예제 #1
0
    def run_analysis(self, argv):
        """Run this analysis"""
        args = self._parser.parse_args(argv)

        if not HAVE_ST:
            raise RuntimeError(
                "Trying to run fermipy analysis, but don't have ST")

        if is_not_null(args.roi_baseline):
            gta = GTAnalysis.create(args.roi_baseline, args.config)
        else:
            gta = GTAnalysis(args.config,
                             logging={'verbosity': 3},
                             fileio={'workdir_regex': '\.xml$|\.npy$'})
        gta.print_roi()
        
        test_source = args.target
        gta.sed(test_source, outfile='sed_%s.fits' % 'FL8Y', make_plots=True)
        gta.extension(test_source, make_plots=True)
        return gta
예제 #2
0
class ExtensionFit:
    def __init__(self, configFile):

        self.gta = GTAnalysis(configFile, logging={'verbosity': 3})
        self.target = None
        self.targetRadius = None
        self.distance = None
        self.catalog = fits.getdata('/users-data/mfalxa/code/gll_psch_v13.fit',
                                    1)

    def setSourceName(self, sourceObject, newName):
        self.gta.delete_source(sourceObject['name'])
        self.gta.add_source(newName, sourceObject)

    ''' INITIALIZE '''

    def initialize(self, sizeROI, rInner, addToROI, TSMin, debug):

        self.gta.setup()
        if self.gta.config['selection']['emin'] >= 10000:
            self.gta.set_parameter('galdiff', 'Scale', 30000)

        if debug == True:
            self.gta.make_plots('startAll')
            self.gta.residmap(prefix='startAll', make_plots=True)

        # Get model source names
        sourceList = self.gta.get_sources(exclude=['isodiff', 'galdiff'])

        # Delete sources unassociated with TS < 50
        for i in range(len(sourceList)):
            if sourceList[i]['catalog']['TS_value'] < TSMin and self.catalog[
                    'CLASS'][self.catalog['Source_Name'] == sourceList[i]
                             ['name']][0] == '':
                self.gta.delete_source(sourceList[i]['name'])

        closests = self.gta.get_sources(distance=rInner,
                                        exclude=['isodiff', 'galdiff'])

        # Delete all unidentified sources
        for i in range(len(closests)):
            if self.catalog['CLASS'][self.catalog['Source_Name'] == closests[i]
                                     ['name']][0].isupper() == False:
                self.gta.delete_source(closests[i]['name'])
            if self.catalog['CLASS'][self.catalog['Source_Name'] == closests[i]
                                     ['name']][0] == 'SFR':
                self.target = closests[i]
                self.setSourceName(self.target, 'TESTSOURCE')

# If debug, save ROI and make plots
        if debug == True:
            self.gta.write_roi('startModel')
            self.gta.residmap(prefix='start', make_plots=True)
            self.gta.make_plots('start')

        # Optmize spectral parameters for sources with npred > 1
        self.gta.optimize(npred_threshold=1, skip=['isodiff'])

        # Get model source names
        sourceList = self.gta.get_sources(distance=sizeROI + addToROI,
                                          square=True,
                                          exclude=['isodiff', 'galdiff'])

        # Iterate source localizing on source list
        for i in range(len(sourceList)):
            if sourceList[i].extended == False:
                self.gta.localize(sourceList[i]['name'],
                                  write_fits=False,
                                  write_npy=False,
                                  update=True)

        # Free sources within ROI size + extra distance from center
        self.gta.free_sources(distance=sizeROI + addToROI, square=True)

        # Re-optimize ROI
        self.gta.optimize(skip=['isodiff'])

        # Save and make plots if debug
        if debug == True:
            self.gta.write_roi('modelInitialized')
            self.gta.residmap(prefix='initialized', make_plots=True)
            self.gta.make_plots('initialized')

        # Lock sources
        self.gta.free_sources(free=False)

    ''' OUTER REGION '''
    def outerRegionAnalysis(self, sizeROI, rInner, sqrtTsThreshold,
                            minSeparation, debug):

        self.gta.free_sources(distance=sizeROI,
                              pars='norm',
                              square=True,
                              free=True)
        self.gta.free_sources(distance=rInner, free=False)
        self.gta.free_source('galdiff', free=True)
        self.gta.free_source('isodiff', free=False)

        # Seek new sources until none are found
        sourceModel = {
            'SpectrumType': 'PowerLaw',
            'Index': 2.0,
            'Scale': 30000,
            'Prefactor': 1.e-15,
            'SpatialModel': 'PointSource'
        }
        newSources = self.gta.find_sources(sqrt_ts_threshold=sqrtTsThreshold,
                                           min_separation=minSeparation,
                                           model=sourceModel,
                                           **{
                                               'search_skydir':
                                               self.gta.roi.skydir,
                                               'search_minmax_radius':
                                               [rInner, sizeROI]
                                           })

        if len(newSources) > 0:
            for i in range(len(newSources)):
                if newSources['sources'][i]['ts'] > 100.:
                    self.gta.set_source_spectrum(
                        newSources['sources'][i]['name'],
                        spectrum_type='LogParabola')
                    self.gta.free_source(newSources['sources'][i]['name'])
                    self.gta.fit()
                    self.gta.free_source(newSources['sources'][i]['name'],
                                         free=False)

