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pyrtcm 1.1.1
pyrtcm
Current Status |
Installation |
Reading |
Parsing |
Generating |
Serializing |
Examples |
Extensibility |
Command Line Utility |
Graphical Client |
Author & License
pyrtcm is an original Python 3 parser for the RTCM3 © GPS/GNSS protocol. RTCM3 is a proprietary GPS/GNSS differential correction or DGPS protocol published by the Radio Technical Commission for Maritime Services.
RTCM STANDARD 10403.n DIFFERENTIAL GNSS (GLOBAL NAVIGATION SATELLITE SYSTEMS) SERVICES – VERSION 3.
The pyrtcm homepage is located at https://github.com/semuconsulting/pyrtcm.
This is an independent project and we have no affiliation whatsoever with the Radio Technical Commission for Maritime Services.
FYI There are companion libraries which handle standard NMEA 0183 © and UBX © (u-blox) GNSS/GPS messages:
pyubx2
pynmeagps
Current Status
Parses RTCM3 messages into their constituent data fields - DF002, DF003, etc. Refer to the RTCM_MSGIDS dictionary in rtcmtypes_core.py for a list of message types currently implemented. Additional message types can be readily added - see Extensibility.
Sphinx API Documentation in HTML format is available at https://www.semuconsulting.com/pyrtcm.
Contributions welcome - please refer to CONTRIBUTING.MD.
Bug reports and Feature requests - please use the templates provided. For general queries and advice, post a message to one of the pyrtcm Discussions channels.
Installation
pyrtcm is compatible with Python >=3.8 and has no third-party library dependencies.
In the following, python3 & pip refer to the Python 3 executables. You may need to type
python or pip3, depending on your particular environment.
The recommended way to install the latest version of pyrtcm is with
pip:
python3 -m pip install --upgrade pyrtcm
If required, pyrtcm can also be installed into a virtual environment, e.g.:
python3 -m pip install --user --upgrade virtualenv
python3 -m virtualenv env
source env/bin/activate (or env\Scripts\activate on Windows)
(env) python3 -m pip install --upgrade pyrtcm
...
deactivate
For Conda users, pyrtcm is also available from conda-forge:
conda install -c conda-forge pyrtcm
Reading (Streaming)
class pyrtcm.rtcmreader.RTCMReader(stream, **kwargs)
You can create a RTCMReader object by calling the constructor with an active stream object.
The stream object can be any data stream which supports a read(n) -> bytes method (e.g. File or Serial, with
or without a buffer wrapper). pyrtcm implements an internal SocketStream class to allow sockets to be read in the same way as other streams (see example below).
Individual RTCM messages can then be read using the RTCMReader.read() function, which returns both the raw binary data (as bytes) and the parsed data (as a RTCMMessage, via the parse() method). The function is thread-safe in so far as the incoming data stream object is thread-safe. RTCMReader also implements an iterator.
Example - Serial input:
from serial import Serial
from pyrtcm import RTCMReader
with Serial('/dev/tty.usbmodem14101', 9600, timeout=3) as stream:
rtr = RTCMReader(stream)
raw_data, parsed_data = rtr.read()
if parsed_data is not None:
print(parsed_data)
"<RTCM(1077, DF002=1077, DF003=0, DF004=204137001, DF393=1, DF409=0, DF001_7=0, ..., DF404_15=-9556, DF404_16=-2148, DF404_17=-2174)>",
Example - File input (using iterator).
from pyrtcm import RTCMReader
with open('rtcmdata.log', 'rb') as stream:
rtr = RTCMReader(stream)
for raw_data, parsed_data in rtr:
print(parsed_data)
Example - Socket input (using iterator):
import socket
from pyrtcm import RTCMReader
with socket.socket(socket.AF_INET, socket.SOCK_STREAM) as stream:
stream.connect(("localhost", 50007))
rtr = RTCMReader(stream)
for raw_data, parsed_data in rtr:
print(parsed_data)
Parsing
You can parse individual RTCM messages using the static RTCMReader.parse(data) function, which takes a bytes array containing a binary RTCM message and returns a RTCMMessage object.
NB: Once instantiated, an RTCMMessage object is immutable.
Example:
from pyrtcm import RTCMReader
msg = RTCMReader.parse(b"\xd3\x00\x13>\xd0\x00\x03\x8aX\xd9I<\x87/4\x10\x9d\x07\xd6\xafH Z\xd7\xf7")
print(msg)
<RTCM(1005, DF002=1005, DF003=0, DF021=0, DF022=1, DF023=1, DF024=1, DF141=0, DF025=4444030.8028, DF142=1, DF001_1=0, DF026=3085671.2349, DF364=0, DF027=3366658.256)>
The RTCMMessage object exposes different public attributes depending on its message type or 'identity'. Attributes are defined as data fields (DF002, DF003, etc.) e.g. the 1097 multiple signal message (MSM) contains the following data fields:
print(msg)
print(msg.identity)
print(msg.DF248)
print(msg.DF404_07)
"<RTCM(1097, DF002=1097, DF003=0, DF248=204137001, DF393=1, DF409=0, DF001_7=0, DF411=0, DF412=0, DF417=0, DF418=0, DF394=216181732825628672, NSat=5, DF395=1073872896, NSig=2, DF396=1023, NCell=10, PRN_01=007, PRN_02=008, PRN_03=021, PRN_04=027, ..., DF404_07=5534, DF404_08=5545, DF404_09=-7726, DF404_10=-7733)>",
'1097'
204137001
5534
Attributes within repeating groups are parsed with a two-digit suffix (DF419_01, DF419_02, etc. See example below for an illustration of how to iterate through grouped attributes).
