https://github.com/RadioAstronomySoftwareGroup/pyuvdata
Tip revision: 6694e4e7426f41d8493145e3d61b49eba9dca0a9 authored by Bryna Hazelton on 21 July 2021, 15:54:00 UTC
update the changelog for v2.2.1
update the changelog for v2.2.1
Tip revision: 6694e4e
mwa_corr_fits.py
# -*- mode: python; coding: utf-8 -*-
# Copyright (c) 2019 Radio Astronomy Software Group
# Licensed under the 2-clause BSD License
"""Class for reading MWA correlator FITS files."""
import os
import warnings
import itertools
import numpy as np
import h5py
from astropy.io import fits
from astropy.time import Time
from astropy import constants as const
from pyuvdata.data import DATA_PATH
from scipy.special import erf
from scipy.integrate import simps
from .. import _corr_fits
from . import UVData
from .. import utils as uvutils
__all__ = ["input_output_mapping", "MWACorrFITS"]
def input_output_mapping():
"""Build a mapping dictionary from pfb input to output numbers."""
# the polyphase filter bank maps inputs to outputs, which the MWA
# correlator then records as the antenna indices.
# the following is taken from mwa_build_lfiles/mwac_utils.c
# inputs are mapped to outputs via pfb_mapper as follows
# (from mwa_build_lfiles/antenna_mapping.h):
# floor(index/4) + index%4 * 16 = input
# for the first 64 outputs, pfb_mapper[output] = input
return _corr_fits.input_output_mapping()
def sighat_vector(x):
"""
Generate quantized sigma using Van Vleck relation.
For an explanation of the Van Vleck relations used and their implementation
in this code, see the memos at
https://github.com/EoRImaging/Memos/blob/master/PDFs/007_Van_Vleck_A.pdf and
https://github.com/EoRImaging/Memos/blob/master/PDFs/008_Van_Vleck_B.pdf
Parameters
----------
x : numpy array
Array of sigma inputs.
Returns
-------
sighat : numpy array
Array of corresponding sigmas of quantized values.
"""
yy = np.arange(7)[:, np.newaxis]
z = (2 * yy + 1) * erf((yy + 0.5) / (x * np.sqrt(2)))
z = z.sum(axis=0)
sighat = np.sqrt(7 ** 2 - z)
return sighat
def sighat_vector_prime(x):
"""
Calculate the derivative of sighat_vector.
Parameters
----------
x : numpy array
Array of sigma inputs.
Returns
-------
sighat : numpy array
Array of corresponding derivatives with respect to sigma inputs.
"""
yy = np.arange(7)[:, np.newaxis]
z = (
(2 * yy + 1)
* (yy + 0.5)
* np.exp(-((yy + 0.5) ** 2) / (2 * (x ** 2)))
/ (np.sqrt(2 * np.pi) * (x ** 2))
)
sighat_prime = z.sum(axis=0)
sighat_prime = sighat_prime / sighat_vector(x)
return sighat_prime
def corrcorrect_simps(rho, sig1, sig2):
"""
Generate quantized kappa using the Van Vleck relation.
For an explanation of the Van Vleck relations used and their implementation
in this code, see the memos at
https://github.com/EoRImaging/Memos/blob/master/PDFs/007_Van_Vleck_A.pdf and
https://github.com/EoRImaging/Memos/blob/master/PDFs/008_Van_Vleck_B.pdf
Parameters
----------
rho : numpy array
Array of rho inputs.
sig1 : numpy array
Array of sigma inputs corresponding to antenna 1.
sig2: numpy array
Array of sigma inputs corresponding to antenna 2.
Returns
-------
integrated_khat : numpy array
Array of cross-correlations of quantized values.
"""
x = np.linspace(0, rho, 11, dtype=np.float64)
khat = np.zeros((11, rho.size), dtype=np.float64)
khat = _corr_fits.get_khat(x, sig1, sig2)
integrated_khat = simps(khat, x, axis=0)
return integrated_khat
def corrcorrect_vect_prime(rho, sig1, sig2):
"""
Calculate the derivative of corrcorrect_simps.
Parameters
----------
rho : numpy array
Array of rho inputs.
sig1 : numpy array
Array of sigma inputs corresponding to antenna 1.
sig2: numpy array
Array of sigma inputs corresponding to antenna 2.
"""
return _corr_fits.get_khat(rho, sig1, sig2)
def van_vleck_autos(sighat_arr):
"""
Use Newton's method to solve the inverse of sighat_vector.
For an explanation of the Van Vleck corrections used and their implementation
in this code, see the memos at
https://github.com/EoRImaging/Memos/blob/master/PDFs/007_Van_Vleck_A.pdf and
https://github.com/EoRImaging/Memos/blob/master/PDFs/008_Van_Vleck_B.pdf
Parameters
----------
sighat_arr : numpy array
Array of quantized sigma to be corrected.
Returns
-------
sighat_arr : numpy array
Array of Van Vleck corrected scaled auto-correlations.
"""
# cut off small sigmas that will not converge
cutoff_inds = np.where(sighat_arr > 0.5)[0]
sighat = sighat_arr[cutoff_inds]
if len(sighat) > 0:
guess = np.copy(sighat)
inds = np.where(np.abs(sighat_vector(guess) - sighat) > 1e-10)[0]
while len(inds) != 0:
guess[inds] = guess[inds] - (
(sighat_vector(guess[inds]) - sighat[inds])
/ sighat_vector_prime(guess[inds])
)
inds = np.where(np.abs(sighat_vector(guess) - sighat) > 1e-10)[0]
sighat_arr[cutoff_inds] = guess
return sighat_arr
def van_vleck_crosses_int(k_arr, sig1_arr, sig2_arr, cheby_approx):
"""
Use Newton's method to solve the inverse of corrcorrect_simps.
For an explanation of the Van Vleck corrections used and their implementation
in this code, see the memos at
https://github.com/EoRImaging/Memos/blob/master/PDFs/007_Van_Vleck_A.pdf and
https://github.com/EoRImaging/Memos/blob/master/PDFs/008_Van_Vleck_B.pdf
Parameters
----------
k_arr : numpy array
Array of quantized kappa to be corrected.
sig1_arr : numpy array
Array of sigma inputs corresponding to antenna 1.
sig2_arr: numpy array
Array of sigma inputs corresponding to antenna 2.
cheby_approx : bool
Flag to warn if chebyshev approximation is being used.
Returns
-------
k_arr : numpy array
Array of Van Vleck corrected scaled cross-correlations.
