e [BBC micro:bit:/service0021/char0022]# attribute-info Characteristic - Nordic UART TX UUID: 6e400002-b5a3-f393-e0a9-e50e24dcca9e Service: /org/bluez/hci0/dev_E4_6D_B6_FC_83_A8/service0021 Value: 00 . Notifying: no Flags: indicate [BBC micro:bit:/service0021/char0022]# notify on ... [CHG] Attribute /org/bluez/hci0/dev_E4_6D_B6_FC_83_A8/service0021/char0022 Value: 34 30 33 39 4039 [CHG] Attribute /org/bluez/hci0/dev_E4_6D_B6_FC_83_A8/service0021/char0022 Value: 34 30 34 32 4042 [BBC micro:bit:/service0021/char0022]# notify off [CHG] Attribute /org/bluez/hci0/dev_E4_6D_B6_FC_83_A8/service0021/char0022 Notifying: no Notify stopped
To read the temperature value.
$ sudo gatttool -b E4:6D:B6:FC:83:A8 -I -t random [XX:XX:XX:XX:XX:XX][LE]> connect Attempting to connect to XX:XX:XX:XX:XX:XX Connection successful [XX:XX:XX:XX:XX:XX][LE]> primary attr handle: 0x0001, end grp handle: 0x0007 uuid: 00001800-0000-1000-8000-00805f9b34fb attr handle: 0x0008, end grp handle: 0x000b uuid: 00001801-0000-1000-8000-00805f9b34fb attr handle: 0x000c, end grp handle: 0x000e uuid: e95d93b0-251d-470a-a062-fa1922dfa9a8 attr handle: 0x000f, end grp handle: 0x0015 uuid: 0000180a-0000-1000-8000-00805f9b34fb attr handle: 0x0016, end grp handle: 0x0020 uuid: e95d93af-251d-470a-a062-fa1922dfa9a8 attr handle: 0x0021, end grp handle: 0xffff uuid: e95d6100-251d-470a-a062-fa1922dfa9a8 [XX:XX:XX:XX:XX:XX][LE]> char-desc 0x0021 0xffff handle: 0x0021, uuid: 00002800-0000-1000-8000-00805f9b34fb handle: 0x0022, uuid: 00002803-0000-1000-8000-00805f9b34fb handle: 0x0023, uuid: e95d9250-251d-470a-a062-fa1922dfa9a8 handle: 0x0024, uuid: 00002902-0000-1000-8000-00805f9b34fb handle: 0x0025, uuid: 00002803-0000-1000-8000-00805f9b34fb handle: 0x0026, uuid: e95d1b25-251d-470a-a062-fa1922dfa9a8 [XX:XX:XX:XX:XX:XX][LE]> char-read-hnd 0x0023 Indication handle = 0x000a value: 0c 00 ff ff Characteristic value/descriptor: 19
19 is in sint8, that is 25 in decimal.
To read the notification interval (Temperature Interval) of the temperature (when enabled, see below).
[E4:6D:B6:FC:83:A8][LE]> char-read-hnd 0x0026 Characteristic value/descriptor: e8 03
e8 08
that is 59395 milliseconds (UINT16 - Big Endian (AB))
So to receive temperature updates (as seen before, every 1 second circa) we have to write 0100
to the Client Characteristic Configuration Descriptor (CCCD), and 0000
in order to stop notifications.
[XX:XX:XX:XX:XX:XX][LE]> char-write-req 0x0024 0100 Characteristic value was written successfully Notification handle = 0x0023 value: 19 Notification handle = 0x0023 value: 19 Notification handle = 0x0023 value: 19 Notification handle = 0x0023 value: 19 Notification handle = 0x0023 value: 19 Notification handle = 0x0023 value: 19 Notification handle = 0x0023 value: 19 Notification handle = 0x0023 value: 19 Notification handle = 0x0023 value: 19 [XX:XX:XX:XX:XX:XX][LE]> char-write-req 0x0024 0000 Characteristic value was written successfully
Please note: the value to write to the UART CCCD in order to enable notifications is 0200
and not 0100
These are the services that we will use in the Python program.
For UART
Type | UUID | Description |
---|---|---|
Primary Service | 6e400001-b5a3-f393-e0a9-e50e24dcca9e | Nordic UART Service |
Descriptor | 00002902-0000-1000-8000-00805f9b34fb | Client Characteristic Configuration |
Characteristic | 6e400002-b5a3-f393-e0a9-e50e24dcca9e | Nordic UART TX |
Characteristic | 6e400003-b5a3-f393-e0a9-e50e24dcca9e | Nordic UART RX |
For temperature sensor
Type | UUID | Description |
---|---|---|
Primary Service | e95d6100-251d-470a-a062-fa1922dfa9a8 | MicroBit Temperature Service |
Descriptor | 00002902-0000-1000-8000-00805f9b34fb | Client Characteristic Configuration |
Characteristic | e95d9250-251d-470a-a062-fa1922dfa9a8 | Vendor specific (the temperature value) |
Characteristic | e95d1b25-251d-470a-a062-fa1922dfa9a8 | MicroBit Temperature Period |
For the accelerometer
Type | UUID | Description |
---|---|---|
Primary Service | e95d0753-251d-470a-a062-fa1922dfa9a8 | MicroBit Accelerometer Service |
Descriptor | 00002902-0000-1000-8000-00805f9b34fb | Client Characteristic Configuration |
Characteristic | e95dca4b-251d-470a-a062-fa1922dfa9a8 | MicroBit Accelerometer Data |
Characteristic | e95dfb24-251d-470a-a062-fa1922dfa9a8 | MicroBit Accelerometer Period |
Accelerometer Data contains accelerometer measurements for X, Y and Z axes as 3 signed 16 bit values in that order and in little endian format.
MicroBit Accelerometer Period determines the frequency with which accelerometer data is reported in milliseconds; valid values are 1, 2, 5, 10, 20, 80, 160 and 640. So "8002" is 640, "A000" is 160, "1400" is 20, "0200" is 2 and so on. Note: 1 millisecond (that is "0100") seems to be invalid.
- micro:bit Bluetooth profile specification: https://lancaster-university.github.io/microbit-docs/resources/bluetooth/bluetooth_profile.html
- micro:bit Bluetooth UART Service: https://lancaster-university.github.io/microbit-docs/ble/uart-service/#bluetooth-uart-service
- MakeCode Bluetooth Pairing: https://makecode.microbit.org/reference/bluetooth/bluetooth-pairing
- bluepy, a Bluetooth LE interface for Python documentation: http://ianharvey.github.io/bluepy-doc/
I'm not a Python developer and my knowledge of Bluetooth protocol is close to zero. So sorry for the imperfections.