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Find RuuviTag sensor beacons and get data from selected sensor and decode data from eddystone url

Project description

Codeship Status for ttu/ruuvitag-sensor PyPI

RuuviTag Sensor is a Python library for communicating with RuuviTag BLE Sensor Beacon and for decoding sensord data from broadcasted eddystone-url.


  • RuuviTag with Weather Station firmware

  • Python 2.7 and 3

    • psutil

      • Package uses psutil to start and stop processes. Psutil requires sudo apt-get install python-dev python-psutil or sudo apt-get install python3-dev python3-psutil

  • Linux

    • Package’s Windows and OSX supports are only for testing and url decoding

  • Bluez

    • sudo apt-get install bluez bluez-hcidump

    • Package uses internally hciconfig, hcitool and hcidump. These tools are deprecated. In case tools are missing, older version of Bluez is required (Issue)

  • Superuser rights

    • BlueZ tools require superuser rights

NOTE: Experimental implementation with cross-platform BLE communication in branch: bleson-ble-communication * Uses Bleson module instead of Bluez * More info on issues #31 and #18


Install latest released version

$ pip install ruuvitag_sensor

Install latest developement version

$ pip install git+
# Or clone this repository and install locally
$ pip install -e .

Full installation guide for Raspberry PI & Raspbian


RuuviTag sensors can be identified using MAC addresses.

Get data from sensor

from ruuvitag_sensor.ruuvitag import RuuviTag

sensor = RuuviTag('AA:2C:6A:1E:59:3D')

# update state from the device
state = sensor.update()

# get latest state (does not get it from the device)
state = sensor.state


Get sensor datas with callback

get_datas calls the callback every time when a RuuviTag sensor broadcasts data

from ruuvitag_sensor.ruuvi import RuuviTagSensor

def handle_data(found_data):
    print('MAC ' + found_data[0])


Optional list of macs and run flag can be passed to the get_datas function. Callback is called only for macs in the list and setting run flag to false will stop execution. If run flag is not passed, function will execute forever.

from ruuvitag_sensor.ruuvi import RuuviTagSensor, RunFlag

counter = 10
# RunFlag for stopping execution at desired time
run_flag = RunFlag()

def handle_data(found_data):
    print('MAC ' + found_data[0])
    global counter
    counter = counter - 1
    if counter < 0:
        run_flag.running = False

# List of macs of sensors which will execute callback function
macs = ['AA:2C:6A:1E:59:3D', 'CC:2C:6A:1E:59:3D']

RuuviTagSensor.get_datas(handle_data, macs, run_flag)

Get data for specified sensors

get_data_for_sensors will collect latest data from sensors for specified duration.

from ruuvitag_sensor.ruuvi import RuuviTagSensor

# List of macs of sensors which data will be collected
# If list is empty, data will be collected for all found sensors
macs = ['AA:2C:6A:1E:59:3D', 'CC:2C:6A:1E:59:3D']
# get_data_for_sensors will look data for the duration of timeout_in_sec
timeout_in_sec = 4

datas = RuuviTagSensor.get_data_for_sensors(macs, timeout_in_sec)

# Dictionary will have lates data for each sensor


Reactive wrapper and background process for RuuviTagSensor get_datas. Optional MAC address list can be passed on initializer and execution can be stopped with stop function.

from ruuvitag_sensor.ruuvi_rx import RuuviTagReactive

ruuvi_rx = RuuviTagReactive()

# Print all notifications

# Print only last data every 10 seconds for F4:A5:74:89:16:57
    filter(lambda x: x[0] == 'F4:A5:74:89:16:57').\
    subscribe(lambda datas: print(datas[len(datas) - 1]))

# Execute only every time when temperature changes for F4:A5:74:89:16:57
    filter(lambda x: x[0] == 'F4:A5:74:89:16:57').\
    map(lambda x: x[1]['temperature']).\
    subscribe(lambda x: print('Temperature changed: {}'.format(x)))

# Close all connections and stop bluetooth communication

More samples and simple HTTP server under examples directory.