"""
nonzero_inds = np.where((k_arr != 0) & (sig1_arr != 0) & (sig2_arr != 0))[0]
if len(nonzero_inds) > 0.0:
if cheby_approx:
warnings.warn(
str(len(nonzero_inds))
+ " values are being corrected with the van vleck integral"
)
neg_inds = np.where(k_arr < 0.0)[0]
khat = np.abs(k_arr[nonzero_inds])
sig1 = sig1_arr[nonzero_inds]
sig2 = sig2_arr[nonzero_inds]
x0 = khat / (sig1 * sig2)
corr = corrcorrect_simps(x0, sig1, sig2) - khat
x0 = x0 - (corr / corrcorrect_vect_prime(x0, sig1, sig2))
inds = np.where(np.abs(corr) > 1e-8)[0]
while len(inds) != 0:
corr = corrcorrect_simps(x0[inds], sig1[inds], sig2[inds]) - khat[inds]
x0[inds] = x0[inds] - (
corr / corrcorrect_vect_prime(x0[inds], sig1[inds], sig2[inds])
)
inds2 = np.where(np.abs(corr) > 1e-8)[0]
inds = inds[inds2]
k_arr[nonzero_inds] = x0 * sig1 * sig2
k_arr[neg_inds] = np.negative(k_arr[neg_inds])
return k_arr
def van_vleck_crosses_cheby(
khat,
sig1,
sig2,
broad_inds,
rho_coeff,
sv_inds_right1,
sv_inds_right2,
ds1,
ds2,
cheby_approx,
):
"""
Compute a chebyshev approximation of corrcorrect_simps.
Uses a bilinear interpolation to find chebyshev coefficients. Assumes distance
between points of interpolation grid is 0.01. If sig1 or sig2 falls outside
the interpolation grid, the corresponding values are corrected using
van_vleck_crosses_int.
For an explanation of the Van Vleck corrections used and their implementation
in this code, see the memos at
https://github.com/EoRImaging/Memos/blob/master/PDFs/007_Van_Vleck_A.pdf and
https://github.com/EoRImaging/Memos/blob/master/PDFs/008_Van_Vleck_B.pdf
Parameters
----------
khat : numpy array
Array of quantized kappa to be corrected.
sig1 : numpy array
Array of sigma inputs corresponding to antenna 1.
sig2: numpy array
Array of sigma inputs corresponding to antenna 2.
broad_inds : numpy array
Array indexing sigmas within the chebyshev approximation range.
rho_coeff : numpy array
Array of chebyshev polynomial coefficients.
sv_inds_right1 : numpy array
Array of right indices for sig1 for bilinear interpolation.
sv_inds_right2 : numpy array
Array of right indices for sig2 for bilinear interpolation.
ds1 : numpy array
Distance between sig1 and right-indexed value for bilinear interpolation.
ds2 : numpy array
Distance between sig2 and right-indexed value for bilinear interpolation.
cheby_approx : bool
Flag to warn if chebyshev approximation is being used.
Returns
-------
khat : numpy array
Array of Van Vleck corrected scaled cross-correlations.
"""
kap = np.array([khat[broad_inds].real, khat[broad_inds].imag])
_corr_fits.van_vleck_cheby(
kap, rho_coeff, sv_inds_right1, sv_inds_right2, ds1, ds2,
)
khat[broad_inds] = (kap[0, :] + 1j * kap[1, :]) * (
sig1[broad_inds] * sig2[broad_inds]
)
khat[~broad_inds] = van_vleck_crosses_int(
khat.real[~broad_inds], sig1[~broad_inds], sig2[~broad_inds], cheby_approx
) + 1j * van_vleck_crosses_int(
khat.imag[~broad_inds], sig1[~broad_inds], sig2[~broad_inds], cheby_approx
)
return khat
class MWACorrFITS(UVData):
"""
UVData subclass for reading MWA correlator fits files.
This class should not be interacted with directly; instead use the
read_mwa_corr_fits method on the UVData class.
"""
def correct_cable_length(self, cable_lens):
"""
Apply a cable length correction to the data array.
Parameters
----------
cable_lens : list of strings
A list of strings containing the cable lengths for each antenna.
"""
# as of version 0.29.X cython does not handle numpy arrays of strings
# particularly efficiently. Casting to bytes, then into this demonic
# form is a workaround found here: https://stackoverflow.com/a/28777163
cable_lens = np.asarray(cable_lens).astype(np.string_)
cable_lens = cable_lens.view("uint8").reshape(
cable_lens.size, cable_lens.dtype.itemsize
)
# from MWA_Tools/CONV2UVFITS/convutils.h
cable_len_diffs = _corr_fits.get_cable_len_diffs(
self.ant_1_array, self.ant_2_array, cable_lens,
)
self.data_array *= np.exp(
-1j
* 2
* np.pi
* cable_len_diffs.reshape(self.Nblts, 1)
/ const.c.to("m/s").value
* self.freq_array.reshape(1, self.Nfreqs)
)[:, :, None]
history_add_string = " Applied cable length correction."
self.history += history_add_string
def flag_init(
self,
num_fine_chan,
edge_width=80e3,
start_flag=2.0,
end_flag=0.0,
flag_dc_offset=True,
):
"""
Apply routine flagging to the MWA Correlator FITS file data.
Includes options to flag the coarse channel edges, beginning and end
of obs, as well as the center fine channel of each coarse channel.
Parameters
----------
edge_width: float
The width to flag on the edge of each coarse channel, in hz. Set to
0 for no edge flagging.
start_flag: float
The number of seconds to flag at the beginning of the observation.
Set to 0 for no flagging.
end_flag: floats
The number of seconds to flag at the end of the observation. Set to
0 for no flagging.
flag_dc_offset: bool
Set to True to flag the center fine channel of each coarse channel.
Raises
------
ValueError
If edge_width is not an integer multiple of the channel_width of
the data (0 also acceptable).
If start_flag is not an integer multiple of the integration time
(0 also acceptable).
If end_flag is not an integer multiple of the integration time
(0 also acceptable).
"""
if (edge_width % self.channel_width) > 0:
raise ValueError(
"The edge_width must be an integer multiple of the "
"channel_width of the data or zero."
)
if (start_flag % self.integration_time[0]) > 0:
raise ValueError(
"The start_flag must be an integer multiple of the "
"integration_time of the data or zero."
)
if (end_flag % self.integration_time[0]) > 0:
raise ValueError(
"The end_flag must be an integer multiple of the "
"integration_time of the data or zero."
