def setUp(self): self.calib = IsrProvenance(detectorName='test_calibType Det00', detectorSerial='Det00', calibType="Test Calib") self.calib.updateMetadata() self.calib.fromDataIds([{'exposure': 1234, 'detector': 0, 'filter': 'G'}, {'exposure': 1235, 'detector': 0, 'filter': 'G'}, {'exposure': 1234, 'detector': 1, 'filter': 'G'}, {'exposure': 1235, 'detector': 1, 'filter': 'G'}])
def test_Fits(self): filename = tempfile.mktemp() usedFilename = self.calib.writeFits(filename + '.fits') fromFits = IsrProvenance.readFits(usedFilename) self.assertEqual(self.calib, fromFits) fromFits.updateMetadata(setDate=True) self.assertNotEqual(self.calib, fromFits)
def runText(self, textType): filename = tempfile.mktemp() usedFilename = self.calib.writeText(filename + textType) fromText = IsrProvenance.readText(usedFilename) self.assertEqual(self.calib, fromText) # Test generic interface: fromGeneric = IsrCalib.readText(usedFilename) self.assertEqual(self.calib, fromGeneric)
class IsrCalibCases(lsst.utils.tests.TestCase): """Test unified calibration type. """ def setUp(self): self.calib = IsrProvenance(detectorName='test_calibType Det00', detectorSerial='Det00', calibType="Test Calib") self.calib.updateMetadata() self.calib.fromDataIds([{'exposure': 1234, 'detector': 0, 'filter': 'G'}, {'exposure': 1235, 'detector': 0, 'filter': 'G'}, {'exposure': 1234, 'detector': 1, 'filter': 'G'}, {'exposure': 1235, 'detector': 1, 'filter': 'G'}]) def runText(self, textType): filename = tempfile.mktemp() usedFilename = self.calib.writeText(filename + textType) fromText = IsrProvenance.readText(usedFilename) self.assertEqual(self.calib, fromText) def test_Text(self): self.runText('.yaml') self.runText('.ecsv') def test_Fits(self): filename = tempfile.mktemp() usedFilename = self.calib.writeFits(filename + '.fits') fromFits = IsrProvenance.readFits(usedFilename) self.assertEqual(self.calib, fromFits) fromFits.updateMetadata(setDate=True) self.assertNotEqual(self.calib, fromFits)
def run(self, inputRatios, inputFluxes=None, camera=None, inputDims=None, outputDims=None): """Combine ratios to produce crosstalk coefficients. Parameters ---------- inputRatios : `list` [`dict` [`dict` [`dict` [`dict` [`list`]]]]] A list of nested dictionaries of ratios indexed by target and source chip, then by target and source amplifier. inputFluxes : `list` [`dict` [`dict` [`list`]]] A list of nested dictionaries of source pixel fluxes, indexed by source chip and amplifier. camera : `lsst.afw.cameraGeom.Camera` Input camera. inputDims : `list` [`lsst.daf.butler.DataCoordinate`] DataIds to use to construct provenance. outputDims : `list` [`lsst.daf.butler.DataCoordinate`] DataIds to use to populate the output calibration. Returns ------- results : `lsst.pipe.base.Struct` The results struct containing: ``outputCrosstalk`` : `lsst.ip.isr.CrosstalkCalib` Final crosstalk calibration. ``outputProvenance`` : `lsst.ip.isr.IsrProvenance` Provenance data for the new calibration. Raises ------ RuntimeError Raised if the input data contains multiple target detectors. Notes ----- The lsstDebug.Info() method can be rewritten for __name__ = `lsst.ip.isr.measureCrosstalk`, and supports the parameters: debug.display['reduce'] : `bool` Display a histogram of the combined ratio measurements for a pair of source/target amplifiers from all input exposures/detectors. """ if outputDims: calibChip = outputDims['detector'] instrument = outputDims['instrument'] else: # calibChip needs to be set manually in Gen2. calibChip = None instrument = None self.log.info("Combining measurements from %d ratios and %d fluxes", len(inputRatios), len(inputFluxes) if inputFluxes else 0) if inputFluxes is None: inputFluxes = [None for exp in inputRatios] combinedRatios = defaultdict(lambda: defaultdict(list)) combinedFluxes = defaultdict(lambda: defaultdict(list)) for ratioDict, fluxDict in zip(inputRatios, inputFluxes): for targetChip in ratioDict: if calibChip and targetChip != calibChip: raise RuntimeError("Received multiple target chips!") sourceChip = targetChip if sourceChip in ratioDict[targetChip]: ratios = ratioDict[targetChip][sourceChip] for targetAmp in ratios: for sourceAmp in ratios[targetAmp]: combinedRatios[targetAmp][sourceAmp].extend(ratios[targetAmp][sourceAmp]) if fluxDict: combinedFluxes[targetAmp][sourceAmp].extend(fluxDict[sourceChip][sourceAmp]) # TODO: DM-21904 # Iterating over all other entries in ratioDict[targetChip] will yield # inter-chip terms. for targetAmp in combinedRatios: for sourceAmp in combinedRatios[targetAmp]: self.log.info("Read %d pixels for %s -> %s", len(combinedRatios[targetAmp][sourceAmp]), targetAmp, sourceAmp) if len(combinedRatios[targetAmp][sourceAmp]) > 1: self.debugRatios('reduce', combinedRatios, targetAmp, sourceAmp) if self.config.fluxOrder == 0: self.log.info("Fitting crosstalk coefficients.") calib = self.measureCrosstalkCoefficients(combinedRatios, self.config.rejIter, self.config.rejSigma) else: raise NotImplementedError("Non-linear crosstalk terms are not yet supported.") self.log.info("Number of valid coefficients: %d", np.sum(calib.coeffValid)) if self.config.doFiltering: # This step will apply the calculated validity values to # censor poorly measured coefficients. self.log.info("Filtering measured crosstalk to remove invalid solutions.") calib = self.filterCrosstalkCalib(calib) # Populate the remainder of the calibration information. calib.hasCrosstalk = True calib.interChip = {} # calibChip is the detector dimension, which is the detector Id calib._detectorId = calibChip if camera: calib._detectorName = camera[calibChip].getName() calib._detectorSerial = camera[calibChip].getSerial() calib._instrument = instrument calib.updateMetadata(setCalibId=True, setDate=True) # Make an IsrProvenance(). provenance = IsrProvenance(calibType="CROSSTALK") provenance._detectorName = calibChip if inputDims: provenance.fromDataIds(inputDims) provenance._instrument = instrument provenance.updateMetadata() return pipeBase.Struct( outputCrosstalk=calib, outputProvenance=provenance, )
def runText(self, textType): filename = tempfile.mktemp() usedFilename = self.calib.writeText(filename + textType) fromText = IsrProvenance.readText(usedFilename) self.assertEqual(self.calib, fromText)
def run(self, inputPtc, camera, inputDims): """Fit non-linearity to PTC data, returning the correct Linearizer object. Parameters ---------- inputPtc : `lsst.cp.pipe.PtcDataset` Pre-measured PTC dataset. camera : `lsst.afw.cameraGeom.Camera` Camera geometry. inputDims : `lsst.daf.butler.DataCoordinate` or `dict` DataIds to use to populate the output calibration. Returns ------- results : `lsst.pipe.base.Struct` The results struct containing: ``outputLinearizer`` : `lsst.ip.isr.Linearizer` Final linearizer calibration. ``outputProvenance`` : `lsst.ip.isr.IsrProvenance` Provenance data for the new calibration. Notes ----- This task currently fits only polynomial-defined corrections, where the correction coefficients are defined such that: corrImage = uncorrImage + sum_i c_i uncorrImage^(2 + i) These `c_i` are defined in terms of the direct polynomial fit: meanVector ~ P(x=timeVector) = sum_j k_j x^j such that c_(j-2) = -k_j/(k_1^j) in units of DN^(1-j) (c.f., Eq. 37 of 2003.05978). The `config.polynomialOrder` or `config.splineKnots` define the maximum order of x^j to fit. As k_0 and k_1 are degenerate with bias level and gain, they are not included in the non-linearity correction. """ detector = camera[inputDims['detector']] if self.config.linearityType == 'LookupTable': table = np.zeros((len(detector), self.config.maxLookupTableAdu), dtype=np.float32) tableIndex = 0 else: table = None tableIndex = None # This will fail if we increment it. if self.config.linearityType == 'Spline': fitOrder = self.config.splineKnots else: fitOrder = self.config.polynomialOrder # Initialize the linearizer. linearizer = Linearizer(detector=detector, table=table, log=self.log) for i, amp in enumerate(detector): ampName = amp.getName() if (len(inputPtc.expIdMask[ampName]) == 0): self.log.warn( f"Mask not found for {ampName} in non-linearity fit. Using all points." ) mask = np.repeat(True, len(inputPtc.expIdMask[ampName])) else: mask = inputPtc.expIdMask[ampName] inputAbscissa = np.array(inputPtc.rawExpTimes[ampName])[mask] inputOrdinate = np.array(inputPtc.rawMeans[ampName])[mask] # Determine proxy-to-linear-flux transformation fluxMask = inputOrdinate < self.config.maxLinearAdu lowMask = inputOrdinate > self.config.minLinearAdu fluxMask = fluxMask & lowMask linearAbscissa = inputAbscissa[fluxMask] linearOrdinate = inputOrdinate[fluxMask] linearFit, linearFitErr, chiSq, weights = irlsFit([0.0, 100.0], linearAbscissa, linearOrdinate, funcPolynomial) # Convert this proxy-to-flux fit into an expected linear flux linearOrdinate = linearFit[0] + linearFit[1] * inputAbscissa # Exclude low end outliers threshold = self.config.nSigmaClipLinear * np.sqrt(linearOrdinate) fluxMask = np.abs(inputOrdinate - linearOrdinate) < threshold linearOrdinate = linearOrdinate[fluxMask] fitOrdinate = inputOrdinate[fluxMask] self.debugFit('linearFit', inputAbscissa, inputOrdinate, linearOrdinate, fluxMask, ampName) # Do fits if self.config.linearityType in [ 'Polynomial', 'Squared', 'LookupTable' ]: polyFit = np.zeros(fitOrder + 1) polyFit[1] = 1.0 polyFit, polyFitErr, chiSq, weights = irlsFit( polyFit, linearOrdinate, fitOrdinate, funcPolynomial) # Truncate the polynomial fit k1 = polyFit[1] linearityFit = [ -coeff / (k1**order) for order, coeff in enumerate(polyFit) ] significant = np.where( np.abs(linearityFit) > 1e-10, True, False) self.log.info(f"Significant polynomial fits: {significant}") modelOrdinate = funcPolynomial(polyFit, linearAbscissa) self.debugFit('polyFit', linearAbscissa, fitOrdinate, modelOrdinate, None, ampName) if self.config.linearityType == 'Squared': linearityFit = [linearityFit[2]] elif self.config.linearityType == 'LookupTable': # Use linear part to get time at wich signal is maxAduForLookupTableLinearizer DN tMax = (self.config.maxLookupTableAdu - polyFit[0]) / polyFit[1] timeRange = np.linspace(0, tMax, self.config.maxLookupTableAdu) signalIdeal = polyFit[0] + polyFit[1] * timeRange signalUncorrected = funcPolynomial(polyFit, timeRange) lookupTableRow = signalIdeal - signalUncorrected # LinearizerLookupTable has correction linearizer.tableData[tableIndex, :] = lookupTableRow linearityFit = [tableIndex, 0] tableIndex += 1 elif self.config.linearityType in ['Spline']: # See discussion in `lsst.ip.isr.linearize.py` before modifying. numPerBin, binEdges = np.histogram(linearOrdinate, bins=fitOrder) with np.errstate(invalid="ignore"): # Algorithm note: With the counts of points per # bin above, the next histogram calculates the # values to put in each bin by weighting each # point by the correction value. values = np.histogram( linearOrdinate, bins=fitOrder, weights=(inputOrdinate[fluxMask] - linearOrdinate))[0] / numPerBin # After this is done, the binCenters are # calculated by weighting by the value we're # binning over. This ensures that widely # spaced/poorly sampled data aren't assigned to # the midpoint of the bin (as could be done using # the binEdges above), but to the weighted mean of # the inputs. Note that both histograms are # scaled by the count per bin to normalize what # the histogram returns (a sum of the points # inside) into an average. binCenters = np.histogram( linearOrdinate, bins=fitOrder, weights=linearOrdinate)[0] / numPerBin values = values[numPerBin > 0] binCenters = binCenters[numPerBin > 0] self.debugFit('splineFit', binCenters, np.abs(values), values, None, ampName) interp = afwMath.makeInterpolate( binCenters.tolist(), values.tolist(), afwMath.stringToInterpStyle("AKIMA_SPLINE")) modelOrdinate = linearOrdinate + interp.interpolate( linearOrdinate) self.debugFit('splineFit', linearOrdinate, fitOrdinate, modelOrdinate, None, ampName) # If we exclude a lot of points, we may end up with # less than fitOrder points. Pad out the low-flux end # to ensure equal lengths. if len(binCenters) != fitOrder: padN = fitOrder - len(binCenters) binCenters = np.pad(binCenters, (padN, 0), 'linear_ramp', end_values=(binCenters.min() - 1.0, )) # This stores the correction, which is zero at low values. values = np.pad(values, (padN, 0)) # Pack the spline into a single array. linearityFit = np.concatenate( (binCenters.tolist(), values.tolist())).tolist() polyFit = [0.0] polyFitErr = [0.0] chiSq = np.nan else: polyFit = [0.0] polyFitErr = [0.0] chiSq = np.nan linearityFit = [0.0] linearizer.linearityType[ampName] = self.config.linearityType linearizer.linearityCoeffs[ampName] = np.array(linearityFit) linearizer.linearityBBox[ampName] = amp.getBBox() linearizer.fitParams[ampName] = np.array(polyFit) linearizer.fitParamsErr[ampName] = np.array(polyFitErr) linearizer.fitChiSq[ampName] = chiSq image = afwImage.ImageF(len(inputOrdinate), 1) image.getArray()[:, :] = inputOrdinate linearizeFunction = linearizer.getLinearityTypeByName( linearizer.linearityType[ampName]) linearizeFunction()(image, **{ 'coeffs': linearizer.linearityCoeffs[ampName], 'table': linearizer.tableData, 'log': linearizer.log }) linearizeModel = image.getArray()[0, :] self.debugFit('solution', inputOrdinate[fluxMask], linearOrdinate, linearizeModel[fluxMask], None, ampName) linearizer.hasLinearity = True linearizer.validate() linearizer.updateMetadata(camera=camera, detector=detector, filterName='NONE') linearizer.updateMetadata(setDate=True, setCalibId=True) provenance = IsrProvenance(calibType='linearizer') return pipeBase.Struct( outputLinearizer=linearizer, outputProvenance=provenance, )