LSSTApplications  18.0.0+106,18.0.0+50,19.0.0,19.0.0+1,19.0.0+10,19.0.0+11,19.0.0+13,19.0.0+17,19.0.0+2,19.0.0-1-g20d9b18+6,19.0.0-1-g425ff20,19.0.0-1-g5549ca4,19.0.0-1-g580fafe+6,19.0.0-1-g6fe20d0+1,19.0.0-1-g7011481+9,19.0.0-1-g8c57eb9+6,19.0.0-1-gb5175dc+11,19.0.0-1-gdc0e4a7+9,19.0.0-1-ge272bc4+6,19.0.0-1-ge3aa853,19.0.0-10-g448f008b,19.0.0-12-g6990b2c,19.0.0-2-g0d9f9cd+11,19.0.0-2-g3d9e4fb2+11,19.0.0-2-g5037de4,19.0.0-2-gb96a1c4+3,19.0.0-2-gd955cfd+15,19.0.0-3-g2d13df8,19.0.0-3-g6f3c7dc,19.0.0-4-g725f80e+11,19.0.0-4-ga671dab3b+1,19.0.0-4-gad373c5+3,19.0.0-5-ga2acb9c+2,19.0.0-5-gfe96e6c+2,w.2020.01
LSSTDataManagementBasePackage
measureCrosstalk.py
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1 #
2 # LSST Data Management System
3 # Copyright 2008-2017 AURA/LSST.
4 #
5 # This product includes software developed by the
6 # LSST Project (http://www.lsst.org/).
7 #
8 # This program is free software: you can redistribute it and/or modify
9 # it under the terms of the GNU General Public License as published by
10 # the Free Software Foundation, either version 3 of the License, or
11 # (at your option) any later version.
12 #
13 # This program is distributed in the hope that it will be useful,
14 # but WITHOUT ANY WARRANTY; without even the implied warranty of
15 # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 # GNU General Public License for more details.
17 #
18 # You should have received a copy of the LSST License Statement and
19 # the GNU General Public License along with this program. If not,
20 # see <https://www.lsstcorp.org/LegalNotices/>.
21 #
22 """
23 Measure intra-detector crosstalk coefficients.
24 """
25 
26 __all__ = ["MeasureCrosstalkConfig", "MeasureCrosstalkTask"]
27 
28 
29 import itertools
30 import numpy as np
31 
32 from lsstDebug import getDebugFrame
33 from lsst.afw.detection import FootprintSet, Threshold
34 from lsst.afw.display import getDisplay
35 from lsst.daf.persistence.butlerExceptions import NoResults
36 from lsst.pex.config import Config, Field, ListField, ConfigurableField
37 from lsst.pipe.base import CmdLineTask, Struct
38 
39 from .crosstalk import calculateBackground, extractAmp, writeCrosstalkCoeffs
40 from .isrTask import IsrTask
41 
42 
43 class MeasureCrosstalkConfig(Config):
44  """Configuration for MeasureCrosstalkTask."""
45  isr = ConfigurableField(
46  target=IsrTask,
47  doc="Instrument signature removal task to use to process data."
48  )
49  threshold = Field(
50  dtype=float,
51  default=30000,
52  doc="Minimum level of source pixels for which to measure crosstalk."
53  )
54  doRerunIsr = Field(
55  dtype=bool,
56  default=True,
57  doc="Rerun the ISR, even if postISRCCD files are available?"
58  )
59  badMask = ListField(
60  dtype=str,
61  default=["SAT", "BAD", "INTRP"],
62  doc="Mask planes to ignore when identifying source pixels."
63  )
64  rejIter = Field(
65  dtype=int,
66  default=3,
67  doc="Number of rejection iterations for final coefficient calculation."
68  )
69  rejSigma = Field(
70  dtype=float,
71  default=2.0,
72  doc="Rejection threshold (sigma) for final coefficient calculation."
73  )
74  isTrimmed = Field(
75  dtype=bool,
76  default=True,
77  doc="Have the amplifiers been trimmed before measuring CT?"
78  )
79 
80  def setDefaults(self):
81  Config.setDefaults(self)
82  # Set ISR processing to run up until we would be applying the CT
83  # correction. Applying subsequent stages may corrupt the signal.
84  self.isr.doWrite = False
85  self.isr.doOverscan = True
86  self.isr.doAssembleCcd = True
87  self.isr.doBias = True
88  self.isr.doVariance = False # This isn't used in the calculation below.
89  self.isr.doLinearize = True # This is the last ISR step we need.