)
num_ch_flag = int(edge_width / self.channel_width)
num_start_flag = int(start_flag / self.integration_time[0])
num_end_flag = int(end_flag / self.integration_time[0])
if num_ch_flag > 0:
edge_inds = []
for ch_count in range(num_ch_flag):
# count up from the left
left_chans = list(range(ch_count, self.Nfreqs, num_fine_chan))
# count down from the right
right_chans = list(range(self.Nfreqs - 1 - ch_count, 0, -num_fine_chan))
edge_inds = edge_inds + left_chans + right_chans
self.flag_array[:, :, edge_inds, :] = True
if flag_dc_offset:
center_inds = list(range(num_fine_chan // 2, self.Nfreqs, num_fine_chan))
self.flag_array[:, :, center_inds, :] = True
if (num_start_flag > 0) or (num_end_flag > 0):
shape = self.flag_array.shape
# TODO: Spw axis to be collapsed in future release
# Asserting this here because this is effectively a stripped down UVFITS
# reader, and thus assuming that this should only support simple tables
assert shape[1] == 1
reshape = [self.Ntimes, self.Nbls, 1, self.Nfreqs, self.Npols]
self.flag_array = np.reshape(self.flag_array, reshape)
if num_start_flag > 0:
self.flag_array[:num_start_flag, :, :, :, :] = True
if num_end_flag > 0:
self.flag_array[-num_end_flag:, :, :, :, :] = True
self.flag_array = np.reshape(self.flag_array, shape)
def _read_fits_file(
self, filename, time_array, file_nums_to_index, num_fine_chans, int_time,
):
"""
Read the fits file and populate into memory.
This is an internal function and should not regularly be called except
by read_mwa_corr_fits function.
It is designed to close the fits files, headers, and all associated pointers.
Without this read in a function, reading files has a large memory footprint.
Parameters
----------
filename : str
The mwa gpubox fits file to read
time_array : array of floats
The time_array object constructed during read_mwa_corr_fits call
file_nums_to_index : dict
Mappings of file name to index in coarse channel
num_fine_chans : int
Number of fine channels in a coarse channel
int_time : float
The integration time of each observation.
"""
# get the file number from the file name
file_num = int(filename.split("_")[-2][-2:])
# map file number to frequency index
freq_ind = file_nums_to_index[file_num] * num_fine_chans
with fits.open(filename, mode="denywrite") as hdu_list:
for hdu in hdu_list:
# entry 0 is a header, so we skip it.
if hdu.data is None:
continue
time = (
hdu.header["TIME"]
+ hdu.header["MILLITIM"] / 1000.0
+ int_time / 2.0
)
time_ind = np.where(time_array == time)[0][0]
# dump data into matrix
# and take data from real to complex numbers
indices = np.index_exp[
time_ind, freq_ind : freq_ind + num_fine_chans, :
]
self.data_array[indices] = hdu.data[:, 0::2] + 1j * hdu.data[:, 1::2]
self.nsample_array[
time_ind, :, freq_ind : freq_ind + num_fine_chans, :
] = 1.0
self.flag_array[time_ind, :, file_nums_to_index[file_num], :] = False
return
def van_vleck_correction(
self,
flagged_ants,
cheby_approx,
data_array_dtype,
remove_flagged_ants,
flag_small_sig_ants,
):
"""
Apply a van vleck correction to the data array.
For an explanation of the Van Vleck corrections used and their implementation
in this code, see the memos at
https://github.com/EoRImaging/Memos/blob/master/PDFs/007_Van_Vleck_A.pdf and
https://github.com/EoRImaging/Memos/blob/master/PDFs/008_Van_Vleck_B.pdf
Parameters
----------
cheby_approx : bool
Option to implement the van vleck correction with a chebyshev polynomial
approximation.
data_array_dtype : numpy dtype
Datatype to store the output data_array as.
Returns
-------
flagged_ants : numpy array of type int
Updated list of indices of flagged antennas
"""
history_add_string = " Applied Van Vleck correction."
# need data array to have 64 bit precision
# work on this in the future to only change precision where necessary
if self.data_array.dtype != np.complex128:
self.data_array = self.data_array.astype(np.complex128)
# scale the data
# number of samples per fine channel is equal to channel width (Hz)
# multiplied be the integration time (s)
nsamples = self.channel_width * self.integration_time[0]
# cast data to ints
self.data_array /= self.extra_keywords["SCALEFAC"]
np.rint(self.data_array, out=self.data_array)
# take advantage of circular symmetry! divide by two
self.data_array /= nsamples * 2.0
# reshape to (nbls, ntimes, nfreqs, npols)
self.data_array = np.swapaxes(self.data_array, 0, 1)
# get indices for autos
autos = np.where(
self.ant_1_array[0 : self.Nbls] == self.ant_2_array[0 : self.Nbls]
)[0]
# get indices for crosses
crosses = np.where(
self.ant_1_array[0 : self.Nbls] != self.ant_2_array[0 : self.Nbls]
)[0]
# find polarizations
xx = np.where(self.polarization_array == -5)[0][0]
yy = np.where(self.polarization_array == -6)[0][0]
xy = np.where(self.polarization_array == -7)[0][0]
yx = np.where(self.polarization_array == -8)[0][0]
pols = np.array([yy, xx])
# combine axes
self.data_array = self.data_array.reshape(
(self.Nbls, self.Nfreqs * self.Ntimes, self.Npols)
)
# square root autos
auto_inds = autos[:, np.newaxis]
self.data_array.real[auto_inds, :, pols] = np.sqrt(
self.data_array.real[auto_inds, :, pols]
)
# look for small sigmas that will not converge
small_sig_flags = np.logical_and(
self.data_array.real[auto_inds, :, pols] != 0,
self.data_array.real[auto_inds, :, pols] <= 0.5,
)
if flag_small_sig_ants:
# find antenna indices for small sig ants and add to flagged_ants
# nonzero sigmas below 0.5 generally indicate bad data
ant_inds = np.unique(np.nonzero(small_sig_flags)[0])
ant_inds = ant_inds[~np.in1d(ant_inds, flagged_ants)]
if len(ant_inds) != 0:
history_add_string += (
" The following antennas were flagged by the Van Vleck \
correction and removed from the data: "
+ str(ant_inds)
+ "."
