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author | Aaron LI <aly@aaronly.me> | 2017-06-13 08:47:08 +0800 |
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committer | Aaron LI <aly@aaronly.me> | 2017-06-13 08:47:08 +0800 |
commit | 3148e665ea336c0b4b97b3ebe52546f552720073 (patch) | |
tree | dbf01cf221d6cede1c2f40597341f454ac74b6b6 /astro/oskar | |
parent | 14c32fbbe8276153395beeac67776254e145357c (diff) | |
download | atoolbox-3148e665ea336c0b4b97b3ebe52546f552720073.tar.bz2 |
Add astro/oskar/fits2skymodel.py
Diffstat (limited to 'astro/oskar')
-rwxr-xr-x | astro/oskar/fits2skymodel.py | 248 |
1 files changed, 248 insertions, 0 deletions
diff --git a/astro/oskar/fits2skymodel.py b/astro/oskar/fits2skymodel.py new file mode 100755 index 0000000..781b907 --- /dev/null +++ b/astro/oskar/fits2skymodel.py @@ -0,0 +1,248 @@ +#!/usr/bin/env python3 +# +# Copyright (c) 2017 Weitian LI <weitian@aaronly.me> +# MIT License +# + +""" +Convert a FITS image to OSKAR sky model for simulation usage. + +NOTE +---- +The OSKAR sky model consists of all the valid (>threshold) pixels +from the given image (slice), and fluxes are given in unit [Jy], +therefore, the input image should be converted from brightness +temperature [K] to unit [Jy/pixel]. + +References +---------- +[1] GitHub: OxfordSKA/OSKAR + https://github.com/OxfordSKA/OSKAR +[2] OSKAR - Sky Model + http://www.oerc.ox.ac.uk/~ska/oskar2/OSKAR-Sky-Model.pdf +[3] OSKAR - Settings + http://www.oerc.ox.ac.uk/~ska/oskar2/OSKAR-Settings.pdf +""" + +import os +import sys +import argparse +import logging +from datetime import datetime + +import numpy as np +import astropy.io.fits as fits +import astropy.constants as ac +from astropy.wcs import WCS + + +logging.basicConfig(level=logging.INFO) +logger = logging.getLogger(os.path.basename(sys.argv[0])) + + +class SkyModel: + """ + OSKAR sky model. + + Parameters + ---------- + image : 2D float `~numpy.ndarray` + Input image array; unit [K] (brightness temperature) + freq : float + Frequency of the input image slice; unit [MHz] + pixsize : float + Pixel size of the input image; unit [arcmin] + ra0, dec0 : float + The coordinate of the image center; unit [deg] + minvalue : float, optional + The minimum threshold for the image values + projection : str, optional + The WCS projection for the image; default "TAN" + TODO: support "SIN" etc. + """ + def __init__(self, image, freq, pixsize, ra0, dec0, + minvalue=1e-4, projection="TAN"): + self.image = image # K (brightness temperature) + self.freq = freq # MHz + self.pixsize = pixsize # arcmin + self.ra0 = ra0 # deg + self.dec0 = dec0 # deg + self.minvalue = minvalue + self.projection = projection + logger.info("SkyModel: Loaded image @ %.2f [MHz]" % freq) + + @property + def wcs(self): + """ + WCS for the given image slice. + """ + shape = self.image.shape + delta = self.pixsize / 60.0 # deg + wcs_ = WCS(naxis=2) + wcs_.wcs.ctype = ["RA---"+self.projection, "DEC--"+self.projection] + wcs_.wcs.crval = np.array([self.ra0, self.dec0]) + wcs_.wcs.crpix = np.array([shape[1], shape[0]]) / 2.0 + 1 + wcs_.wcs.cdelt = np.array([delta, delta]) + return wcs_ + + @property + def fits_header(self): + header = self.wcs.to_header() + header["BUNIT"] = ("Jy/pixel", "Brightness unit") + header["FREQ"] = (self.freq, "Frequency [MHz]") + header["RA0"] = (self.ra0, "Center R.A. [deg]") + header["DEC0"] = (self.dec0, "Center Dec. [deg]") + header["PIXSIZE"] = (self.pixsize, "Pixel size [arcmin]") + return header + + @property + def factor_K2JyPixel(self): + """ + Conversion factor to convert brightness unit from 'K' to 'Jy/pixel' + + http://www.iram.fr/IRAMFR/IS/IS2002/html_1/node187.html + """ + pixarea = np.deg2rad(self.pixsize/60.0) ** 2 # [sr] + kB = ac.k_B.si.value # Boltzmann constant [J/K] + c0 = ac.c.si.value # speed of light in vacuum [m/s] + freqHz = self.freq * 1e6 # [Hz] + factor = 2*kB * 1.0e26 * pixarea * (freqHz/c0)**2 + return factor + + @property + def ra_dec(self): + """ + Calculate the (ra, dec) of each image pixel using the above WCS. + + NOTE: axis ordering difference between numpy array and FITS + """ + shape = self.image.shape + wcs = self.wcs + x, y = np.meshgrid(np.arange(shape[1]), np.arange(shape[0])) + pix = np.column_stack([x.flatten(), y.flatten()]) + world = wcs.wcs_pix2world(pix, 0) + ra = world[:, 0].reshape(shape) + dec = world[:, 1].reshape(shape) + return (ra, dec) + + @property + def