90  self.isr.doCrosstalk = False
91  self.isr.doBrighterFatter = False
92  self.isr.doDark = False
93  self.isr.doStrayLight = False
94  self.isr.doFlat = False
95  self.isr.doFringe = False
96  self.isr.doApplyGains = False
97  self.isr.doDefect = True # Masking helps remove spurious pixels.
98  self.isr.doSaturationInterpolation = False
99  self.isr.growSaturationFootprintSize = 0 # We want the saturation spillover: it's good signal.
100 
101 
103  """Measure intra-detector crosstalk.
104 
105  Notes
106  -----
107  The crosstalk this method measures assumes that when a bright
108  pixel is found in one detector amplifier, all other detector
109  amplifiers may see an increase in the same pixel location
110  (relative to the readout amplifier) as these other pixels are read
111  out at the same time.
112 
113  After processing each input exposure through a limited set of ISR
114  stages, bright unmasked pixels above the threshold are identified.
115  The potential CT signal is found by taking the ratio of the
116  appropriate background-subtracted pixel value on the other
117  amplifiers to the input value on the source amplifier. If the
118  source amplifier has a large number of bright pixels as well, the
119  background level may be elevated, leading to poor ratio
120  measurements.
121 
122  The set of ratios found between each pair of amplifiers across all
123  input exposures is then gathered to produce the final CT
124  coefficients. The sigma-clipped mean and sigma are returned from
125  these sets of ratios, with the coefficient to supply to the ISR
126  CrosstalkTask() being the multiplicative inverse of these values.
127  """
128  ConfigClass = MeasureCrosstalkConfig
129  _DefaultName = "measureCrosstalk"
130 
131  def __init__(self, *args, **kwargs):
132  CmdLineTask.__init__(self, *args, **kwargs)
133  self.makeSubtask("isr")
134 
135  @classmethod
136  def _makeArgumentParser(cls):
137  parser = super(MeasureCrosstalkTask, cls)._makeArgumentParser()
138  parser.add_argument("--crosstalkName",
139  help="Name for this set of crosstalk coefficients", default="Unknown")
140  parser.add_argument("--outputFileName",
141  help="Name of yaml file to which to write crosstalk coefficients")
142  parser.add_argument("--dump-ratios", dest="dumpRatios",
143  help="Name of pickle file to which to write crosstalk ratios")
144  return parser
145 
146  @classmethod
147  def parseAndRun(cls, *args, **kwargs):
148  """Implement scatter/gather
149 
150  Returns
151  -------
152  coeff : `numpy.ndarray`
153  Crosstalk coefficients.
154  coeffErr : `numpy.ndarray`
155  Crosstalk coefficient errors.
156  coeffNum : `numpy.ndarray`
157  Number of pixels used for crosstalk measurement.
158  """
159  kwargs["doReturnResults"] = True
160  results = super(MeasureCrosstalkTask, cls).parseAndRun(*args, **kwargs)
161  task = cls(config=results.parsedCmd.config, log=results.parsedCmd.log)
162  resultList = [rr.result for rr in results.resultList]
163  if results.parsedCmd.dumpRatios:
164  import pickle
165  pickle.dump(resultList, open(results.parsedCmd.dumpRatios, "wb"))
166  coeff, coeffErr, coeffNum = task.reduce(resultList)
167 
168  outputFileName = results.parsedCmd.outputFileName
169  if outputFileName is not None:
170  butler = results.parsedCmd.butler
171  dataId = results.parsedCmd.id.idList[0]
172  dataId["detector"] = butler.queryMetadata("raw", ["detector"], dataId)[0]
173 
174  det = butler.get('raw', dataId).getDetector()
175  writeCrosstalkCoeffs(outputFileName, coeff, det=det,
176  crosstalkName=results.parsedCmd.crosstalkName, indent=2)
177 
178  return Struct(
179  coeff=coeff,
180  coeffErr=coeffErr,
181  coeffNum=coeffNum
182  )
183 
184  def _getConfigName(self):
185  """Disable config output."""
186  return None
187 
188  def _getMetadataName(self):
189  """Disable metdata output."""
190  return None
191 
192  def runDataRef(self, dataRef):
193  """Get crosstalk ratios for detector.
194 
195  Parameters
196  ----------
197  dataRef : `lsst.daf.peristence.ButlerDataRef`
198  Data references for detectors to process.
199 
200  Returns
201  -------
202  ratios : `list` of `list` of `numpy.ndarray`
203  A matrix of pixel arrays.
204  """
205  exposure = None
206  if not self.config.doRerunIsr:
207  try:
208  exposure = dataRef.get("postISRCCD")
209  except NoResults:
210  pass
211 
212  if exposure is None:
213  exposure = self.isr.runDataRef(dataRef).exposure
214 
215  dataId = dataRef.dataId
216  return self.run(exposure, dataId=dataId)
217 
218  def run(self, exposure, dataId=None):
219  """Extract and return cross talk ratios for an exposure.