Helper methods are available to interpret the individual datafields:
from pyrtcm import RTCM_DATA_FIELDS, datadesc
dfname = "DF012"
print(RTCM_DATA_FIELDS[dfname])
print(datadesc(dfname))
(INT20, 0.0001, "GPS L1 PhaseRange - L1 Pseudorange")
'GPS L1 PhaseRange - L1 Pseudorange'
The payload attribute always contains the raw payload as bytes.
Iterating Through Group Attributes
To iterate through a group of one or more repeating attributes in a given RTCMMessage object, the following construct can be used (in this illustration, repeating attributes CELLPRN, CELLSIG, DF405, DF406, DF407, DF408, DF420 and DF404 are extracted from an MSM 1077 message msg and collated in the array msmarray):
msmarray = []
for i in range(msg.NCell): # msg = MSM 1077, number of cells = NCell
vals = []
for attr in ("CELLPRN", "CELLSIG", "DF405", "DF406", "DF407", "DF408", "DF420", "DF404"):
val = getattr(msg, f"{attr}_{i+1:02d}")
vals.append(val)
msmarray.append(vals)
print(msmarray)
[['005', '1C', 0.00014309026300907135, 0.00014193402603268623, 341, 45.0, 0, -0.9231], ..., ['030', '2L', -0.00030865520238876343, -0.00030898721888661385, 341, 41.0, 0, -0.2174]]
The following dedicated helper methods are available to parse selected RTCM3 message types into a series of iterable data arrays:
parse_msm - for MSM message types (e.g. 1077, 1125, etc.).
parse_4076_201 - for 4076_201 SSR (harmonic coefficients) message types.
Generating
class pyrtcm.rtcmmessage.RTCMMessage(**kwargs)
You can create an RTCMMessage object by calling the constructor with the following keyword arguments:
payload as bytes
Example:
from pyrtcm import RTCMMessage
msg = RTCMMessage(payload=b">\xd0\x00\x03\x8aX\xd9I<\x87/4\x10\x9d\x07\xd6\xafH ")
print(msg)
<RTCM(1005, DF002=1005, DF003=0, DF021=0, DF022=1, DF023=1, DF024=1, DF141=0, DF025=4444030.8028, DF142=1, DF001_1=0, DF026=3085671.2349, DF364=0, DF027=3366658.256)>
Serializing
The RTCMMessage class implements a serialize() method to convert a RTCMMessage object to a bytes array suitable for writing to an output stream.
e.g. to create and send a 1005 message type:
from serial import Serial
from pyrtcm import RTCMMessage
serialOut = Serial('COM7', 38400, timeout=5)
msg = RTCMMessage(payload=b">\xd0\x00\x03\x8aX\xd9I<\x87/4\x10\x9d\x07\xd6\xafH ")
print(msg)
output = msg.serialize()
print(output)
serialOut.write(output)
<RTCM(1005, DF002=1005, DF003=0, DF021=0, DF022=1, DF023=1, DF024=1, DF141=0, DF025=4444030.8028, DF142=1, DF001_1=0, DF026=3085671.2349, DF364=0, DF027=3366658.256)>
b'\xd3\x00\x13>\xd0\x00\x03\x8aX\xd9I<\x87/4\x10\x9d\x07\xd6\xafH Z\xd7\xf7'
Examples
The following examples are available in the /examples folder:
rtcmpoller.py - illustrates how to read and display RTCM messages 'concurrently' with other tasks using threads and queues. This represents a useful generic pattern for many end user applications.
rtcmfile.py - illustrates how to stream RTCM data from binary log file.
rtcmsocket.py - illustrates how to implement a TCP Socket reader for RTCM messages using RTCMReader iterator functionality.
msmparser.py - illustrates how to parse RTCM3 MSM (multiple signal messages) into a series of iterable data arrays keyed on satellite PRN and signal ID.
rtcm_ntrip_client.py - illustrates a simple NTRIP client using pyrtcm to parse the RTCM3 output.
Extensibility
The RTCM protocol is principally defined in the modules rtcmtypes_core.py and rtcmtypes_get.py as a series of dictionaries. RTCM uses a series of pre-defined data fields ("DF002", DF003" etc.), each of which has a designated data type (UINT32, etc.). Message payload definitions must conform to the following rules:
1. datafield names must be unique within each message class
2. datafield types must be one of the valid data fields ("DF026", "DF059", etc.)
3. repeating or bitfield groups must be defined as a tuple ('numr', {dict}), where:
'numr' is either:
a. an integer representing a fixed number of repeats e.g. 32
b. a string representing the name of a preceding attribute containing the number of repeats e.g. 'DF029'
{dict} is the nested dictionary of repeating items or bitfield group
Repeating attribute names are parsed with a two-digit suffix ("DF030_01", "DF030_02", etc.). Nested repeating groups are supported.
Command Line Utility
A command line utility gnssdump is available via the pygnssutils package. This is capable of reading and parsing NMEA, UBX and RTCM3 data from a variety of input sources (e.g. serial, socket and file) and outputting to a variety of media in a variety of formats. See https://github.com/semuconsulting/pygnssutils for further details.
To install pygnssutils:
python3 -m pip install --upgrade pygnssutils
For help with the gnssdump utility, type:
gnssdump -h
Graphical Client
A python/tkinter graphical GPS client which supports NMEA, UBX, RTCM3, NTRIP and SPARTN protocols is available at:
https://github.com/semuconsulting/PyGPSClient
Author & License Information
[email protected]
pyrtcm is maintained entirely by unpaid volunteers. It receives no funding from advertising or corporate sponsorship. If you find the library useful, a small donation would be greatly appreciated!
For personal and professional use. You cannot resell or redistribute these repositories in their original state.
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