Check official documentation from RxPy GitHub and RxPY Public API

Find sensors

find_ruuvitags function will exeute forever and when new RuuviTag sensor is found it will print it’s MAC address and state at that moment. This function can be used with a command line applications. Logging must be enabled and set to print to console.

from ruuvitag_sensor.ruuvi import RuuviTagSensor
import ruuvitag_sensor.log



Using different Bluetooth device

If you have multiple Bluetooth devices installed, device to be used might not be the default (Linux: hci0). Device can be passed with bt_device parameter.

from ruuvitag_sensor.ruuvi import RuuviTagSensor
from ruuvitag_sensor.ruuvitag import RuuviTag

sensor = RuuviTag('F4:A5:74:89:16:57', 'hci1')


datas = RuuviTagSensor.get_data_for_sensors(bt_device='hci1')

RuuviTagSensor.get_datas(lambda x: print('%s - %s' % (x[0], x[1]), bt_device=device))

Parse data

from ruuvitag_sensor.ruuvi import RuuviTagSensor
from ruuvitag_sensor.decoder import UrlDecoder

full_data = '043E2A0201030157168974A51F0201060303AAFE1716AAFE10F9037275752E76692F23416A5558314D417730C3'
data = full_data[26:]

# convert_data returns tuple which has Data Format type and encoded data
encoded = RuuviTagSensor.convert_data(data)

sensor_data = UrlDecoder().decode_data(encoded[1])

# {'temperature': 25.12, 'identifier': '0', 'humidity': 26.5, 'pressure': 992.0}

Data Formats

Example data has data from 4 sensors with different firmwares. * 1st is Data Format 2 so identifier is None as sensor doesn’t broadcast any identifier data * 2nd is Data Format 4 and it has an identifier character * 3rd is Data Format 3 * 4th is Data Format 5

'CA:F7:44:DE:EB:E1': { 'data_format': 2, 'temperature': 22.0, 'humidity': 28.0, 'pressure': 991.0, 'identifier': None },
'F4:A5:74:89:16:57': { 'data_format': 4, 'temperature': 23.24, 'humidity': 29.0, 'pressure': 991.0, 'identifier': '0' },
'A3:GE:2D:91:A4:1F': { 'data_format': 3, 'battery': 2899, 'pressure': 1027.66, 'humidity': 20.5, 'acceleration': 63818.215675463696, 'acceleration_x': 200.34, 'acceleration_y': 0.512, 'acceleration_z': -200.42, 'temperature': 26.3},
'CB:B8:33:4C:88:4F': { 'data_format': 5, 'battery': 2.995, 'pressure': 1000.43, 'mac': 'cbb8334c884f', 'measurement_sequence_number': 2467, 'acceleration_z': 1028, 'acceleration': 1028.0389097694697, 'temperature': 22.14, 'acceleration_y': -8, 'acceleration_x': 4, 'humidity': 53.97, 'tx_power': 4, 'movement_counter': 70 }

Logging and Print to console

Logging can be enabled by importing ruuvitag_sensor.log. Console print can be enabled by calling ruuvitag_sensor.log.enable_console(). Command line application has console logging enabled by default.

from ruuvitag_sensor.ruuvi import RuuviTagSensor
import ruuvitag_sensor.log


datas = RuuviTagSensor.get_data_for_sensors()


Command line application

$ python ruuvitag_sensor -h

usage: ruuvitag_sensor [-h] [-g MAC_ADDRESS] [-d BT_DEVICE] [-f] [-l] [-s] [--version]

optional arguments:
  -h, --help            show this help message and exit
                        Get data
  -d BT_DEVICE, --device BT_DEVICE
                        Set Bluetooth device id (default hci0)
  -f, --find            Find broadcasting RuuviTags
  -l, --latest          Get latest data for found RuuviTags
  -s, --stream          Stream broadcasts from all RuuviTags
  --version             show program's version number and exit

Unit Tests

Unit tests use unittest.mock library, so Python 3.3. or newer is required.

Run with nosetests

$ pip install nose
$ nosetests

Run with setup

$ python test

Verification Test

Verification test sciprt executes a set of tests on active RuuviTags. Tests require at least one active RuuviTag and Python 2.7 and 3.x.

$ chmod +x
$ ./


Examples are in examples directory, e.g.




Pull requests are welcome. For major changes, please open an issue first to discuss what you would like to change.


Licensed under the MIT License.

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