220 
221  Parameters
222  ----------
223  exposure : `lsst.afw.image.Exposure`
224  Image data to measure crosstalk ratios from.
225  dataId :
226  Optional data ID for the exposure to process; used for logging.
227 
228  Returns
229  -------
230  ratios : `list` of `list` of `numpy.ndarray`
231  A matrix of pixel arrays.
232  """
233  ratios = self.extractCrosstalkRatios(exposure)
234  self.log.info("Extracted %d pixels from %s",
235  sum(len(jj) for ii in ratios for jj in ii if jj is not None), dataId)
236  return ratios
237 
238  def extractCrosstalkRatios(self, exposure, threshold=None, badPixels=None):
239  """Extract crosstalk ratios between different amplifiers.
240 
241  For pixels above ``threshold``, we calculate the ratio between
242  each background-subtracted target amp and the source amp. We
243  return a list of ratios for each pixel for each target/source
244  combination, as a matrix of lists.
245 
246  Parameters
247  ----------
248  exposure : `lsst.afw.image.Exposure`
249  Exposure for which to measure crosstalk.
250  threshold : `float`, optional
251  Lower limit on pixels for which we measure crosstalk.
252  badPixels : `list` of `str`, optional
253  Mask planes indicating a pixel is bad.
254 
255  Returns
256  -------
257  ratios : `list` of `list` of `numpy.ndarray`
258  A matrix of pixel arrays. ``ratios[i][j]`` is an array of
259  the fraction of the ``j``-th amp present on the ``i``-th amp.
260  The value is `None` for the diagonal elements.
261 
262  Notes
263  -----
264  This has been moved into MeasureCrosstalkTask to allow for easier
265  debugging.
266 
267  The lsstDebug.Info() method can be rewritten for __name__ =
268  `lsst.ip.isr.measureCrosstalk`, and supports the parameters:
269 
270  debug.display['extract'] : `bool`
271  Display the exposure under consideration, with the pixels used
272  for crosstalk measurement indicated by the DETECTED mask plane.
273  debug.display['pixels'] : `bool`
274  Display a plot of the ratio calculated for each pixel used in this
275  exposure, split by amplifier pairs. The median value is listed
276  for reference.
277  """
278  if threshold is None:
279  threshold = self.config.threshold
280  if badPixels is None:
281  badPixels = list(self.config.badMask)
282 
283  mi = exposure.getMaskedImage()
284  FootprintSet(mi, Threshold(threshold), "DETECTED")
285  detected = mi.getMask().getPlaneBitMask("DETECTED")
286  bad = mi.getMask().getPlaneBitMask(badPixels)
287  bg = calculateBackground(mi, badPixels + ["DETECTED"])
288 
289  self.debugView('extract', exposure)
290 
291  ccd = exposure.getDetector()
292  ratios = [[None for iAmp in ccd] for jAmp in ccd]
293 
294  for ii, iAmp in enumerate(ccd):
295  iImage = mi[iAmp.getBBox()]
296  iMask = iImage.mask.array
297  select = (iMask & detected > 0) & (iMask & bad == 0) & np.isfinite(iImage.image.array)
298  for jj, jAmp in enumerate(ccd):
299  if ii == jj:
300  continue
301  jImage = extractAmp(mi.image, jAmp, iAmp.getReadoutCorner(), isTrimmed=self.config.isTrimmed)
302  ratios[jj][ii] = (jImage.array[select] - bg)/iImage.image.array[select]
303  self.debugPixels('pixels', iImage.image.array[select], jImage.array[select] - bg, ii, jj)
304  return ratios
305 
306  def reduce(self, ratioList):
307  """Combine ratios to produce crosstalk coefficients.
308 
309  Parameters
310  ----------
311  ratioList : `list` of `list` of `list` of `numpy.ndarray`
312  A list of matrices of arrays; a list of results from
313  `extractCrosstalkRatios`.
314 
315  Returns
316  -------
317  coeff : `numpy.ndarray`
318  Crosstalk coefficients.
319  coeffErr : `numpy.ndarray`
320  Crosstalk coefficient errors.
321  coeffNum : `numpy.ndarray`
322  Number of pixels used for crosstalk measurement.
323 
324  Raises
325  ------
326  RuntimeError
327  Raised if there is no crosstalk data available.
328 
329  Notes
330  -----
331  The lsstDebug.Info() method can be rewritten for __name__ =
332  `lsst.ip.isr.measureCrosstalk`, and supports the parameters:
333 
334  debug.display['reduce'] : `bool`
335  Display a histogram of the combined ratio measurements for
336  a pair of source/target amplifiers from all input
337  exposures/detectors.
