#!/usr/bin/env python3 # # Copyright (c) 2017 Weitian LI # MIT license """ Make the radial surface brightness profile (SBP) regions, consisting a series of annulus/pie regions, which later been used to extract the SBP. Algorithm --------- 1. innermost 10 regions, meet the following two conditions: * width >=5 pixels * >=50 counts within 0.7-7.0 keV 2. outer regions: * R_out = R_in * ratio (e.g., 1.2) * signal-to-noise ratio (SNR) >= threshold (e.g., 1.5) """ import os import argparse import subprocess import logging import tempfile import shutil import math from _context import acispy from acispy.header import read_keyword from acispy.manifest import get_manifest from acispy.pfiles import setup_pfiles from acispy.region import Regions from acispy.spectrum import Spectrum from acispy.ds9 import ds9_view logging.basicConfig(level=logging.INFO) logger = logging.getLogger(__name__) def extract_spec(outfile, evtfile, region, clobber=False): """ Extract the spectrum within region from the event file. """ clobber = "yes" if clobber else "no" subprocess.check_call(["punlearn", "dmextract"]) subprocess.check_call([ "dmextract", "infile=%s[sky=%s][bin pi]" % (evtfile, region), "outfile=%s" % outfile, "clobber=%s" % clobber ]) def calc_snr(region, evt, bkg=None, elow=700, ehigh=7000, elow_pb=9500, ehigh_pb=12000): """ Calculate the signal-to-noise ratio (SNR) for the source spectrum with respect to the background spectrum, with particle background renormalization considered. The source and background spectra are extracted from the corresponding event files within the given region. NOTE ---- * If the given background is already a spectrum (e.g., the corrected background spectrum), then just use it; * If ``bkg=None``, then just return ``math.inf``. Definition ---------- SNR = (flux_src / flux_bkg) * (pbflux_bkg / pbflux_src) Parameters ---------- region : str Region string within which to calculate the SNR evt : str Input (source) event file bkg : str, optional Filename of the background event file or corrected background spectrum. elow, ehigh : float, optional Lower and upper energy limit to calculate the photon counts. elow_pb, ehigh_pb : float, optional Lower and upper energy limit of the particle background. """ if bkg is None: return math.inf tf1 = tempfile.NamedTemporaryFile() tf2 = tempfile.NamedTemporaryFile() # Source spectrum extract_spec(tf1.name, evtfile=evt, region=region, clobber=True) # Background spectrum if read_keyword(bkg, keyword="HDUCLAS1")["value"] == "SPECTRUM": shutil.copy(bkg, tf2.name) else: extract_spec(tf2.name, evtfile=bkg, region=region, clobber=True) # Calculate SNR spec = Spectrum(tf1.name) spec_bkg = Spectrum(tf2.name) flux = spec.calc_flux(elow=elow, ehigh=ehigh) flux_bkg = spec_bkg.calc_flux(elow=elow, ehigh=ehigh) pbflux = spec.calc_pb_flux(elow=elow_pb, ehigh=ehigh_pb) pbflux_bkg = spec_bkg.calc_pb_flux(elow=elow_pb, ehigh=ehigh_pb) snr = (flux / flux_bkg) * (pbflux_bkg / pbflux) tf1.close() tf2.close() return snr def get_counts(evtfile, region, elow=700, ehigh=7000): fenergy = "energy=%s:%s" % (elow, ehigh) subprocess.check_call(["punlearn", "dmlist"]) output = subprocess.check_output([ "dmlist", "infile=%s[%s][sky=%s]" % (evtfile, fenergy, region), "opt=counts" ]).decode("utf-8").strip() counts = int(output) return counts def gen_regions_inner(evtfile, center, rin, min_width=5, min_counts=50, elow=700, ehigh=7000): """ Generate the innermost regions, which meets the following conditions: * width >=5 pixels * >=50 counts within 0.7-7.0 keV """ x, y = center rout = rin + min_width region = "pie(%s,%s,%.2f,%.2f,0,360)" % (x, y, rin, rout) counts = get_counts(evtfile, region=region, elow=elow, ehigh=ehigh) while counts < min_counts: rout += 1 region = "pie(%s,%s,%.2f,%.2f,0,360)" % (x, y, rin, rout) counts = get_counts(evtfile, region=region, elow=elow, ehigh=ehigh) return (rout, region) def gen_regions(center, evt, bkg=None, n_inner=10, min_counts=50, min_width=5, ratio_radius=1.2, snr_thresh=1.5, elow=700, ehigh=7000, elow_pb=9500, ehigh_pb=12000): """ Generate the SBP regions, consisting the inner- and outer-type two parts. """ regions = [] logger.info("Generating %d inner-type regions ..." % n_inner) rin = 0.0 for i in range(n_inner): rout, region = gen_regions_inner( evtfile=evt, center=center, rin=rin, min_width=min_width, min_counts=min_counts, elow=elow, ehigh=ehigh) rin = rout snr = calc_snr(region, evt=evt, bkg=bkg, elow=elow, ehigh=ehigh, elow_pb=elow_pb, ehigh_pb=ehigh_pb) regions.append(region) logger.info("Region #%d: %s; SNR=%.3f" % (len(regions), regions[-1], snr)) logger.info("Generating outer-type regions (SNR >= %s) ..." % snr_thresh) x, y = center rout = rin * ratio_radius region = "pie(%s,%s,%.2f,%.2f,0,360)" % (x, y, rin, rout) counts = get_counts(evt, region=region, elow=elow, ehigh=ehigh) while counts >= min_counts: snr = calc_snr(region, evt=evt, bkg=bkg, elow=elow, ehigh=ehigh, elow_pb=elow_pb, ehigh_pb=ehigh_pb) if snr < snr_thresh: break regions.append(region) logger.info("Region #%d: %s; SNR=%.3f" % (len(regions), regions[-1], snr)) rin = rout rout = rin * ratio_radius region = "pie(%s,%s,%.2f,%.2f,0,360)" % (x, y, rin, rout) counts = get_counts(evt, region=region, elow=elow, ehigh=ehigh) logger.info("Finished with %d SBP regions." % len(regions)) return regions def main(): parser = argparse.ArgumentParser( description="Make the SBP regions") parser.add_argument("-L", "--elow", dest="elow", type=int, default=700, help="lower energy limit to calculate the photon " + "counts [eV] (default: 700 eV)") parser.add_argument("-H", "--ehigh", dest="ehigh", type=int, default=7000, help="upper energy limit to calculate the photon " + "counts [eV] (default: 7000 eV)") parser.add_argument("-p", "--elow-pb", dest="elow_pb", type=int, default=9500, help="lower energy limit of the particle " + "background [eV] (default: 9500 eV)") parser.add_argument("-P", "--ehigh-pb", dest="ehigh_pb", type=int, default=12000, help="upper energy limit of the particle " + "background [eV] (default: 12000 eV)") parser.add_argument("-m", "--min-counts", dest="min_counts", type=int, default=50, help="minimum photon counts of echo SBP " + "region (default: 50)") parser.add_argument("-M", "--min-width", dest="min_width", type=int, default=5, help="minimum annulus/pie width of the inner-type " + "regions (default: 5 [pix])") parser.add_argument("-N", "--n-inner", dest="n_inner", type=int, default=10, help="number of the inner-type regions (default: 10)") parser.add_argument("-R", "--ratio-radius", dest="ratio_radius", type=float, default=1.2, help="ratio of outer radius w.r.t. inner radius " + "(default: 1.2)") parser.add_argument("-S", "--snr-thresh", dest="snr_thresh", type=float, default=1.5, help="lower threshold of the SNR (default: 1.5)") parser.add_argument("-V", "--view", dest="view", action="store_true", help="open DS9 to view output centroid") parser.add_argument("-C", "--clobber", dest="clobber", action="store_true", help="overwrite existing files") parser.add_argument("-b", "--bkg", dest="bkg", help="background file for SNR calculation; " + "may be blanksky or corrected background spectrum") parser.add_argument("-c", "--center", dest="center", help="Region file specifying the center " + "(default: 'reg_centroid' from manifest)") parser.add_argument("-i", "--infile", dest="infile", help="input event file " + "(default: 'evt2_clean' from manifest)") parser.add_argument("-o", "--outfile", dest="outfile", default="sbprofile.reg", help="output SBP region filename " + "(default: sbprofile.reg)") args = parser.parse_args() if os.path.exists(args.outfile): if args.clobber: os.remove(args.outfile) else: raise OSError("File already exists: %s" % args.outfile) setup_pfiles(["dmlist", "dmstat", "dmextract"]) manifest = get_manifest() if args.infile: infile = args.infile else: infile = manifest.getpath("evt2_clean", relative=True) if args.center: center_reg = args.center else: center_reg = manifest.getpath("reg_centroid", relative=True) region = Regions(center_reg).regions[0] center = (region.xc, region.yc) regions = gen_regions(center=center, evt=infile, bkg=args.bkg, n_inner=args.n_inner, min_counts=args.min_counts, min_width=args.min_width, ratio_radius=args.ratio_radius, snr_thresh=args.snr_thresh, elow=args.elow, ehigh=args.ehigh, elow_pb=args.elow_pb, ehigh_pb=args.ehigh_pb) open(args.outfile, "w").write("\n".join(regions) + "\n") if args.view: ds9_view(infile, regfile=args.outfile) # Add generated SBP region file to manifest key = "sbp_reg" manifest.setpath(key, args.outfile) logger.info("Added '%s' to manifest: %s" % (key, manifest.get(key))) if __name__ == "__main__": main()