rtl_433 (despite the name) is a generic data receiver, mainly for the 433.92 MHz, 868 MHz (SRD), 315 MHz, and 915 MHz ISM bands.
It works with RTL-SDR and/or SoapySDR. Activly tested and supported are Realtek RTL2832 based DVB dongles (using RTL-SDR) and LimeSDR (LimeSDR USB and LimeSDR mini engineering samples kindly provided by MyriadRf), PlutoSDR, HackRF One (using SoapySDR drivers), as well as SoapyRemote.
See BUILDING.md
Read the Test Data section at the bottom.
rtl_433 -h
Usage: = Tuner options =
[-d <RTL-SDR USB device index> | :<RTL-SDR USB device serial> | <SoapySDR device query>]
[-g <gain>] (default: auto)
[-f <frequency>] [-f...] Receive frequency(s) (default: 433920000 Hz)
[-H <seconds>] Hop interval for polling of multiple frequencies (default: 600 seconds)
[-p <ppm_error] Correct rtl-sdr tuner frequency offset error (default: 0)
[-s <sample rate>] Set sample rate (default: 250000 Hz)
= Demodulator options =
[-R <device>] Enable only the specified device decoding protocol (can be used multiple times)
[-G] Enable all device protocols, included those disabled by default
[-X <spec> | help] Add a general purpose decoder (-R 0 to disable all other decoders)
[-l <level>] Change detection level used to determine pulses [0-16384] (0 = auto) (default: 0)
[-z <value>] Override short value in data decoder
[-x <value>] Override long value in data decoder
[-n <value>] Specify number of samples to take (each sample is 2 bytes: 1 each of I & Q)
= Analyze/Debug options =
[-a] Analyze mode. Print a textual description of the signal. Disables decoding
[-A] Pulse Analyzer. Enable pulse analysis and decode attempt
[-I] Include only: 0 = all (default), 1 = unknown devices, 2 = known devices
[-D] Print debug info on event (repeat for more info)
[-q] Quiet mode, suppress non-data messages
[-y <code>] Verify decoding of demodulated test data (e.g. "{25}fb2dd58") with enabled devices
= File I/O options =
[-t] Test signal auto save. Use it together with analyze mode (-a -t). Creates one file per signal
Note: Saves raw I/Q samples (uint8 pcm, 2 channel). Preferred mode for generating test files
[-r <filename>] Read data from input file instead of a receiver
[-w <filename>] Save data stream to output file (a '-' dumps samples to stdout)
[-W <filename>] Save data stream to output file, overwrite existing file
[-F] kv|json|csv|syslog|null Produce decoded output in given format. Not yet supported by all drivers.
Append output to file with :<filename> (e.g. -F csv:log.csv), defaults to stdout.
Specify host/port for syslog with e.g. -F syslog:127.0.0.1:1514
[-C] native|si|customary Convert units in decoded output.
[-T] Specify number of seconds to run
[-U] Print timestamps in UTC (this may also be accomplished by invocation with TZ environment variable set).
