.. _gsb:
.. include:: ../tutorials/glossary_substitutions.rst
***
GSB
***
The GMRT software backend (GSB) file format is the standard output of
the initial correlator of the `Giant Metrewave Radio Telescope (GMRT)
`_. The GSB design is described by Roy et
al. (`2010, Exper. Astron. 28:25-60 `_)
with further specifications and operating procedures given on the relevant
`GMRT/GSB pages `_.
.. _gsb_file_structure:
File Structure
==============
A GSB dataset consists of an ASCII file with a sequence of |headers|,
and one or more accompanying binary data files. Each line in the header and
its corresponding data comprise a :term:`data frame`, though these do not have
explicit divisions in the data files.
Baseband currently supports two forms of GSB data: **rawdump**, for storing
real-valued raw voltage timestreams, and **phased**, for storing complex
pre-channelized data from the GMRT in phased array baseband mode.
Data in `rawdump format `_ is stored in a binary file
representing the voltage stream from one polarization of a single dish. Each
such file is accompanied by a header file which contains GPS timestamps, in the
form::
YYYY MM DD HH MM SS 0.SSSSSSSSS
In the default rawdump observing setup, samples are recorded at a rate of
33.3333... megasamples per second (Msps). Each sample is 4 bits in size, and
two samples are grouped into bytes such that the oldest sample occupies
the least significant bit. Each frame consists of **4 megabytes** of data,
or :math:`2^{23}`, samples; as such, the timespan of one frame is exactly
**0.25165824 s**.
Data in `phased format `_ is normally spread over four binary
files and one accompanying header file. The binary files come in two pairs,
one for each polarization, with the pair contain the first and second half of
the data of each frame.
When recording GSB in phased array voltage beam (ie. baseband) mode, the "raw",
or pre-channelized, :term:`sample rate` is either 33.3333... Msps at 8 bits per
sample or 66.6666... Msps at 4 bits per sample (in the latter case, sample
bit-ordering is the same as for rawdump). Channelization via fast Fourier
transform sets the channelized :term:`complete sample` rate to the raw rate
divided by :math:`2N_\mathrm{F}`, where :math:`N_\mathrm{F}` is the number of
Fourier channels (either 256 or 512). The timespan of one frame is **0.25165824
s**, and one frame is **8 megabytes** in size, for either raw sample rate.
The phased header's structure is::
where ```` and ```` are the less accurate computer-based
and exact GPS-based timestamps, respectively, with the same format as the
rawdump timestamp; ```` is the frame number; and ````
a redundant modulo-8 shared memory block number.
.. _gsb_usage:
Usage Notes
===========
This section covers reading and writing GSB files with Baseband; general usage
is covered in the :ref:`Using Baseband ` section. While
Baseband features the general `baseband.open` and `baseband.file_info`
functions, these cannot read GSB binary files without the accompanying
timestamp file (at which point it is obvious the files are GSB).
`baseband.file_info`, however, can be used on the timestamp file to determine
if it is in rawdump or phased format.
The examples below use the samplefiles in the ``baseband/data/gsb/`` directory,
and the `numpy`, `astropy.units` and `baseband.gsb` modules::
>>> import numpy as np
>>> import astropy.units as u
>>> from baseband import gsb
>>> from baseband.data import (
... SAMPLE_GSB_RAWDUMP, SAMPLE_GSB_RAWDUMP_HEADER,
... SAMPLE_GSB_PHASED, SAMPLE_GSB_PHASED_HEADER)
A single timestamp file can be opened with `~baseband.gsb.open` in text
mode::
>>> ft = gsb.open(SAMPLE_GSB_RAWDUMP_HEADER, 'rt')
>>> ft.read_timestamp()
>>> ft.close()
Reading payloads requires the samples per frame or sample rate. For phased the
sample rate is::
sample_rate = raw_sample_rate / (2 * nchan)
where the raw sample rate is the pre-channelized one, and ``nchan`` the number
of Fourier channels. The samples per frame for both rawdump and phased is::
samples_per_frame = timespan_of_frame * sample_rate
.. note::
Since the number of samples per frame is an integer number while
both the frame timespan and sample rate are not, it is better to separately
caculate ``samples_per_frame`` rather than multiplying
``timespan_of_frame`` with ``sample_rate`` in order to avoid rounding
issues.
Alternatively, if the size of the frame buffer and the frame rate are known, the
former can be used to determine ``samples_per_frame``, and the latter used to
determine ``sample_rate`` by inverting the above equation.
If ``samples_per_frame`` is not given, Baseband assumes it is the equivalent of
4 megabytes of data for rawdump, or 8 megabytes if phased. If ``sample_rate``
is not given, it is calculated from ``samples_per_frame`` assuming
``timespan_of_frame = 0.25165824`` (see :ref:`File Structure
` above).
A single payload file can be opened with `~baseband.gsb.open` in binary mode.