)
flagged_ants = np.concatenate((flagged_ants, ant_inds))
else:
# get flags for small sig ants and add to flag array
small_sig_flags = np.logical_or(
small_sig_flags[:, 0, :], small_sig_flags[:, 1, :]
)
small_sig_flags = np.logical_or(
small_sig_flags[self.ant_1_array, :],
small_sig_flags[self.ant_2_array, :],
)
small_sig_flags = small_sig_flags.reshape(
self.Nbls, self.Ntimes, self.Nfreqs
)
small_sig_flags = np.swapaxes(small_sig_flags, 0, 1)
small_sig_flags = small_sig_flags[:, :, :, np.newaxis]
self.flag_array = np.logical_or(self.flag_array, small_sig_flags)
# get unflagged autos
good_autos = np.delete(autos, flagged_ants)
sighat = self.data_array.real[good_autos[:, np.newaxis], :, pols].flatten()
# correct autos
sigma = van_vleck_autos(sighat)
self.data_array.real[good_autos[:, np.newaxis], :, pols] = sigma.reshape(
len(good_autos), len(pols), self.Ntimes * self.Nfreqs
)
# get good crosses
bad_ant_inds = np.nonzero(
np.logical_or(
np.isin(self.ant_1_array[0 : self.Nbls], flagged_ants),
np.isin(self.ant_2_array[0 : self.Nbls], flagged_ants),
)
)[0]
crosses = np.delete(crosses, np.nonzero(np.isin(crosses, bad_ant_inds))[0])
# correct crosses
if cheby_approx:
history_add_string += " Used Van Vleck Chebychev approximation."
# load in interpolation files
with h5py.File(DATA_PATH + "/mwa_config_data/Chebychev_coeff.h5", "r") as f:
rho_coeff = f["rho_data"][:]
with h5py.File(DATA_PATH + "/mwa_config_data/sigma1.h5", "r") as f:
sig_vec = f["sig_data"][:]
sigs = self.data_array.real[autos[:, np.newaxis], :, pols]
# find sigmas within interpolation range
in_inds = np.logical_and(sigs > 0.9, sigs <= 4.5)
# get indices and distances for bilinear interpolation
sv_inds_right = np.zeros(in_inds.shape, dtype=np.int64)
ds = np.zeros(in_inds.shape)
sv_inds_right[in_inds] = np.searchsorted(sig_vec, sigs[in_inds])
ds[in_inds] = sig_vec[sv_inds_right[in_inds]] - sigs[in_inds]
# get indices for sigmas corresponding to crosses
sig1_inds = self.ant_1_array[crosses]
sig2_inds = self.ant_2_array[crosses]
# iterate over polarization
pol_dict = {
yy: [(yy, yy), (0, 0)],
yx: [(yy, xx), (0, 1)],
xy: [(xx, yy), (1, 0)],
xx: [(xx, xx), (1, 1)],
}
for i in [xx, yy, xy, yx]:
(pol1, pol2) = pol_dict[i][1]
(sig1_pol, sig2_pol) = pol_dict[i][0]
# broadcast in_inds
broad_inds = np.logical_and(
in_inds[sig1_inds, pol1, :], in_inds[sig2_inds, pol2, :],
)
# broadcast indices and distances for bilinear interpolation
sv_inds_right1 = sv_inds_right[sig1_inds, pol1, :][broad_inds]
sv_inds_right2 = sv_inds_right[sig2_inds, pol2, :][broad_inds]
ds1 = ds[sig1_inds, pol1, :][broad_inds]
ds2 = ds[sig2_inds, pol2, :][broad_inds]
self.data_array[crosses, :, i] = van_vleck_crosses_cheby(
self.data_array[crosses, :, i],
self.data_array.real[autos[sig1_inds], :, sig1_pol],
self.data_array.real[autos[sig2_inds], :, sig2_pol],
broad_inds,
rho_coeff,
sv_inds_right1,
sv_inds_right2,
ds1,
ds2,
cheby_approx,
)
# correct yx autos
sig_inds = self.ant_1_array[good_autos]
broad_inds = np.logical_and(
in_inds[sig_inds, 0, :], in_inds[sig_inds, 1, :]
)
sv_inds_right1 = sv_inds_right[sig_inds, 0, :][broad_inds]
sv_inds_right2 = sv_inds_right[sig_inds, 1, :][broad_inds]
ds1 = ds[sig_inds, 0, :][broad_inds]
ds2 = ds[sig_inds, 1, :][broad_inds]
self.data_array[good_autos, :, yx] = van_vleck_crosses_cheby(
self.data_array[good_autos, :, yx],
self.data_array.real[good_autos, :, yy],
self.data_array.real[good_autos, :, xx],
broad_inds,
rho_coeff,
sv_inds_right1,
sv_inds_right2,
ds1,
ds2,
cheby_approx,
)
# add back in frequency axis
self.data_array = self.data_array.reshape(
(self.Nbls, self.Ntimes, self.Nfreqs, self.Npols)
)
# solve integral directly
else:
# add back in frequency axis
self.data_array = self.data_array.reshape(
(self.Nbls, self.Ntimes, self.Nfreqs, self.Npols)
)
for k in crosses:
auto1 = autos[self.ant_1_array[k]]
auto2 = autos[self.ant_2_array[k]]
for j in range(self.Nfreqs):
# get data
sig1 = self.data_array.real[
auto1, :, j, np.array([yy, yy, xx, xx])
].flatten()
sig2 = self.data_array.real[
auto2, :, j, np.array([yy, xx, yy, xx])
].flatten()
khat = self.data_array[
k, :, j, np.array([yy, yx, xy, xx])
].flatten()
# correct real
kap = van_vleck_crosses_int(khat.real, sig1, sig2, cheby_approx)
self.data_array.real[k, :, j, :] = kap.reshape(
self.Ntimes, self.Npols
)
# correct imaginary
kap = van_vleck_crosses_int(khat.imag, sig1, sig2, cheby_approx)
self.data_array.imag[k, :, j, :] = kap.reshape(
self.Ntimes, self.Npols
)
# correct yx autos
for k in good_autos:
for j in range(self.Nfreqs):
# get data
sig1 = self.data_array.real[k, :, j, yy]
sig2 = self.data_array.real[k, :, j, xx]
khat = self.data_array[k, :, j, yx]
# correct real
kap = van_vleck_crosses_int(khat.real, sig1, sig2, cheby_approx)
self.data_array.real[k, :, j, yx] = kap
# correct imaginary
kap = van_vleck_crosses_int(khat.imag, sig1, sig2, cheby_approx)
self.data_array.imag[k, :, j, yx] = kap
# correct xy autos
self.data_array[good_autos, :, :, xy] = np.conj(
self.data_array[good_autos, :, :, yx]
)
# square autos
self.data_array.real[auto_inds, :, :, pols] = (
self.data_array.real[auto_inds, :, :, pols] ** 2
)
# reshape to (ntimes, nbls, nfreqs, npols)
self.data_array = np.swapaxes(self.data_array, 0, 1)
# rescale the data
self.data_array *= self.extra_keywords["SCALEFAC"] * nsamples * 2
# return data array to desired precision
if self.data_array.dtype != data_array_dtype:
self.data_array = self.data_array.astype(data_array_dtype)
self.history += history_add_string
return flagged_ants
def read_mwa_corr_fits(
self,
filelist,
use_cotter_flags=None,
remove_dig_gains=True,
remove_coarse_band=True,
correct_cable_len=False,
correct_van_vleck=False,
cheby_approx=True,
flag_small_sig_ants=True,
phase_to_pointing_center=False,
propagate_coarse_flags=True,
flag_init=True,
edge_width=80e3,
start_flag="goodtime",
end_flag=0.0,
flag_dc_offset=True,
remove_flagged_ants=True,
background_lsts=True,
read_data=True,
data_array_dtype=np.complex64,
nsample_array_dtype=np.float32,
run_check=True,
check_extra=True,
run_check_acceptability=True,
strict_uvw_antpos_check=False,
):
"""
Read in MWA correlator gpu box files.