[-E] Stop after outputting successful event(s)
[-V] Output the version string and exit
[-h] Output this usage help and exit
Use -d, -g, -R, -X, -F, -r, or -w without argument for more help
Supported device protocols:
[01] Silvercrest Remote Control
[02] Rubicson Temperature Sensor
[03] Prologue Temperature Sensor
[04] Waveman Switch Transmitter
[05]* Steffen Switch Transmitter
[06]* ELV EM 1000
[07]* ELV WS 2000
[08] LaCrosse TX Temperature / Humidity Sensor
[10]* Acurite 896 Rain Gauge
[11] Acurite 609TXC Temperature and Humidity Sensor
[12] Oregon Scientific Weather Sensor
[13]* Mebus 433
[14]* Intertechno 433
[15] KlikAanKlikUit Wireless Switch
[16] AlectoV1 Weather Sensor (Alecto WS3500 WS4500 Ventus W155/W044 Oregon)
[17] Cardin S466-TX2
[18] Fine Offset Electronics, WH2, WH5, Telldus Temperature/Humidity/Rain Sensor
[19] Nexus Temperature & Humidity Sensor
[20] Ambient Weather Temperature Sensor
[21] Calibeur RF-104 Sensor
[22]* X10 RF
[23] DSC Security Contact
[24]* Brennenstuhl RCS 2044
[25] GT-WT-02 Sensor
[26] Danfoss CFR Thermostat
[27]* Energy Count 3000 (868.3 MHz)
[28]* Valeo Car Key
[29] Chuango Security Technology
[30] Generic Remote SC226x EV1527
[31] TFA-Twin-Plus-30.3049 and Ea2 BL999
[32] Fine Offset Electronics WH1080/WH3080 Weather Station
[33] WT450
[34] LaCrosse WS-2310 Weather Station
[35] Esperanza EWS
[36] Efergy e2 classic
[37]* Inovalley kw9015b, TFA Dostmann 30.3161 (Rain and temperature sensor)
[38] Generic temperature sensor 1
[39] WG-PB12V1
[40] Acurite 592TXR Temp/Humidity, 5n1 Weather Station, 6045 Lightning
[41] Acurite 986 Refrigerator / Freezer Thermometer
[42] HIDEKI TS04 Temperature, Humidity, Wind and Rain Sensor
[43] Watchman Sonic / Apollo Ultrasonic / Beckett Rocket oil tank monitor
[44] CurrentCost Current Sensor
[45] emonTx OpenEnergyMonitor
[46] HT680 Remote control
[47] S3318P Temperature & Humidity Sensor
[48] Akhan 100F14 remote keyless entry
[49] Quhwa
[50] OSv1 Temperature Sensor
[51] Proove
[52] Bresser Thermo-/Hygro-Sensor 3CH
[53] Springfield Temperature and Soil Moisture
[54] Oregon Scientific SL109H Remote Thermal Hygro Sensor
[55] Acurite 606TX Temperature Sensor
[56] TFA pool temperature sensor
[57] Kedsum Temperature & Humidity Sensor
[58] blyss DC5-UK-WH (433.92 MHz)
[59] Steelmate TPMS
[60] Schrader TPMS
[61]* LightwaveRF
[62] Elro DB286A Doorbell
[63] Efergy Optical
[64] Honda Car Key
[67] Radiohead ASK
[68] Kerui PIR Sensor
[69] Fine Offset WH1050 Weather Station
[70] Honeywell Door/Window Sensor
[71] Maverick ET-732/733 BBQ Sensor
[72]* RF-tech
[73] LaCrosse TX141-Bv2/TX141TH-Bv2 sensor
[74] Acurite 00275rm,00276rm Temp/Humidity with optional probe
[75] LaCrosse TX35DTH-IT, TFA Dostmann 30.3155 Temperature/Humidity sensor
[76] LaCrosse TX29IT Temperature sensor
[77] Vaillant calorMatic 340f Central Heating Control
[78] Fine Offset Electronics, WH25, WH24, WH65B, HP1000 Temperature/Humidity/Pressure Sensor
[79] Fine Offset Electronics, WH0530 Temperature/Rain Sensor
[80] IBIS beacon
[81] Oil Ultrasonic STANDARD FSK
[82] Citroen TPMS
[83] Oil Ultrasonic STANDARD ASK
[84] Thermopro TP11 Thermometer
[85] Solight TE44
[86] Wireless Smoke and Heat Detector GS 558
[87] Generic wireless motion sensor
[88] Toyota TPMS
[89] Ford TPMS
[90] Renault TPMS
[91]* inFactory
[92] FT-004-B Temperature Sensor
[93] Ford Car Key
[94] Philips outdoor temperature sensor
[95] Schrader TPMS EG53MA4
[96] Nexa
[97] Thermopro TP08/TP12 thermometer
[98] GE Color Effects
[99] X10 Security
[100] Interlogix GE UTC Security Devices
[101]* Dish remote 6.3
[102] SimpliSafe Home Security System (May require disabling automatic gain for KeyPad decodes)
[103] Sensible Living Mini-Plant Moisture Sensor
