LSST Applications 26.0.0,g0265f82a02+6660c170cc,g07994bdeae+30b05a742e,g0a0026dc87+17526d298f,g0a60f58ba1+17526d298f,g0e4bf8285c+96dd2c2ea9,g0ecae5effc+c266a536c8,g1e7d6db67d+6f7cb1f4bb,g26482f50c6+6346c0633c,g2bbee38e9b+6660c170cc,g2cc88a2952+0a4e78cd49,g3273194fdb+f6908454ef,g337abbeb29+6660c170cc,g337c41fc51+9a8f8f0815,g37c6e7c3d5+7bbafe9d37,g44018dc512+6660c170cc,g4a941329ef+4f7594a38e,g4c90b7bd52+5145c320d2,g58be5f913a+bea990ba40,g635b316a6c+8d6b3a3e56,g67924a670a+bfead8c487,g6ae5381d9b+81bc2a20b4,g93c4d6e787+26b17396bd,g98cecbdb62+ed2cb6d659,g98ffbb4407+81bc2a20b4,g9ddcbc5298+7f7571301f,ga1e77700b3+99e9273977,gae46bcf261+6660c170cc,gb2715bf1a1+17526d298f,gc86a011abf+17526d298f,gcf0d15dbbd+96dd2c2ea9,gdaeeff99f8+0d8dbea60f,gdb4ec4c597+6660c170cc,ge23793e450+96dd2c2ea9,gf041782ebf+171108ac67
LSST Data Management Base Package
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simple_curve.py
Go to the documentation of this file.
2# LSST Data Management System
3#
4# Copyright 2019 AURA/LSST.
5#
6# This product includes software developed by the
7# LSST Project (http://www.lsst.org/).
8#
9# This program is free software: you can redistribute it and/or modify
10# it under the terms of the GNU General Public License as published by
11# the Free Software Foundation, either version 3 of the License, or
12# (at your option) any later version.
13#
14# This program is distributed in the hope that it will be useful,
15# but WITHOUT ANY WARRANTY; without even the implied warranty of
16# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17# GNU General Public License for more details.
18#
19# You should have received a copy of the LSST License Statement and
20# the GNU General Public License along with this program. If not,
21# see <https://www.lsstcorp.org/LegalNotices/>.
22#
23
24__all__ = ["Curve", "AmpCurve", "DetectorCurve", "ImageCurve"]
25
26from scipy.interpolate import interp1d
27from astropy.table import QTable
28import astropy.units as u
29from abc import ABC, abstractmethod
30import datetime
31import os
32import numpy
33
34import lsst.afw.cameraGeom.utils as cgUtils
35from lsst.geom import Point2I
36
37
38class Curve(ABC):
39 """ An abstract class to represent an arbitrary curve with
40 interpolation.
41 """
42 mode = ''
43 subclasses = dict()
44
45 def __init__(self, wavelength, efficiency, metadata):
46 if not (isinstance(wavelength, u.Quantity) and wavelength.unit.physical_type == 'length'):
47 raise ValueError('The wavelength must be a quantity with a length sense.')
48 if not isinstance(efficiency, u.Quantity) or efficiency.unit != u.percent:
49 raise ValueError('The efficiency must be a quantity with units of percent.')
50 self.wavelength = wavelength
51 self.efficiency = efficiency
52 # make sure needed metadata is set if built directly from ctor.
53 metadata.update({'MODE': self.modemode, 'TYPE': 'QE'})
54 self.metadata = metadata
55
56 @classmethod
57 @abstractmethod
58 def fromTable(cls, table):
59 """Class method for constructing a `Curve` object.
60
61 Parameters
62 ----------
63 table : `astropy.table.QTable`
64 Table containing metadata and columns necessary
65 for constructing a `Curve` object.
66
67 Returns
68 -------
69 curve : `Curve`
70 A `Curve` subclass of the appropriate type according
71 to the table metadata
72 """
73 pass
74
75 @abstractmethod
76 def toTable(self):
77 """Convert this `Curve` object to an `astropy.table.QTable`.
78
79 Returns
80 -------
81 table : `astropy.table.QTable`
82 A table object containing the data from this `Curve`.
83 """
84 pass
85
86 @abstractmethod
87 def evaluate(self, detector, position, wavelength, kind='linear', bounds_error=False, fill_value=0):
88 """Interpolate the curve at the specified position and wavelength.
89
90 Parameters
91 ----------
93 Is used to find the appropriate curve given the position for
94 curves that vary over the detector. Ignored in the case where
95 there is only a single curve per detector.
96 position : `lsst.geom.Point2D`
97 The position on the detector at which to evaluate the curve.
98 wavelength : `astropy.units.Quantity`
99 The wavelength(s) at which to make the interpolation.
100 kind : `str`, optional
101 The type of interpolation to do (default is 'linear').
102 See documentation for `scipy.interpolate.interp1d` for
103 accepted values.
104 bounds_error : `bool`, optional
105 Raise error if interpolating outside the range of x?
106 (default is False)
107 fill_value : `float`, optional
108 Fill values outside the range of x with this value
109 (default is 0).
110
111 Returns
112 -------
113 value : `astropy.units.Quantity`
114 Interpolated value(s). Number of values returned will match the
115 length of `wavelength`.
116
117 Raises
118 ------
119 ValueError
120 If the ``bounds_error`` is changed from the default, it will raise
121 a `ValueError` if evaluating outside the bounds of the curve.
