def testNoSystematicUncertainty(self): """ Test that systematic uncertainty is handled correctly when set to None. """ m5 = [23.5, 24.3, 22.1, 20.0, 19.5, 21.7] photParams = PhotometricParameters(sigmaSys=0.0) obs_metadata = ObservationMetaData( unrefractedRA=23.0, unrefractedDec=45.0, m5=m5, bandpassName=self.filterNameList ) magnitudes = [] for bp in self.bpList: mag = self.starSED.calcMag(bp) magnitudes.append(mag) skySedList = [] for bp, hardware, filterName in zip(self.bpList, self.hardwareList, self.filterNameList): skyDummy = Sed() skyDummy.readSED_flambda(os.path.join(lsst.utils.getPackageDir("throughputs"), "baseline", "darksky.dat")) normalizedSkyDummy = setM5( obs_metadata.m5[filterName], skyDummy, bp, hardware, seeing=LSSTdefaults().seeing(filterName), photParams=photParams, ) skySedList.append(normalizedSkyDummy) sigmaList = snr.calcMagError_m5(numpy.array(magnitudes), numpy.array(self.bpList), numpy.array(m5), photParams) for i in range(len(self.bpList)): snrat = snr.calcSNR_sed( self.starSED, self.bpList[i], skySedList[i], self.hardwareList[i], seeing=LSSTdefaults().seeing(self.filterNameList[i]), photParams=PhotometricParameters(), ) testSNR, gamma = snr.calcSNR_m5( numpy.array([magnitudes[i]]), [self.bpList[i]], numpy.array([m5[i]]), photParams=PhotometricParameters(sigmaSys=0.0), ) self.assertAlmostEqual( snrat, testSNR[0], 10, msg="failed on calcSNR_m5 test %e != %e " % (snrat, testSNR[0]) ) control = snr.magErrorFromSNR(testSNR) msg = "%e is not %e; failed" % (sigmaList[i], control) self.assertAlmostEqual(sigmaList[i], control, 10, msg=msg)
def testSystematicUncertainty(self): """ Test that systematic uncertainty is added correctly. """ sigmaSys = 0.002 m5_list = [23.5, 24.3, 22.1, 20.0, 19.5, 21.7] photParams = PhotometricParameters(sigmaSys=sigmaSys) obs_metadata = ObservationMetaData(pointingRA=23.0, pointingDec=45.0, m5=m5_list, bandpassName=self.filterNameList) magnitude_list = [] for bp in self.bpList: mag = self.starSED.calcMag(bp) magnitude_list.append(mag) for bp, hardware, filterName, mm, m5 in \ zip(self.bpList, self.hardwareList, self.filterNameList, magnitude_list, m5_list): skyDummy = Sed() skyDummy.readSED_flambda( os.path.join(lsst.utils.getPackageDir('throughputs'), 'baseline', 'darksky.dat')) normalizedSkyDummy = setM5( obs_metadata.m5[filterName], skyDummy, bp, hardware, FWHMeff=LSSTdefaults().FWHMeff(filterName), photParams=photParams) sigma, gamma = snr.calcMagError_m5(mm, bp, m5, photParams) snrat = snr.calcSNR_sed(self.starSED, bp, normalizedSkyDummy, hardware, FWHMeff=LSSTdefaults().FWHMeff(filterName), photParams=PhotometricParameters()) testSNR, gamma = snr.calcSNR_m5( mm, bp, m5, photParams=PhotometricParameters(sigmaSys=0.0)) self.assertAlmostEqual(snrat, testSNR, 10, msg='failed on calcSNR_m5 test %e != %e ' % (snrat, testSNR)) control = np.sqrt( np.power(snr.magErrorFromSNR(testSNR), 2) + np.power(sigmaSys, 2)) msg = '%e is not %e; failed' % (sigma, control) self.assertAlmostEqual(sigma, control, 10, msg=msg)
def testNoSystematicUncertainty(self): """ Test that systematic uncertainty is handled correctly when set to None. """ m5 = [23.5, 24.3, 22.1, 20.0, 19.5, 21.7] photParams= PhotometricParameters(sigmaSys=0.0) obs_metadata = ObservationMetaData(unrefractedRA=23.0, unrefractedDec=45.0, m5=m5, bandpassName=self.filterNameList) magnitudes = [] for bp in self.bpList: mag = self.starSED.calcMag(bp) magnitudes.append(mag) skySedList = [] for bp, hardware, filterName in zip(self.bpList, self.hardwareList, self.filterNameList): skyDummy = Sed() skyDummy.readSED_flambda(os.path.join(lsst.utils.getPackageDir('throughputs'), 'baseline', 'darksky.dat')) normalizedSkyDummy = setM5(obs_metadata.m5[filterName], skyDummy, bp, hardware, seeing=LSSTdefaults().seeing(filterName), photParams=photParams) skySedList.append(normalizedSkyDummy) sigmaList = snr.calcMagError_m5(numpy.array(magnitudes), numpy.array(self.bpList), \ numpy.array(m5), photParams) for i in range(len(self.bpList)): snrat = snr.calcSNR_sed(self.starSED, self.bpList[i], skySedList[i], self.hardwareList[i], seeing=LSSTdefaults().seeing(self.filterNameList[i]), photParams=PhotometricParameters()) testSNR, gamma = snr.calcSNR_m5(numpy.array([magnitudes[i]]), [self.bpList[i]], numpy.array([m5[i]]), photParams=PhotometricParameters(sigmaSys=0.0)) self.assertAlmostEqual(snrat, testSNR[0], 10, msg = 'failed on calcSNR_m5 test %e != %e ' \ % (snrat, testSNR[0])) control = snr.magErrorFromSNR(testSNR) msg = '%e is not %e; failed' % (sigmaList[i], control) self.assertAlmostEqual(sigmaList[i], control, 10, msg=msg)
def testNoSystematicUncertainty(self): """ Test that systematic uncertainty is handled correctly when set to None. """ m5_list = [23.5, 24.3, 22.1, 20.0, 19.5, 21.7] photParams= PhotometricParameters(sigmaSys=0.0) obs_metadata = ObservationMetaData(pointingRA=23.0, pointingDec=45.0, m5=m5_list, bandpassName=self.filterNameList) magnitude_list = [] for bp in self.bpList: mag = self.starSED.calcMag(bp) magnitude_list.append(mag) skySedList = [] for bp, hardware, filterName, mm, m5 in \ zip(self.bpList, self.hardwareList, self.filterNameList, magnitude_list, m5_list): skyDummy = Sed() skyDummy.readSED_flambda(os.path.join(lsst.utils.getPackageDir('throughputs'), 'baseline', 'darksky.dat')) normalizedSkyDummy = setM5(obs_metadata.m5[filterName], skyDummy, bp, hardware, FWHMeff=LSSTdefaults().FWHMeff(filterName), photParams=photParams) sigma, gamma = snr.calcMagError_m5(mm, bp, m5, photParams) snrat = snr.calcSNR_sed(self.starSED, bp, normalizedSkyDummy, hardware, FWHMeff=LSSTdefaults().FWHMeff(filterName), photParams=PhotometricParameters()) testSNR, gamma = snr.calcSNR_m5(mm, bp, m5, photParams=PhotometricParameters(sigmaSys=0.0)) self.assertAlmostEqual(snrat, testSNR, 10, msg = 'failed on calcSNR_m5 test %e != %e ' \ % (snrat, testSNR)) control = snr.magErrorFromSNR(testSNR) msg = '%e is not %e; failed' % (sigma, control) self.assertAlmostEqual(sigma, control, 10, msg=msg)