Here, for our sample file, we have to take into account that in order to keep
these files small, their sample size has been reduced to only **4 or 8
kilobytes** worth of samples per frame (for the default timespan). So, we
define their sample rate here, and use that to calculate ``payload_nbytes``,
the size of one frame in bytes. Since rawdump samples are 4 bits,
``payload_nbytes`` is just ``samples_per_frame / 2``::
>>> rawdump_samples_per_frame = 2**13
>>> payload_nbytes = rawdump_samples_per_frame // 2
>>> fb = gsb.open(SAMPLE_GSB_RAWDUMP, 'rb', payload_nbytes=payload_nbytes,
... nchan=1, bps=4, complex_data=False)
>>> payload = fb.read_payload()
>>> payload[:4]
array([[ 0.],
[-2.],
[-2.],
[ 0.]], dtype=float32)
>>> fb.close()
(``payload_nbytes`` for phased data is the size of one frame *divided by the
number of binary files*.)
Opening in stream mode allows timestamp and binary files to be read in
concert to create data frames, and also wraps the low-level routines such that
reading and writing is in units of samples, and provides access to header
information.
When opening a rawdump file in stream mode, we pass the timestamp file as the
first argument, and the binary file to the ``raw`` keyword. As per above, we
also pass ``samples_per_frame``::
>>> fh_rd = gsb.open(SAMPLE_GSB_RAWDUMP_HEADER, mode='rs',
... raw=SAMPLE_GSB_RAWDUMP,
... samples_per_frame=rawdump_samples_per_frame)
>>> fh_rd.header0
>>> dr = fh_rd.read()
>>> dr.shape
(81920,)
>>> dr[:3]
array([ 0., -2., -2.], dtype=float32)
>>> fh_rd.close()
To open a phased fileset in stream mode, we package the binary files into a
nested tuple with the format::
((L pol stream 1, L pol stream 2), (R pol stream 1, R pol stream 2))
The nested tuple is passed to ``raw`` (note that we again have to pass a
non-default sample rate)::
>>> phased_samples_per_frame = 2**3
>>> fh_ph = gsb.open(SAMPLE_GSB_PHASED_HEADER, mode='rs',
... raw=SAMPLE_GSB_PHASED,
... samples_per_frame=phased_samples_per_frame)
>>> header0 = fh_ph.header0 # To be used for writing, below.
>>> dp = fh_ph.read()
>>> dp.shape
(80, 2, 512)
>>> dp[0, 0, :3] # doctest: +FLOAT_CMP
array([30.+12.j, -1. +8.j, 7.+19.j], dtype=complex64)
>>> fh_ph.close()
To set up a file for writing, we need to pass names for both
timestamp and raw files, as well as ``sample_rate``, ``samples_per_frame``, and
either the first header or a ``time`` object. We first calculate
``sample_rate``::
>>> timespan = 0.25165824 * u.s
>>> rawdump_sample_rate = (rawdump_samples_per_frame / timespan).to(u.MHz)
>>> phased_sample_rate = (phased_samples_per_frame / timespan).to(u.MHz)
To write a rawdump file::
>>> from astropy.time import Time
>>> fw_rd = gsb.open('test_rawdump.timestamp',
... mode='ws', raw='test_rawdump.dat',
... sample_rate=rawdump_sample_rate,
... samples_per_frame=rawdump_samples_per_frame,
... time=Time('2015-04-27T13:15:00'))
>>> fw_rd.write(dr)
>>> fw_rd.close()
>>> fh_rd = gsb.open('test_rawdump.timestamp', mode='rs',
... raw='test_rawdump.dat',
... sample_rate=rawdump_sample_rate,
... samples_per_frame=rawdump_samples_per_frame)
>>> np.all(dr == fh_rd.read())
True
>>> fh_rd.close()
To write a phased file, we need to pass a nested tuple of filenames or
filehandles::
>>> test_phased_bin = (('test_phased_pL1.dat', 'test_phased_pL2.dat'),
... ('test_phased_pR1.dat', 'test_phased_pR2.dat'))
>>> fw_ph = gsb.open('test_phased.timestamp',
... mode='ws', raw=test_phased_bin,
... sample_rate=phased_sample_rate,
... samples_per_frame=phased_samples_per_frame,
... header0=header0)
>>> fw_ph.write(dp)
>>> fw_ph.close()
>>> fh_ph = gsb.open('test_phased.timestamp', mode='rs',
... raw=test_phased_bin,
... sample_rate=phased_sample_rate,
... samples_per_frame=phased_samples_per_frame)
>>> np.all(dp == fh_ph.read())
True
>>> fh_ph.close()
Baseband does not use the PC time in the phased header, and, when writing,
simply uses the same time for both GPS and PC times. Since the PC time can
drift from the GPS time by several tens of milliseconds,
``test_phased.timestamp`` will not be identical to ``SAMPLE_GSB_PHASED``, even
though we have written the exact same data to file.
.. _gsb_api:
Reference/API
=============
.. automodapi:: baseband.gsb
.. automodapi:: baseband.gsb.header
.. automodapi:: baseband.gsb.payload
.. automodapi:: baseband.gsb.frame
.. automodapi:: baseband.gsb.base