        # Optimize all ROI
        self.gta.optimize(skip=['isodiff'])

        # Save sources found
        if debug == True:
            self.gta.residmap(prefix='outer', make_plots=True)
            self.gta.write_roi('outerAnalysisROI')
            self.gta.make_plots('outer')

    ''' INNER REGION '''

    def innerRegionAnalysis(self, sizeROI, rInner, maxIter, sqrtTsThreshold,
                            minSeparation, dmMin, TSm1Min, TSextMin, debug):

        self.gta.free_sources(distance=sizeROI, square=True, free=False)
        self.gta.free_sources(distance=rInner, free=True, exclude=['isodiff'])

        # Keep closest source if identified with star forming region in catalog or look for new source closest to center within Rinner
        if self.target != None:
            print('Closest source identified with star forming region : ',
                  self.target['name'])
            self.gta.set_source_morphology('TESTSOURCE',
                                           **{'spatial_model': 'PointSource'})
        else:
            closeSources = self.gta.find_sources(sqrt_ts_threshold=2.,
                                                 min_separation=minSeparation,
                                                 max_iter=1,
                                                 **{
                                                     'search_skydir':
                                                     self.gta.roi.skydir,
                                                     'search_minmax_radius':
                                                     [0., rInner]
                                                 })
            dCenter = np.array([])
            for i in range(len(closeSources['sources'])):
                dCenter = np.append(
                    dCenter,
                    self.gta.roi.skydir.separation(
                        closeSources['sources'][i].skydir).value)
            self.target = closeSources['sources'][np.argmin(dCenter)]
            print('Target name : ', self.target['name'])
            self.setSourceName(self.target, 'TESTSOURCE')
            for i in [
                    x for x in range(len(closeSources['sources']))
                    if x != (np.argmin(dCenter))
            ]:
                self.gta.delete_source(closeSources['sources'][i]['name'])
            self.gta.optimize(skip=['isodiff'])

        # Initialize n sources array
        nSources = []

        # Save ROI without extension fit
        self.gta.write_roi('nSourcesFit')

        if debug == True:
            self.gta.make_plots('innerInit')
            self.gta.residmap(prefix='innerInit', make_plots=True)

        # Test for extension
        extensionTest = self.gta.extension('TESTSOURCE',
                                           make_plots=True,
                                           write_npy=debug,
                                           write_fits=debug,
                                           spatial_model='RadialDisk',
                                           update=True,
                                           free_background=True,
                                           fit_position=True)
        extLike = extensionTest['loglike_ext']
        TSext = extensionTest['ts_ext']
        print('TSext : ', TSext)
        extAIC = 2 * (len(self.gta.get_free_param_vector()) -
                      self.gta._roi_data['loglike'])
        self.gta.write_roi('extFit')

        if debug == True:
            self.gta.residmap(prefix='ext0', make_plots=True)
            self.gta.make_plots('ext0')

        self.gta.load_roi('nSourcesFit', reload_sources=True)

        for i in range(1, maxIter + 1):

            # Test for n point sources
            nSourcesTest = self.gta.find_sources(
                sources_per_iter=1,
                sqrt_ts_threshold=sqrtTsThreshold,
                min_separation=minSeparation,
                max_iter=1,
                **{
                    'search_skydir': self.gta.roi.skydir,
                    'search_minmax_radius': [0., rInner]
                })

            if len(nSourcesTest['sources']) > 0:

                if nSourcesTest['sources'][0]['ts'] > 100.:
                    self.gta.set_source_spectrum(
                        nSourcesTest['sources'][0]['name'],
                        spectrum_type='LogParabola')
                    self.gta.free_source(nSourcesTest['sources'][0]['name'])
                    self.gta.fit()
                    self.gta.free_source(nSourcesTest['sources'][0]['name'],
                                         free=False)

                if debug == True:
                    self.gta.make_plots('nSources' + str(i))

                nSources.append(nSourcesTest['sources'])
                self.gta.localize(nSourcesTest['sources'][0]['name'],
                                  write_npy=debug,
                                  write_fits=debug,
                                  update=True)
                nAIC = 2 * (len(self.gta.get_free_param_vector()) -
                            self.gta._roi_data['loglike'])
                self.gta.free_source(nSourcesTest['sources'][0]['name'],
                                     free=True)
                self.gta.residmap(prefix='nSources' + str(i), make_plots=True)
                self.gta.write_roi('n1SourcesFit')

                # Estimate Akaike Information Criterion difference between both models
                dm = extAIC - nAIC
                print('AIC difference between both models = ', dm)