338  """
339  numAmps = None
340  for rr in ratioList:
341  if rr is None:
342  continue
343 
344  if numAmps is None:
345  numAmps = len(rr)
346 
347  assert len(rr) == numAmps
348  assert all(len(xx) == numAmps for xx in rr)
349 
350  if numAmps is None:
351  raise RuntimeError("Unable to measure crosstalk signal for any amplifier")
352 
353  ratios = [[None for jj in range(numAmps)] for ii in range(numAmps)]
354  for ii, jj in itertools.product(range(numAmps), range(numAmps)):
355  if ii == jj:
356  result = []
357  else:
358  values = [rr[ii][jj] for rr in ratioList]
359  num = sum(len(vv) for vv in values)
360  if num == 0:
361  self.log.warn("No values for matrix element %d,%d" % (ii, jj))
362  result = np.nan
363  else:
364  result = np.concatenate([vv for vv in values if len(vv) > 0])
365  ratios[ii][jj] = result
366  self.debugRatios('reduce', ratios, ii, jj)
367  coeff, coeffErr, coeffNum = self.measureCrosstalkCoefficients(ratios, self.config.rejIter,
368  self.config.rejSigma)
369  self.log.info("Coefficients:\n%s\n", coeff)
370  self.log.info("Errors:\n%s\n", coeffErr)
371  self.log.info("Numbers:\n%s\n", coeffNum)
372  return coeff, coeffErr, coeffNum
373 
374  def measureCrosstalkCoefficients(self, ratios, rejIter=3, rejSigma=2.0):
375  """Measure crosstalk coefficients from the ratios.
376 
377  Given a list of ratios for each target/source amp combination,
378  we measure a sigma clipped mean and error.
379 
380  The coefficient errors returned are the standard deviation of
381  the final set of clipped input ratios.
382 
383  Parameters
384  ----------
385  ratios : `list` of `list` of `numpy.ndarray`
386  Matrix of arrays of ratios.
387  rejIter : `int`
388  Number of rejection iterations.
389  rejSigma : `float`
390  Rejection threshold (sigma).
391 
392  Returns
393  -------
394  coeff : `numpy.ndarray`
395  Crosstalk coefficients.
396  coeffErr : `numpy.ndarray`
397  Crosstalk coefficient errors.
398  coeffNum : `numpy.ndarray`
399  Number of pixels for each measurement.
400 
401  Notes
402  -----
403  This has been moved into MeasureCrosstalkTask to allow for easier
404  debugging.
405 
406  The lsstDebug.Info() method can be rewritten for __name__ =
407  `lsst.ip.isr.measureCrosstalk`, and supports the parameters:
408 
409  debug.display['measure'] : `bool`
410  Display a histogram of the combined ratio measurements for
411  a pair of source/target amplifiers from the final set of
412  clipped input ratios.
413  """
414  if rejIter is None:
415  rejIter = self.config.rejIter
416  if rejSigma is None:
417  rejSigma = self.config.rejSigma
418 
419  numAmps = len(ratios)
420  assert all(len(rr) == numAmps for rr in ratios)
421 
422  coeff = np.zeros((numAmps, numAmps))
423  coeffErr = np.zeros((numAmps, numAmps))
424  coeffNum = np.zeros((numAmps, numAmps), dtype=int)
425 
426  for ii, jj in itertools.product(range(numAmps), range(numAmps)):
427  if ii == jj:
428  values = [0.0]
429  else:
430  values = np.array(ratios[ii][jj])
431  values = values[np.abs(values) < 1.0] # Discard unreasonable values
432 
433  coeffNum[ii][jj] = len(values)
434 
435  if len(values) == 0:
436  self.log.warn("No values for matrix element %d,%d" % (ii, jj))
437  coeff[ii][jj] = np.nan
438  coeffErr[ii][jj] = np.nan
439  else:
440  if ii != jj:
441  for rej in range(rejIter):
442  lo, med, hi = np.percentile(values, [25.0, 50.0, 75.0])
443  sigma = 0.741*(hi - lo)
444  good = np.abs(values - med) < rejSigma*sigma
445  if good.sum() == len(good):
446  break
447  values = values[good]
448 
449  coeff[ii][jj] = np.mean(values)
450  coeffErr[ii][jj] = np.nan if coeffNum[ii][jj] == 1 else np.std(values)
451  self.debugRatios('measure', ratios, ii, jj)
452 
453  return coeff, coeffErr, coeffNum
454 
455  def debugView(self, stepname, exposure):
456  """Utility function to examine the image being processed.
