def test_aperturephotometry():

	INPUT_DIR = os.path.join(os.path.dirname(__file__), 'input')
	OUTPUT_DIR = tempfile.mkdtemp(prefix='tessphot_tests_aperture')

	for datasource in ('tpf', 'ffi'):
		with AperturePhotometry(182092046, INPUT_DIR, OUTPUT_DIR, plot=True, datasource=datasource, camera=1, ccd=1) as pho:

			pho.photometry()
			pho.save_lightcurve()
			print( pho.lightcurve )

			# It should set the status to one of these:
			assert(pho.status in (STATUS.OK, STATUS.WARNING))

			plt.figure()
			plot_image(pho.sumimage, title=datasource)
			plt.show()

			# They shouldn't be exactly zero:
			assert( ~np.all(pho.lightcurve['flux'] == 0) )
			assert( ~np.all(pho.lightcurve['pos_centroid'][:,0] == 0) )
			assert( ~np.all(pho.lightcurve['pos_centroid'][:,1] == 0) )

			# They shouldn't be NaN (in this case!):
			assert( ~np.all(np.isnan(pho.lightcurve['flux'])) )
			assert( ~np.all(np.isnan(pho.lightcurve['pos_centroid'][:,0])) )
			assert( ~np.all(np.isnan(pho.lightcurve['pos_centroid'][:,1])) )
Exemplo n.º 2
0
def test_aperturephotometry():

    with TemporaryDirectory() as OUTPUT_DIR:
        for datasource in ('tpf', 'ffi'):
            with AperturePhotometry(DUMMY_TARGET,
                                    INPUT_DIR,
                                    OUTPUT_DIR,
                                    plot=True,
                                    datasource=datasource,
                                    **DUMMY_KWARG) as pho:

                pho.photometry()
                pho.save_lightcurve()
                print(pho.lightcurve)

                # It should set the status to one of these:
                assert (pho.status in (STATUS.OK, STATUS.WARNING))

                plt.figure()
                plot_image(pho.sumimage, title=datasource)
                plt.show()

                # They shouldn't be exactly zero:
                assert (~np.all(pho.lightcurve['flux'] == 0))
                assert (~np.all(pho.lightcurve['pos_centroid'][:, 0] == 0))
                assert (~np.all(pho.lightcurve['pos_centroid'][:, 1] == 0))

                # They shouldn't be NaN (in this case!):
                assert (~np.all(np.isnan(pho.lightcurve['flux'])))
                assert (
                    ~np.all(np.isnan(pho.lightcurve['pos_centroid'][:, 0])))
                assert (
                    ~np.all(np.isnan(pho.lightcurve['pos_centroid'][:, 1])))
Exemplo n.º 3
0
		ax.set_yscale('log')
		plt.legend()

		# Plot the new barycentric time correction and the old one:
		fig2 = plt.figure(figsize=(8,10))
		ax3 = fig2.add_subplot(111)
		ax3.axhline(1.0, color='k', ls='--', lw=1)
		ax3.plot(time_nocorr, np.abs(ffi_timecorr - f(time_nocorr))*86400, '.-', label='FFI centre')
		ax3.plot(time_nocorr, np.abs(timecorr_greenwich - f(time_nocorr))*86400*1000, '.-', label='Elenor')
		ax3.plot(time_nocorr, np.abs(timecorr_astropy - f(time_nocorr))*86400*1000, '.-', label='Astropy')
		ax3.plot(time_nocorr, np.abs(timecorr_knl - f(time_nocorr))*86400*1000, '.-', label='Kernel')
		ax3.set_ylabel('abs(TimeCorr - TPF TimeCorr) [ms]')
		ax3.set_xlabel('Uncorrected Time [TJD]')
		ax3.set_yscale('log')
		ax3.set_ylim(bottom=0.1)
		ax3.legend()
		ax3.grid(axis='y', which='both', color='0.7', ls=':', lw=0.5)
		ax3.set_title('TIC %d' % starid)
		plt.tight_layout()

		assert np.all(86400000*np.abs(timecorr_astropy - f(time_nocorr)) < 1), "AstroPy method: More than 1 ms away"
		assert np.all(86400000*np.abs(timecorr_knl - f(time_nocorr)) < 1), "HomeMade method: More than 1 ms away"

	print("="*72)

#--------------------------------------------------------------------------------------------------
if __name__ == '__main__':
	plt.switch_backend('Qt5Agg')
	pytest.main([__file__])
	plt.show()
Exemplo n.º 4
0
                   label='Elenor',
                   alpha=0.5)
        ax.scatter(time_nocorr,
                   86400 * (time_astropy - f2(time_nocorr)),
                   marker='.',
                   c='r',
                   label='Ours',
                   alpha=0.5)

        tab = Table([
            time_nocorr,
            f2(time_nocorr), ffi_time, time_greenwich, time_astropy
        ],
                    names=[
                        'time_nocorr', 'time_spoc', 'time_fficentre',
                        'time_greenwich', 'time_ours'
                    ])
        print(tab)
        tab.write('time_TIC%d.ecsv' % starid,
                  format='ascii.ecsv',
                  delimiter=',')

    ax.set_xlabel('Uncorrected Time [TJD]')
    ax.set_ylabel('Time - SPOC time [s]')
    #ax.set_title('TIC %d' % starid)
    #ax.set_yscale('log')
    plt.legend()

    print("=" * 72)
    plt.show(block=True)