[104]* Wireless M-Bus, Mode C&T, 100kbps (-f 868950000 -s 1200000)
[105]* Wireless M-Bus, Mode S, 32.768kbps (-f 868300000 -s 1000000)
[106]* Wireless M-Bus, Mode R, 4.8kbps (-f 868330000)
[107]* Wireless M-Bus, Mode F, 2.4kbps
[108] WS Temperature Sensor
[109] WT0124 Pool Thermometer
[110] PMV-107J (Toyota) TPMS
* Disabled by default, use -R n or -G
Examples:
| Command | Description |
|---|---|
rtl_433 -G |
Default receive mode, attempt to decode all known devices |
rtl_433 -p NN -R 1 -R 9 -R 36 -R 40 |
Typical usage: Enable device decoders for desired devices. Correct rtl-sdr tuning error (ppm offset). |
rtl_433 -a |
Will run in analyze mode and you will get a text description of the received signal. |
rtl_433 -A |
Enable pulse analyzer. Summarizes the timings of pulses, gaps, and periods. Can be used in either the normal decode mode, or analyze mode. |
rtl_433 -a -t |
Will run in analyze mode and save a test file per detected signal (g###_###M_###k.cu8). Format is uint8, 2 channels. |
rtl_433 -r file_name |
Play back a saved data file. |
rtl_433 file_name |
Will save everything received from the rtl-sdr during the session into a single file. The saves file may become quite large depending on how long rtl_433 is left running. Note: saving signals into individual files with rtl_433 -a -t is preferred. |
rtl_433 -F json -U | mosquitto_pub -t home/rtl_433 -l |
Will pipe the output to network as JSON formatted MQTT messages. A test MQTT client can be found in tests/mqtt_rtl_433_test.py. |
rtl_433 -f 433535000 -f 434019000 -H 15 |
Will poll two frequencies with 15 seconds interval. |
This software is mostly usable for developers right now.
Note: Not all device protocol decoders are enabled by default. When testing to see if your device
is decoded by rtl_433, use -G to enable all device protocols.
The first step in decoding new devices is to record the signals using -a -t. The signals will be
stored individually in files named gNNN_FFFM_RRRk.cu8 that can be played back with rtl_433 -r gNNN_FFFM_RRRk.cu8.
These files are vital for understanding the signal format as well as the message data. Use both analyzers
-a and -A to look at the recorded signal and determine the pulse characteristics, e.g. rtl_433 -r gNNN_FFFM_RRRk.cu8 -a -A.
Make sure you have recorded a proper set of test signals representing different conditions together with any and all information about the values that the signal should represent. For example, make a note of what temperature and/or humidity is the signal encoding. Ideally, capture a range of data values, such a different temperatures, to make it easy to spot what part of the message is changing.
Add the data files, a text file describing the captured signals, pictures of the device and/or a link the manufacturer's page (ideally with specifications) to the rtl_433_tests github repository. Follow the existing structure as best as possible and send a pull request.
https://github.com/merbanan/rtl_433_tests
Please don't open a new github issue for device support or request decoding help from others until you've added test signals and the description to the repository.
The rtl_433_test repository is also used to help test that changes to rtl_433 haven't caused any regressions.
Join the Google group, rtl_433, for more information about rtl_433: https://groups.google.com/forum/#!forum/rtl_433
If you see this error:
Kernel driver is active, or device is claimed by second instance of librtlsdr.
In the first case, please either detach or blacklist the kernel module
(dvb_usb_rtl28xxu), or enable automatic detaching at compile time.
then
sudo rmmod dvb_usb_rtl28xxu rtl2832