The default settings remove some of the instrumental effects in the bandpass
by dividing out the digital gains and the coarse band shape.
If the desired output is raw correlator data, set remove_dig_gains=False,
remove_coarse_band=False, correct_cable_len=False, and
phase_to_pointing_center=False.
Parameters
----------
filelist : list of str
The list of MWA correlator files to read from. Must include at
least one fits file and only one metafits file per data set.
Can also be a list of lists to read multiple data sets.
axis : str
Axis to concatenate files along. This enables fast concatenation
along the specified axis without the normal checking that all other
metadata agrees. This method does not guarantee correct resulting
objects. Please see the docstring for fast_concat for details.
Allowed values are: 'blt', 'freq', 'polarization'. Only used if
multiple files are passed.
use_cotter_flags : bool
Option to use cotter output mwaf flag files. Defaults to true if
cotter flag files are submitted.
remove_dig_gains : bool
Option to divide out digital gains.
remove_coarse_band : bool
Option to divide out coarse band shape.
correct_cable_len : bool
Option to apply a cable delay correction.
correct_van_vleck : bool
Option to apply a van vleck correction.
cheby_approx : bool
Only used if correct_van_vleck is True. Option to implement the van
vleck correction with a chebyshev polynomial approximation.
flag_small_sig_ants : bool
Only used if correct_van_vleck is True. Option to completely flag any
antenna that has a sigma < 0.5, as sigmas in this range generally
indicate bad data. If set to False, only the times and
frequencies at which sigma < 0.5 will be flagged for the antenna.
phase_to_pointing_center : bool
Option to phase to the observation pointing center.
propagate_coarse_flags : bool
Option to propagate flags for missing coarse channel integrations
across frequency.
flag_init: bool
Set to True in order to do routine flagging of coarse channel edges,
start or end integrations, or the center fine channel of each coarse
channel. See associated keywords.
edge_width: float
Only used if flag_init is True. The width to flag on the edge of
each coarse channel, in hz. Errors if not equal to integer multiple
of channel_width. Set to 0 for no edge flagging.
start_flag: float or str
Only used if flag_init is True. The number of seconds to flag at the
beginning of the observation. Set to 0 for no flagging. Default is
'goodtime', which uses information in the metafits file to determine
the length of time that should be flagged. Errors if input is not a
float or 'goodtime'. Errors if float input is not equal to an
integer multiple of the integration time.
end_flag: floats
Only used if flag_init is True. The number of seconds to flag at the
end of the observation. Set to 0 for no flagging. Errors if not
equal to an integer multiple of the integration time.
flag_dc_offset: bool
Only used if flag_init is True. Set to True to flag the center fine
channel of each coarse channel.
remove_flagged_ants : bool
Option to perform a select to remove antennas flagged in the metafits
file. If correct_van_vleck and flag_small_sig_ants are both True then
antennas flagged by the Van Vleck correction are also removed.
background_lsts : bool
When set to True, the lst_array is calculated in a background thread.
read_data : bool
Read in the visibility, nsample and flag data. If set to False, only
the metadata will be read in. Setting read_data to False results in
a metadata only object.
data_array_dtype : numpy dtype
Datatype to store the output data_array as. Must be either
np.complex64 (single-precision real and imaginary) or np.complex128
(double-precision real and imaginary).
nsample_array_dtype : numpy dtype
Datatype to store the output nsample_array as. Must be either
np.float64 (double-precision), np.float32 (single-precision), or
np.float16 (half-precision). Half-precision is only recommended for
cases where no sampling or averaging of baselines will occur,
because round-off errors can be quite large (~1e-3).
run_check : bool
Option to check for the existence and proper shapes of parameters
after after reading in the file (the default is True,
meaning the check will be run).
check_extra : bool
Option to check optional parameters as well as required ones (the
default is True, meaning the optional parameters will be checked).
run_check_acceptability : bool
Option to check acceptable range of the values of parameters after
reading in the file (the default is True, meaning the acceptable
range check will be done).
strict_uvw_antpos_check : bool
Option to raise an error rather than a warning if the check that
uvws match antenna positions does not pass.
Raises
------
ValueError
If required files are missing or multiple files metafits files are
included in filelist.
If files from different observations are included in filelist.
If files in fileslist have different fine channel widths
If file types other than fits, metafits, and mwaf files are included
in filelist.
