If you find this project useful for your research, please considering cite this tool as:
@article{sun2019pymodes, author={J. {Sun} and H. {V\^u} and J. {Ellerbroek} and J. M. {Hoekstra}}, journal={IEEE Transactions on Intelligent Transportation Systems}, title={pyModeS: Decoding Mode-S Surveillance Data for Open Air Transportation Research}, year={2019}, doi={10.1109/TITS.2019.2914770}, ISSN={1524-9050}, }
PyModeS is a Python library designed to decode Mode-S (including ADS-B) message. It can be imported to your python project or be used as a standalone tool to view and save live traffic data.
Messages with following Downlink Formats (DF) are supported:
DF17 / DF18: Automatic Dependent Surveillance-Broadcast (ADS-B)
- TC=1-4 / BDS 0,8: Aircraft identification and category
- TC=5-8 / BDS 0,6: Surface position
- TC=9-18 / BDS 0,5: Airborne position
- TC=19 / BDS 0,9: Airborne velocity
- TC=28 / BDS 6,1: Airborne status [to be implemented]
- TC=29 / BDS 6,2: Target state and status information [to be implemented]
- TC=31 / BDS 6,5: Aircraft operational status [to be implemented]
DF20 / DF21: Mode-S Comm-B replies
- BDS 1,0: Data link capability report
- BDS 1,7: Common usage GICB capability report
- BDS 2,0: Aircraft identification
- BDS 3,0: ACAS active resolution advisory
- BDS 4,0: Selected vertical intention
- BDS 4,4: Meteorological routine air report (experimental)
- BDS 4,5: Meteorological hazard report (experimental)
- BDS 5,0: Track and turn report
- BDS 6,0: Heading and speed report
DF4 / DF20: Altitude code
DF5 / DF21: Identity code (squawk code)
Check out and contribute to this open-source project at: https://github.com/junzis/pyModeS
Detailed manual on Mode-S decoding is published at: https://mode-s.org/decode.
The API documentation of pyModeS is at: http://pymodes.readthedocs.io
Installation examples:
# stable version pip install pyModeS # development version pip install git+https://github.com/junzis/pyModeS
Dependencies numpy
, pyzmq
and pyrtlsdr
are installed automatically during previous installations processes.
General usage:
$ modeslive [-h] --source SOURCE [--connect SERVER PORT DATAYPE] [--latlon LAT LON] [--show-uncertainty] [--dumpto DUMPTO] arguments: -h, --help show this help message and exit --source SOURCE Choose data source, "rtlsdr" or "net" --connect SERVER PORT DATATYPE Define server, port and data type. Supported data types are: ['raw', 'beast', 'skysense'] --latlon LAT LON Receiver latitude and longitude, needed for the surface position, default none --show-uncertainty Display uncertainty values, default off --dumpto DUMPTO Folder to dump decoded output, default none
If you have an RTL-SDR receiver plugged to the computer, you can connect it with rtlsdr
source switch, shown as follows:
$ modeslive --source rtlsdr
If you want to connect to a TCP server that broadcast raw data. use can use net
source switch, for example:
$ modeslive --source net --connect localhost 30002 raw $ modeslive --source net --connect 127.0.0.1 30005 beast
Example screenshot:
import pyModeS as pms
pms.df(msg) # Downlink Format
pms.icao(msg) # Infer the ICAO address from the message
pms.crc(msg, encode=False) # Perform CRC or generate parity bit
pms.hex2bin(str) # Convert hexadecimal string to binary string
pms.bin2int(str) # Convert binary string to integer
pms.hex2int(str) # Convert hexadecimal string to integer
pms.gray2int(str) # Convert grey code to interger
pms.adsb.icao(msg)
pms.adsb.typecode(msg)
# Typecode 1-4
pms.adsb.callsign(msg)
# Typecode 5-8 (surface), 9-18 (airborne, barometric height), and 9-18 (airborne, GNSS height)
pms.adsb.position(msg_even, msg_odd, t_even, t_odd, lat_ref=None, lon_ref=None)
pms.adsb.airborne_position(msg_even, msg_odd, t_even, t_odd)
pms.adsb.surface_position(msg_even, msg_odd, t_even, t_odd, lat_ref, lon_ref)
pms.adsb.surface_velocity(msg)
pms.adsb.position_with_ref(msg, lat_ref, lon_ref)
pms.adsb.airborne_position_with_ref(msg, lat_ref, lon_ref)
pms.adsb.surface_position_with_ref(msg, lat_ref, lon_ref)
pms.adsb.altitude(msg)
# Typecode: 19
pms.adsb.velocity(msg) # Handles both surface & airborne messages
pms.adsb.speed_heading(msg) # Handles both surface & airborne messages
pms.adsb.airborne_velocity(msg)
Note: When you have a fix position of the aircraft, it is convenient to use position_with_ref() method to decode with only one position message (either odd or even). This works with both airborne and surface position messages. But the reference position shall be within 180NM (airborne) or 45NM (surface) of the true position.