457 
458  Parameters
459  ----------
460  stepname : `str`
461  State of processing to view.
462  exposure : `lsst.afw.image.Exposure`
463  Exposure to view.
464  """
465  frame = getDebugFrame(self._display, stepname)
466  if frame:
467  display = getDisplay(frame)
468  display.scale('asinh', 'zscale')
469  display.mtv(exposure)
470 
471  prompt = "Press Enter to continue: "
472  while True:
473  ans = input(prompt).lower()
474  if ans in ("", "c",):
475  break
476 
477  def debugPixels(self, stepname, pixelsIn, pixelsOut, i, j):
478  """Utility function to examine the CT ratio pixel values.
479 
480  Parameters
481  ----------
482  stepname : `str`
483  State of processing to view.
484  pixelsIn : `np.ndarray`
485  Pixel values from the potential crosstalk "source".
486  pixelsOut : `np.ndarray`
487  Pixel values from the potential crosstalk "victim".
488  i : `int`
489  Index of the source amplifier.
490  j : `int`
491  Index of the target amplifier.
492  """
493  frame = getDebugFrame(self._display, stepname)
494  if frame:
495  if i == j or len(pixelsIn) == 0 or len(pixelsOut) < 1:
496  pass
497  import matplotlib.pyplot as plot
498  figure = plot.figure(1)
499  figure.clear()
500 
501  axes = figure.add_axes((0.1, 0.1, 0.8, 0.8))
502  axes.plot(pixelsIn, pixelsOut / pixelsIn, 'k+')
503  plot.xlabel("Source amplifier pixel value")
504  plot.ylabel("Measured pixel ratio")
505  plot.title("(Source %d -> Victim %d) median ratio: %f" %
506  (i, j, np.median(pixelsOut / pixelsIn)))
507  figure.show()
508 
509  prompt = "Press Enter to continue: "
510  while True:
511  ans = input(prompt).lower()
512  if ans in ("", "c",):
513  break
514  plot.close()
515 
516  def debugRatios(self, stepname, ratios, i, j):
517  """Utility function to examine the final CT ratio set.
518 
519  Parameters
520  ----------
521  stepname : `str`
522  State of processing to view.
523  ratios : `List` of `List` of `np.ndarray`
524  Array of measured CT ratios, indexed by source/victim
525  amplifier.
526  i : `int`
527  Index of the source amplifier.
528  j : `int`
529  Index of the target amplifier.
530  """
531  frame = getDebugFrame(self._display, stepname)
532  if frame:
533  if i == j or ratios is None or len(ratios) < 1:
534  pass
535 
536  RR = ratios[i][j]
537  if RR is None or len(RR) < 1:
538  pass
539 
540  value = np.mean(RR)
541 
542  import matplotlib.pyplot as plot
543  figure = plot.figure(1)
544  figure.clear()
545  plot.hist(x=RR, bins='auto', color='b', rwidth=0.9)
546  plot.xlabel("Measured pixel ratio")
547  plot.axvline(x=value, color="k")
548  plot.title("(Source %d -> Victim %d) clipped mean ratio: %f" % (i, j, value))
549  figure.show()
550 
551  prompt = "Press Enter to continue: "
552  while True:
553  ans = input(prompt).lower()
554  if ans in ("", "c",):
555  break
556  plot.close()
def makeSubtask(self, name, keyArgs)
Definition: task.py:275
A Threshold is used to pass a threshold value to detection algorithms.
Definition: Threshold.h:43
bool all(CoordinateExpr< N > const &expr) noexcept
Return true if all elements are true.
def calculateBackground(mi, badPixels=["BAD"])
Definition: crosstalk.py:228
def measureCrosstalkCoefficients(self, ratios, rejIter=3, rejSigma=2.0)
def extractAmp(image, amp, corner, isTrimmed=False)
Definition: crosstalk.py:196
def extractCrosstalkRatios(self, exposure, threshold=None, badPixels=None)
def getDebugFrame(debugDisplay, name)
Definition: lsstDebug.py:90
A set of Footprints, associated with a MaskedImage.
Definition: FootprintSet.h:53
daf::base::PropertyList * list
Definition: fits.cc:903
def writeCrosstalkCoeffs(outputFileName, coeff, det=None, crosstalkName="Unknown", indent=2)
Definition: crosstalk.py:349
def debugPixels(self, stepname, pixelsIn, pixelsOut, i, j)