sky(self): + """ + OSKAR sky model array converted from the input image. + + Columns + ------- + ra : (J2000) right ascension (deg) + dec : (J2000) declination (deg) + flux : source (Stokes I) flux density (Jy) + """ + idx = self.image.flatten() >= self.minvalue + ra, dec = self.ra_dec + ra = ra.flatten()[idx] + dec = dec.flatten()[idx] + flux = self.image.flatten()[idx] * self.factor_K2JyPixel + sky_ = np.column_stack([ra, dec, flux]) + return sky_ + + def write_sky_model(self, outfile, clobber=False): + """ + Write the converted sky model for simulation. + """ + if os.path.exists(outfile) and (not clobber): + raise OSError("OSKAR sky model file already exists: " % outfile) + sky = self.sky + nsources = sky.shape[0] + logger.info("Number of sources: %d" % nsources) + header = ("Frequency = %.3f [MHz]\n" % self.freq + + "Pixel size = %.2f [arcmin]\n" % self.pixsize + + "RA0 = %.4f [deg]\n" % self.ra0 + + "Dec0 = %.4f [deg]\n" % self.dec0 + + "Number of sources = %d\n\n" % len(sky) + + "R.A.[deg] Dec.[deg] flux[Jy]") + np.savetxt(outfile, sky, fmt='%.10e, %.10e, %.10e', header=header) + logger.info("Wrote OSKAR sky model to file: %s" % outfile) + + def write_fits(self, outfile, oldheader=None, clobber=False): + if os.path.exists(outfile) and (not clobber): + raise OSError("Sky FITS already exists: " % outfile) + if oldheader is not None: + header = oldheader + header.extend(self.fits_header, update=True) + else: + header = self.fits_header + header.add_history(datetime.now().isoformat()) + header.add_history(" ".join(sys.argv)) + image = self.image + image[image < self.minvalue] = np.nan + image *= self.factor_K2JyPixel + hdu = fits.PrimaryHDU(data=image, header=header) + try: + hdu.writeto(outfile, overwrite=True) + except TypeError: + hdu.writeto(outfile, clobber=True) # old astropy versions + logger.info("Wrote FITS image of sky model to file: %s" % outfile) + + +def main(): + parser = argparse.ArgumentParser( + description="Convert FITS image to OSKAR sky model") + parser.add_argument("-C", "--clobber", dest="clobber", + action="store_true", + help="overwrite existing file") + parser.add_argument("-r", "--ra0", dest="ra0", type=float, required=True, + help="R.A. of the image center") + parser.add_argument("-d", "--dec0", dest="dec0", type=float, required=True, + help="Dec. of the image center") + parser.add_argument("-p", "--pix-size", dest="pixsize", type=float, + help="image pixel size [arcmin]; " + + "(default: obtain from the FITS header 'PIXSIZE')") + parser.add_argument("-f", "--freq", dest="freq", type=float, + help="frequency [MHz] the image measured; " + + "(default: obtain from the FITS header 'FREQ')") + exgrp = parser.add_mutually_exclusive_group() + exgrp.add_argument("-m", "--min-value", dest="minvalue", type=float, + help="minimum threshold to the output sky model " + + "(default: 1e-4, i.e., 0.1 mK)") + exgrp.add_argument("-M", "--min-peak-fraction", dest="minpfrac", + type=float, + help="minimum threshold determined as the fraction " + + "the peak value to the output sky model") + # + parser.add_argument("-F", "--osm-fits", dest="osmfits", + action="store_true", + help="save a FITS version of the converted sky model") + parser.add_argument("infile", help="input FITS image") + parser.add_argument("outfile", nargs="?", + help="output OSKAR sky model (default: " + + "save basename as the input FITS image)") + args = parser.parse_args() + + if args.outfile: + outfile = args.outfile + else: + outfile = os.path.splitext(args.infile)[0] + ".osm" + + with fits.open(args.infile) as f: + image = f[0].data + header = f[0].header + logger.info("Read image slice: %s" % args.infile) + freq = args.freq if args.freq else header["FREQ"] # [MHz] + pixsize = args.pixsize if args.pixsize else header["PIXSIZE"] # [arcmin] + logger.info("Frequency: %.2f [MHz]" % freq) + logger.info("Pixel size: %.2f [arcmin]" % pixsize) + minvalue = 1e-4 # i.e., 0.1 [mK] + if args.minvalue: + minvalue = args.minvalue + if args.minpfrac: + minvalue = args.minpfrac * image.max() + logger.info("Minimum threshold: %g [K]" % minvalue) + skymodel = SkyModel(image=image, freq=freq, ra0=args.ra0, dec0=args.dec0, + pixsize=pixsize, minvalue=minvalue) + skymodel.write_sky_model(outfile, clobber=args.clobber) + if args.osmfits: + outfits = outfile + ".fits" + skymodel.write_fits(outfits, oldheader=header, clobber=args.clobber) + + +if __name__ == "__main__": + main() |