pms.common.altcode(msg) # Downlink format must be 4 or 20
pms.common.idcode(msg) # Downlink format must be 5 or 21
pms.icao(msg) # Infer the ICAO address from the message
pms.bds.infer(msg) # Infer the Modes-S BDS register
# Check if BDS is 5,0 or 6,0, give reference speed, track, altitude (from ADS-B)
pms.bds.is50or60(msg, spd_ref, trk_ref, alt_ref)
# Check each BDS explicitly
pms.bds.bds10.is10(msg)
pms.bds.bds17.is17(msg)
pms.bds.bds20.is20(msg)
pms.bds.bds30.is30(msg)
pms.bds.bds40.is40(msg)
pms.bds.bds44.is44(msg)
pms.bds.bds50.is50(msg)
pms.bds.bds60.is60(msg)
pms.commb.ovc10(msg) # Overlay capability, BDS 1,0
pms.commb.cap17(msg) # GICB capability, BDS 1,7
pms.commb.cs20(msg) # Callsign, BDS 2,0
# BDS 4,0
pms.commb.selalt40mcp(msg) # MCP/FCU selected altitude (ft)
pms.commb.selalt40fms(msg) # FMS selected altitude (ft)
pms.commb.p40baro(msg) # Barometric pressure (mb)
# BDS 5,0
pms.commb.roll50(msg) # Roll angle (deg)
pms.commb.trk50(msg) # True track angle (deg)
pms.commb.gs50(msg) # Ground speed (kt)
pms.commb.rtrk50(msg) # Track angle rate (deg/sec)
pms.commb.tas50(msg) # True airspeed (kt)
# BDS 6,0
pms.commb.hdg60(msg) # Magnetic heading (deg)
pms.commb.ias60(msg) # Indicated airspeed (kt)
pms.commb.mach60(msg) # Mach number (-)
pms.commb.vr60baro(msg) # Barometric altitude rate (ft/min)
pms.commb.vr60ins(msg) # Inertial vertical speed (ft/min)
# BDS 4,4
pms.commb.wind44(msg) # Wind speed (kt) and direction (true) (deg)
pms.commb.temp44(msg) # Static air temperature (C)
pms.commb.p44(msg) # Average static pressure (hPa)
pms.commb.hum44(msg) # Humidity (%)
# BDS 4,5
pms.commb.turb45(msg) # Turbulence level (0-3)
pms.commb.ws45(msg) # Wind shear level (0-3)
pms.commb.mb45(msg) # Microburst level (0-3)
pms.commb.ic45(msg) # Icing level (0-3)
pms.commb.wv45(msg) # Wake vortex level (0-3)
pms.commb.temp45(msg) # Static air temperature (C)
pms.commb.p45(msg) # Average static pressure (hPa)
pms.commb.rh45(msg) # Radio height (ft)
The TCP client module from pyModeS can be re-used to stream and process Mode-S data as you like. You need to re-implement the handle_messages()
function from the TcpClient
class to write your own logic to handle the messages.
Here is an example:
import pyModeS as pms
from pyModeS.extra.tcpclient import TcpClient
# define your custom class by extending the TcpClient
# - implement your handle_messages() methods
class ADSBClient(TcpClient):
def __init__(self, host, port, rawtype):
super(ADSBClient, self).__init__(host, port, rawtype)
def handle_messages(self, messages):
for msg, ts in messages:
if len(msg) != 28: # wrong data length
continue
df = pms.df(msg)
if df != 17: # not ADSB
continue
if pms.crc(msg) !=0: # CRC fail
continue
icao = pms.adsb.icao(msg)
tc = pms.adsb.typecode(msg)
# TODO: write you magic code here
print(ts, icao, tc, msg)
# run new client, change the host, port, and rawtype if needed
client = ADSBClient(host='127.0.0.1', port=30005, rawtype='beast')
client.run()
To perform unit tests. First, install tox
through pip. Then, run the following commands:
$ tox