"""
metafits_file = None
ppds_file = None
obs_id = None
file_dict = {}
start_time = 0.0
end_time = 0.0
included_file_nums = []
included_flag_nums = []
cotter_warning = False
num_fine_chans = 0
# do datatype checks
if data_array_dtype not in (np.complex64, np.complex128):
raise ValueError("data_array_dtype must be np.complex64 or np.complex128")
if nsample_array_dtype not in (np.float64, np.float32, np.float16):
raise ValueError(
"nsample_array_dtype must be one of: np.float64, np.float32, np.float16"
)
# do start_flag check
if not isinstance(start_flag, (int, float)):
if start_flag != "goodtime":
raise ValueError("start_flag must be int or float or 'goodtime'")
# iterate through files and organize
# create a list of included coarse channels
# find the first and last times that have data
for filename in filelist:
# update filename attribute
basename = os.path.basename(filename)
self.filename = uvutils._combine_filenames(self.filename, [basename])
self._filename.form = (len(self.filename),)
if filename.lower().endswith(".metafits"):
# force only one metafits file
if metafits_file is not None:
raise ValueError("multiple metafits files in filelist")
metafits_file = filename
elif filename.lower().endswith(".fits"):
# check if ppds file
try:
fits.getheader(filename, extname="ppds")
ppds_file = filename
except Exception:
# check obsid
head0 = fits.getheader(filename, 0)
if obs_id is None:
obs_id = head0["OBSID"]
else:
if head0["OBSID"] != obs_id:
raise ValueError(
"files from different observations submitted "
"in same list"
)
# check headers for first and last times containing data
headstart = fits.getheader(filename, 1)
headfin = fits.getheader(filename, -1)
first_time = headstart["TIME"] + headstart["MILLITIM"] / 1000.0
last_time = headfin["TIME"] + headfin["MILLITIM"] / 1000.0
if start_time == 0.0:
start_time = first_time
# check that files with a timing offset can be aligned
elif np.abs(start_time - first_time) % headstart["INTTIME"] != 0.0:
raise ValueError(
"coarse channel start times are misaligned by an amount that is not \
an integer multiple of the integration time"
)
elif start_time > first_time:
start_time = first_time
if end_time < last_time:
end_time = last_time
# get number of fine channels
if num_fine_chans == 0:
num_fine_chans = headstart["NAXIS2"]
elif num_fine_chans != headstart["NAXIS2"]:
raise ValueError(
"files submitted have different fine channel widths"
)
# get the file number from the file name;
# this will later be mapped to a coarse channel
file_num = int(filename.split("_")[-2][-2:])
if file_num not in included_file_nums:
included_file_nums.append(file_num)
# organize files
if "data" not in file_dict.keys():
file_dict["data"] = [filename]
else:
file_dict["data"].append(filename)
# save bscale keyword
if "SCALEFAC" not in self.extra_keywords.keys():
if "BSCALE" in head0.keys():
self.extra_keywords["SCALEFAC"] = head0["BSCALE"]
else:
# correlator did a divide by 4 before october 2014
self.extra_keywords["SCALEFAC"] = 0.25
# look for flag files
elif filename.lower().endswith(".mwaf"):
if use_cotter_flags is None:
use_cotter_flags = True
flag_num = int(filename.split("_")[-1][0:2])
included_flag_nums.append(flag_num)
if use_cotter_flags is False and cotter_warning is False:
warnings.warn("mwaf files submitted with use_cotter_flags=False")
cotter_warning = True
elif "flags" not in file_dict.keys():
file_dict["flags"] = [filename]
else:
file_dict["flags"].append(filename)
else:
raise ValueError("only fits, metafits, and mwaf files supported")
# checks:
if metafits_file is None and ppds_file is None:
raise ValueError("no metafits file submitted")
elif metafits_file is None:
metafits_file = ppds_file
elif ppds_file is not None:
ppds = fits.getheader(ppds_file, 0)
meta = fits.getheader(metafits_file, 0)
for key in ppds.keys():
if key not in meta.keys():
self.extra_keywords[key] = ppds[key]
if "data" not in file_dict.keys():
raise ValueError("no data files submitted")
if "flags" not in file_dict.keys() and use_cotter_flags:
raise ValueError(
"no flag files submitted. Rerun with flag files \
or use_cotter_flags=False"
)
# first set parameters that are always true
self.Nspws = 1
self.spw_array = np.array([0])
self.phase_type = "drift"
self.vis_units = "uncalib"
self.Npols = 4
self.xorientation = "east"
# get information from metafits file
with fits.open(metafits_file, memmap=True) as meta:
meta_hdr = meta[0].header
# get a list of coarse channels
coarse_chans = meta_hdr["CHANNELS"].split(",")
coarse_chans = np.array(sorted(int(i) for i in coarse_chans))
# integration time in seconds
int_time = meta_hdr["INTTIME"]
# pointing center in degrees
ra_deg = meta_hdr["RA"]
dec_deg = meta_hdr["DEC"]
ra_rad = np.pi * ra_deg / 180
dec_rad = np.pi * dec_deg / 180
# set start_flag with goodtime
if flag_init and start_flag == "goodtime":
# ppds file does not contain this key
try:
if meta_hdr["GOODTIME"] > start_time:
start_flag = meta_hdr["GOODTIME"] - start_time
# round start_flag up to nearest multiple of int_time
if start_flag % int_time > 0:
start_flag = (1 + int(start_flag / int_time)) * int_time
else:
start_flag = 0.0
except KeyError:
raise ValueError(
"To use start_flag='goodtime', a .metafits file must \
be submitted"
)
# get parameters from header
# this assumes no averaging by this code so will need to be updated
self.channel_width = float(meta_hdr.pop("FINECHAN") * 1000)
if "HISTORY" in meta_hdr:
self.history = str(meta_hdr["HISTORY"])
meta_hdr.remove("HISTORY", remove_all=True)
else:
self.history = ""
if not uvutils._check_history_version(
self.history, self.pyuvdata_version_str
):
self.history += self.pyuvdata_version_str
self.instrument = meta_hdr["TELESCOP"]
self.telescope_name = meta_hdr.pop("TELESCOP")
self.object_name = meta_hdr.pop("FILENAME")
# get rid of the instrument keyword so it doesn't get put back in
meta_hdr.remove("INSTRUME")
# get rid of keywords that uvfits.py gets rid of
bad_keys = ["SIMPLE", "EXTEND", "BITPIX", "NAXIS", "DATE-OBS"]
for key in bad_keys:
meta_hdr.remove(key, remove_all=True)
# store remaining keys in extra keywords
for key in meta_hdr:
if key == "COMMENT":
self.extra_keywords[key] = str(meta_hdr.get(key))
elif key != "":
self.extra_keywords[key] = meta_hdr.get(key)
# get antenna data from metafits file table
meta_tbl = meta[1].data
# because of polarization, each antenna # is listed twice
antenna_numbers = meta_tbl["Antenna"][1::2]
antenna_names = meta_tbl["TileName"][1::2]
antenna_flags = meta_tbl["Flag"][1::2]
cable_lens = np.asarray(meta_tbl["Length"][1::2]).astype(np.str_)
dig_gains = meta_tbl["Gains"][1::2, :].astype(np.float64)
# get antenna postions in enu coordinates
antenna_positions = np.zeros((len(antenna_numbers), 3))
antenna_positions[:, 0] = meta_tbl["East"][1::2]
antenna_positions[:, 1] = meta_tbl["North"][1::2]
antenna_positions[:, 2] = meta_tbl["Height"][1::2]
# reorder antenna parameters from metafits ordering
reordered_inds = antenna_numbers.argsort()
self.antenna_numbers = antenna_numbers[reordered_inds]
self.antenna_names = list(antenna_names[reordered_inds])
antenna_positions = antenna_positions[reordered_inds, :]
antenna_flags = antenna_flags[reordered_inds]
cable_lens = cable_lens[reordered_inds]
dig_gains = dig_gains[reordered_inds, :]
# find flagged antenna
flagged_ants = self.antenna_numbers[np.where(antenna_flags == 1)]
# set parameters from other parameters
self.Nants_data = len(self.antenna_numbers)
self.Nants_telescope = len(self.antenna_numbers)
self.Nbls = int(
len(self.antenna_numbers) * (len(self.antenna_numbers) + 1) / 2.0
)
# get telescope parameters
self.set_telescope_params()
# build time array of centers
time_array = np.arange(
start_time + int_time / 2.0, end_time + int_time / 2.0 + int_time, int_time
)
# convert to time to jd floats
float_time_array = Time(time_array, format="unix", scale="utc").jd.astype(float)
# build into time array
self.time_array = np.repeat(float_time_array, self.Nbls)
self.Ntimes = len(time_array)
self.Nblts = int(self.Nbls * self.Ntimes)
# convert times to lst
proc = self.set_lsts_from_time_array(background=background_lsts)
self.integration_time = np.full((self.Nblts), int_time)