                # Estimate TS_m+1
                extensionTestPlus = self.gta.extension(
                    'TESTSOURCE',
                    make_plots=True,
                    write_npy=debug,
                    write_fits=debug,
                    spatial_model='RadialDisk',
                    update=True,
                    free_background=True,
                    fit_position=True)
                TSm1 = 2 * (extensionTestPlus['loglike_ext'] - extLike)
                print('TSm+1 = ', TSm1)

                if debug == True:
                    self.gta.residmap(prefix='ext' + str(i), make_plots=True)
                    self.gta.make_plots('ext' + str(i))

                if dm < dmMin and TSm1 < TSm1Min:
                    self.gta.load_roi('extFit', reload_sources=True)
                    break
                else:

                    # Set extension test to current state and save current extension fit ROI and load previous nSources fit ROI
                    extensionTest = extensionTestPlus
                    extLike = extensionTestPlus['loglike_ext']
                    TSext = extensionTestPlus['ts_ext']
                    print('TSext : ', TSext)
                    extAIC = 2 * (len(self.gta.get_free_param_vector()) -
                                  self.gta._roi_data['loglike'])
                    self.gta.write_roi('extFit')
                    self.gta.load_roi('n1SourcesFit', reload_sources=True)
                    self.gta.write_roi('nSourcesFit')

            else:
                if TSext > TSextMin:
                    self.gta.load_roi('extFit', reload_sources=True)
                    break
                else:
                    self.gta.load_roi('nSourcesFit', reload_sources=True)
                    break

        self.gta.fit()

        # Get source radius depending on spatial model
        endSources = self.gta.get_sources()
        for i in range(len(endSources)):
            if endSources[i]['name'] == 'TESTSOURCE':
                self.target = endSources[i]
                self.distance = self.gta.roi.skydir.separation(
                    endSources[i].skydir).value
                if endSources[i].extended == True:
                    self.targetRadius = endSources[i]['SpatialWidth']
                else:
                    self.targetRadius = endSources[i]['pos_r95']

    ''' CHECK OVERLAP '''

    def overlapDisk(self, rInner, radiusCatalog):

        print('Target radius : ', self.targetRadius)

        # Check radius sizes
        if radiusCatalog < self.targetRadius:
            r = float(radiusCatalog)
            R = float(self.targetRadius)
        else:
            r = float(self.targetRadius)
            R = float(radiusCatalog)

        # Estimating overlapping area
        d = self.distance
        print('Distance from center : ', d)

        if d < (r + R):
            if R < (r + d):
                area = r**2 * np.arccos(
                    (d**2 + r**2 - R**2) / (2 * d * r)) + R**2 * np.arccos(
                        (d**2 + R**2 - r**2) / (2 * d * R)) - 0.5 * np.sqrt(
                            (-d + r + R) * (d + r - R) * (d - r + R) *
                            (d + r + R))
                overlap = round((area / (np.pi * r**2)) * 100, 2)
            else:
                area = np.pi * r**2
                overlap = 100.0
        else:
            area = 0.
            overlap = 0.

        print('Overlapping surface : ', area)
        print('Overlap : ', overlap)

        if overlap > 68. and self.distance < rInner:
            associated = True
        else:
            associated = False

        return associated

    ''' CHECK UPPER LIMIT '''

    def upperLimit(self, name, radius):
        sourceModel = {
            'SpectrumType': 'PowerLaw',
            'Index': 2.0,
            'Scale': 30000,
            'Prefactor': 1.e-15,
            'SpatialModel': 'RadialDisk',
            'SpatialWidth': radius,
            'glon': self.gta.config['selection']['glon'],
            'glat': self.gta.config['selection']['glat']
        }
        self.gta.add_source(name, sourceModel, free=True)
        self.gta.fit()
        self.gta.residmap(prefix='upperLimit', make_plots=True)
        print('Upper limit : ', self.gta.get_sources()[0]['flux_ul95'])
예제 #3
0
    gta = GTAnalysis(args.config, logging={"verbosity": 3})

    gta.setup()
    gta.simulate_roi(restore=True)

    ext_fit_data = []
    halo_fit_data = []

    gta.write_roi("base_model", save_model_map=False, make_plots=False)

    for i in range(1):

        gta.load_xml("base_model")

        gta.simulate_roi(randomize=False)

        gta.free_source("testsource")
        gta.update_source("testsource")
        #        gta.fit()
        gta.free_sources(free=False)

        gta.extension("testsource", width=np.logspace(-2.5, -0.5, 9))

        ext_fit_data += [copy.deepcopy(gta.roi["testsource"])]

        gta.write_roi("fit%04i" % i, save_model_map=False, make_plots=False, format="npy")

        fit_halo(gta, "fit%04i" % i, "testsource", halo_width, halo_index)

    np.save(os.path.join(gta._savedir, "ext_fit_data.npy"), ext_fit_data)