# convert antenna positions from enu to ecef
# antenna positions are "relative to
# the centre of the array in local topocentric \"east\", \"north\",
# \"height\". Units are meters."
antenna_positions_ecef = uvutils.ECEF_from_ENU(
antenna_positions, *self.telescope_location_lat_lon_alt
)
# make antenna positions relative to telescope location
self.antenna_positions = antenna_positions_ecef - self.telescope_location
# make initial antenna arrays, where ant_1 <= ant_2
# itertools.combinations_with_replacement returns
# all pairs in the range 0...Nants_telescope
# including pairs with the same number (e.g. (0,0) auto-correlation).
# this is a little faster than having nested for-loops moving over the
# upper triangle of antenna-pair combinations matrix.
ant_1_array, ant_2_array = np.transpose(
list(
itertools.combinations_with_replacement(
np.arange(self.Nants_telescope), 2
)
)
)
self.ant_1_array = np.tile(np.array(ant_1_array), self.Ntimes)
self.ant_2_array = np.tile(np.array(ant_2_array), self.Ntimes)
self.baseline_array = self.antnums_to_baseline(
self.ant_1_array, self.ant_2_array
)
# create self.uvw_array
self.set_uvws_from_antenna_positions(allow_phasing=False)
# coarse channel mapping:
# channels in group 0-128 go in order; channels in group 129-155 go in
# reverse order
# that is, if the lowest channel is 127, it will be assigned to the
# first file
# channel 128 will be assigned to the second file
# then the highest channel will be assigned to the third file
# and the next hightest channel assigned to the fourth file, and so on
count = np.count_nonzero(coarse_chans <= 128)
# map all file numbers to coarse channel numbers
file_nums_to_coarse = {
i + 1: coarse_chans[i]
if i < count
else coarse_chans[(len(coarse_chans) + count - i - 1)]
for i in range(len(coarse_chans))
}
# map included coarse channels to file numbers
coarse_to_incl_files = {}
for i in included_file_nums:
coarse_to_incl_files[file_nums_to_coarse[i]] = i
# sort included coarse channels
included_coarse_chans = sorted(coarse_to_incl_files.keys())
# map included file numbers to an index that orders them
file_nums_to_index = {}
for i in included_coarse_chans:
file_nums_to_index[coarse_to_incl_files[i]] = included_coarse_chans.index(i)
# check that coarse channels are contiguous.
chans = np.array(included_coarse_chans)
for i in np.diff(chans):
if i != 1:
warnings.warn("coarse channels are not contiguous for this observation")
break
# warn user if not all coarse channels are included
if len(included_coarse_chans) != len(coarse_chans):
warnings.warn("some coarse channel files were not submitted")
# build frequency array
self.Nfreqs = len(included_coarse_chans) * num_fine_chans
# TODO: Spw axis to be collapsed in future release
self.freq_array = np.zeros((1, self.Nfreqs))
# each coarse channel is split into 128 fine channels of width 10 kHz.
# The first fine channel for each coarse channel is centered on the
# lower bound frequency of that channel and its center frequency is
# computed as fine_center = coarse_channel_number * 1280-640 (kHz).
# If the fine channels have been averaged (added) by some factor, the
# center of the resulting channel is found by averaging the centers of
# the first and last fine channels it is made up of.
# That is, avg_fine_center=(lowest_fine_center+highest_fine_center)/2
# where highest_fine_center=lowest_fine_center+(avg_factor-1)*10 kHz
# so avg_fine_center=(lowest_fine_center+lowest_fine_center+(avg_factor-1)*10)/2
# =lowest_fine_center+((avg_factor-1)*10)/2
# =lowest_fine_center+offset
# Calculate offset=((avg_factor-1)*10)/2 to build the frequency array
avg_factor = self.channel_width / 10000
width = self.channel_width / 1000
offset = (avg_factor - 1) * 10 / 2.0
for i in range(len(included_coarse_chans)):
# get the lowest fine freq of the coarse channel (kHz)
lower_fine_freq = included_coarse_chans[i] * 1280 - 640
# find the center of the lowest averaged channel
first_center = lower_fine_freq + offset
# add the channel centers for this coarse channel into
# the frequency array (converting from kHz to Hz)
self.freq_array[
0, int(i * num_fine_chans) : int((i + 1) * num_fine_chans)
] = (
np.arange(first_center, first_center + num_fine_chans * width, width)
* 1000
)
# polarizations are ordered yy, yx, xy, xx
self.polarization_array = np.array([-6, -8, -7, -5])
if read_data:
# read data into an array with dimensions (time, uv, baselines*pols)
self.data_array = np.zeros(
(self.Ntimes, self.Nfreqs, self.Nbls * self.Npols),
dtype=data_array_dtype,
)
self.nsample_array = np.zeros(
(self.Ntimes, self.Nbls, self.Nfreqs, self.Npols),
dtype=nsample_array_dtype,
)
self.flag_array = np.full(
(self.Ntimes, self.Nbls, len(included_coarse_chans), self.Npols), True
)
# read data files
for filename in file_dict["data"]:
self._read_fits_file(
filename, time_array, file_nums_to_index, num_fine_chans, int_time
)
# build mapper from antenna numbers and polarizations to pfb inputs
corr_ants_to_pfb_inputs = {}
for i in range(len(antenna_numbers)):
for p in range(2):
corr_ants_to_pfb_inputs[(antenna_numbers[i], p)] = 2 * i + p
# for mapping, start with a pair of antennas/polarizations
# this is the pair we want to find the data for
# map the pair to the corresponding pfb input indices
# map the pfb input indices to the pfb output indices
# these are the indices for the data corresponding to the initial
# antenna/pol pair
# These two 1D arrays will be both C and F contiguous
# but we are explicitly declaring C to be consistent with the rest
# of the python which interacts with the C/Cython code.
# generate a mapping index array
map_inds = np.zeros((self.Nbls * self.Npols), dtype=np.int32, order="C",)
# generate a conjugation array
conj = np.full((self.Nbls * self.Npols), False, dtype=np.bool_, order="C",)
_corr_fits.generate_map(corr_ants_to_pfb_inputs, map_inds, conj)
# propagate coarse flags
if propagate_coarse_flags:
self.flag_array = np.any(self.flag_array, axis=2)
self.flag_array = self.flag_array[:, :, np.newaxis, :]
self.flag_array = np.repeat(self.flag_array, self.Nfreqs, axis=2)
else:
self.flag_array = np.repeat(self.flag_array, num_fine_chans, axis=2)
# reorder data
self.data_array = np.take(self.data_array, map_inds, axis=2)
# conjugate data
self.data_array[:, :, conj] = np.conj(self.data_array[:, :, conj])
# reshape data
self.data_array = self.data_array.reshape(
(self.Ntimes, self.Nfreqs, self.Nbls, self.Npols)
)
self.data_array = np.swapaxes(self.data_array, 1, 2)
# van vleck correction
if correct_van_vleck:
flagged_ants = self.van_vleck_correction(
flagged_ants,
cheby_approx=cheby_approx,
data_array_dtype=data_array_dtype,
remove_flagged_ants=remove_flagged_ants,
flag_small_sig_ants=flag_small_sig_ants,
)
else:
# when MWA data is cast to float for the correlator, the division
# by 127 introduces small errors that are mitigated when the data
# is cast back into integer
self.data_array /= self.extra_keywords["SCALEFAC"]
np.rint(self.data_array, out=self.data_array)
self.data_array *= self.extra_keywords["SCALEFAC"]
# combine baseline and time axes
self.data_array = self.data_array.reshape(
(self.Nblts, self.Nfreqs, self.Npols)
)
self.flag_array = self.flag_array.reshape(
(self.Nblts, self.Nfreqs, self.Npols)
)
self.nsample_array = self.nsample_array.reshape(
(self.Nblts, self.Nfreqs, self.Npols)
)
# divide out digital gains
if remove_dig_gains:
self.history += " Divided out digital gains."
# get gains for included coarse channels
coarse_inds = np.where(np.isin(coarse_chans, included_coarse_chans))[0]
# during commissioning a shift in the bit selection in the digital
# receiver was implemented which effectively multiplies the data by
# a factor of 64. To account for this, the digital gains are divided
# by a factor of 64 here. For a more detailed explanation, see PR #908.
dig_gains = dig_gains[:, coarse_inds] / 64
dig_gains = np.repeat(dig_gains, num_fine_chans, axis=1)
self.data_array /= (
dig_gains[self.ant_1_array, :, np.newaxis]
* dig_gains[self.ant_2_array, :, np.newaxis]
)
# divide out coarse band shape
if remove_coarse_band:
self.history += " Divided out coarse channel bandpass."
# get coarse band shape
with open(
DATA_PATH + "/mwa_config_data/MWA_rev_cb_10khz_doubles.txt", "r"
) as f:
cb = f.read().splitlines()
cb_array = np.array(cb).astype(np.float64)
cb_array = cb_array.reshape(int(128 / avg_factor), int(avg_factor))
cb_array = np.average(cb_array, axis=1)
cb_array = cb_array[0:num_fine_chans]
cb_array = np.tile(cb_array, len(included_coarse_chans))
self.data_array /= cb_array[:, np.newaxis]
# cable delay corrections
if correct_cable_len:
self.correct_cable_length(cable_lens)
# add spectral window index
# TODO: Spw axis to be collapsed in future release
self.data_array = self.data_array[:, np.newaxis, :, :]
self.flag_array = self.flag_array[:, np.newaxis, :, :]
self.nsample_array = self.nsample_array[:, np.newaxis, :, :]
if use_cotter_flags:
# throw an error if matching files not submitted
if included_file_nums != included_flag_nums:
raise ValueError(
"flag file coarse bands do not match data file coarse bands"
)
warnings.warn(
"coarse channel, start time, and end time flagging will default \
to the more aggressive of flag_init and AOFlagger"
)
for filename in file_dict["flags"]:
flag_num = int(filename.split("_")[-1][0:2])
# map file number to frequency index
freq_ind = file_nums_to_index[flag_num] * num_fine_chans
with fits.open(filename) as aoflags:
flags = aoflags[1].data.field("FLAGS")
# some flag files are longer than data; crop the ends
flags = flags[: self.Nblts, :]
# some flag files are shorter than data; assume same end time
blt_ind = self.Nblts - len(flags)
flags = flags[:, np.newaxis, :, np.newaxis]
self.flag_array[
blt_ind:, :, freq_ind : freq_ind + num_fine_chans, :
] = np.logical_or(
self.flag_array[
blt_ind:, :, freq_ind : freq_ind + num_fine_chans, :
],
flags,
)
if flag_init:
self.flag_init(
num_fine_chans,
edge_width=edge_width,
start_flag=start_flag,
end_flag=end_flag,
flag_dc_offset=flag_dc_offset,
)
# to account for discrepancies between file conventions, in order
# to be consistent with the uvw vector direction, all the data must
# be conjugated
self.data_array = np.conj(self.data_array)
# wait for LSTs if set in background
if proc is not None:
proc.join()
if not self.metadata_only:
# reorder polarizations
# reorder pols calls check so must come after
# lst thread is re-joined.
self.reorder_pols(run_check=False)
# remove bad antennas or flag bad ants
# select must be called after lst thread is re-joined
if remove_flagged_ants:
good_ants = np.delete(self.antenna_numbers, flagged_ants)
self.select(antenna_nums=good_ants)
else:
if not self.metadata_only:
# generage baseline flags for flagged ants
bad_ant_inds = np.nonzero(
np.logical_or(
np.isin(self.ant_1_array, flagged_ants),
np.isin(self.ant_2_array, flagged_ants),
)
)[0]
# TODO: Spw axis to be collapsed in future release
self.flag_array[bad_ant_inds, :, :, :] = True
# phasing
if phase_to_pointing_center:
self.phase(ra_rad, dec_rad)
# check if object is self-consistent
# uvws are calcuated using pyuvdata, so turn off the check for speed.
if run_check:
self.check(
check_extra=check_extra,
run_check_acceptability=run_check_acceptability,
strict_uvw_antpos_check=strict_uvw_antpos_check,
)