122 """
123 pass
124
125 @classmethod
126 def __init_subclass__(cls, **kwargs):
127 """Register subclasses with the abstract base class"""
128 super().__init_subclass__(**kwargs)
129 if cls.modemode in Curve.subclasses:
130 raise ValueError(f'Class for mode, {cls.mode}, already defined')
131 Curve.subclasses[cls.modemode] = cls
132
133 @abstractmethod
134 def __eq__(self, other):
135 """Define equality for this class"""
136 pass
137
138 def compare_metadata(self, other,
139 keys_to_compare=['MODE', 'TYPE', 'CALIBDATE', 'INSTRUME', 'OBSTYPE', 'DETECTOR']):
140 """Compare metadata in this object to another.
141
142 Parameters
143 ----------
144 other : `Curve`
145 The object with which to compare metadata.
146 keys_to_compare : `list`
147 List of metadata keys to compare.
148
149 Returns
150 -------
151 same : `bool`
152 Are the metadata the same?
153 """
154 for k in keys_to_compare:
155 if self.metadata[k] != other.metadata[k]:
156 return False
157 return True
158
159 def interpolate(self, wavelengths, values, wavelength, kind, bounds_error, fill_value):
160 """Interplate the curve at the specified wavelength(s).
161
162 Parameters
163 ----------
164 wavelengths : `astropy.units.Quantity`
165 The wavelength values for the curve.
166 values : `astropy.units.Quantity`
167 The y-values for the curve.
168 wavelength : `astropy.units.Quantity`
169 The wavelength(s) at which to make the interpolation.
170 kind : `str`
171 The type of interpolation to do. See documentation for
172 `scipy.interpolate.interp1d` for accepted values.
173
174 Returns
175 -------
176 value : `astropy.units.Quantity`
177 Interpolated value(s)
178 """
179 if not isinstance(wavelength, u.Quantity):
180 raise ValueError("Wavelengths at which to interpolate must be astropy quantities")
181 if not (isinstance(wavelengths, u.Quantity) and isinstance(values, u.Quantity)):
182 raise ValueError("Model to be interpreted must be astropy quantities")
183 interp_wavelength = wavelength.to(wavelengths.unit)
184 f = interp1d(wavelengths, values, kind=kind, bounds_error=bounds_error, fill_value=fill_value)
185 return f(interp_wavelength.value)*values.unit
186
187 def getMetadata(self):
188 """Return metadata
189
190 Returns
191 -------
192 metadata : `dict`
193 Dictionary of metadata for this curve.
194 """
195 # Needed to duck type as an object that can be ingested
196 return self.metadata
197
198 @classmethod
199 def readText(cls, filename):
200 """Class method for constructing a `Curve` object from
201 the standardized text format.
202
203 Parameters
204 ----------
205 filename : `str`
206 Path to the text file to read.
207
208 Returns
209 -------
210 curve : `Curve`
211 A `Curve` subclass of the appropriate type according
212 to the table metadata
213 """
214 table = QTable.read(filename, format='ascii.ecsv')
215 return cls.subclasses[table.meta['MODE']].fromTable(table)
216
217 @classmethod
218 def readFits(cls, filename):
219 """Class method for constructing a `Curve` object from
220 the standardized FITS format.
221
222 Parameters
223 ----------
224 filename : `str`
225 Path to the FITS file to read.
226
227 Returns
228 -------
229 curve : `Curve`
230 A `Curve` subclass of the appropriate type according
231 to the table metadata
232 """
233 table = QTable.read(filename, format='fits')
234 return cls.subclasses[table.meta['MODE']].fromTable(table)
235
236 @staticmethod
237 def _check_cols(cols, table):
238 """Check that the columns are in the table"""
239 for col in cols:
240 if col not in table.columns:
241 raise ValueError(f'The table must include a column named "{col}".')
242
244 """Compute standard metadata before writing file out"""
245 now = datetime.datetime.utcnow()
246 table = self.toTable()
247 metadata = table.meta
248 metadata["DATE"] = now.isoformat()
249 metadata["CALIB_CREATION_DATE"] = now.strftime("%Y-%m-%d")
250 metadata["CALIB_CREATION_TIME"] = now.strftime("%T %Z").strip()
251 return table
252
253 def writeText(self, filename):
254 """ Write the `Curve` out to a text file.
255
256 Parameters
257 ----------
258 filename : `str`
259 Path to the text file to write.
260
261 Returns
262 -------
263 filename : `str`
264 Because this method forces a particular extension return
265 the name of the file actually written.
266 """
267 table = self._to_table_with_meta()
268 # Force file extension to .ecsv
269 path, ext = os.path.splitext(filename)
270 filename = path + ".ecsv"
271 table.write(filename, format="ascii.ecsv")
272 return filename
273
274 def writeFits(self, filename):
275 """ Write the `Curve` out to a FITS file.
276
277 Parameters
278 ----------
279 filename : `str`
280 Path to the FITS file to write.
281
282 Returns
283 -------
284 filename : `str`
285 Because this method forces a particular extension return
286 the name of the file actually written.
287 """
288 table = self._to_table_with_meta()
289 # Force file extension to .ecsv
290 path, ext = os.path.splitext(filename)
291 filename = path + ".fits"
292 table.write(filename, format="fits")
293 return filename
294
295
297 """Subclass of `Curve` that represents a single curve per detector.
298
299 Parameters
300 ----------
301 wavelength : `astropy.units.Quantity`
302 Wavelength values for this curve
303 efficiency : `astropy.units.Quantity`
304 Quantum efficiency values for this curve
305 metadata : `dict`
306 Dictionary of metadata for this curve
307 """
308 mode = 'DETECTOR'
309
310 def __eq__(self, other):
311 return (self.compare_metadata(other)
312 and numpy.array_equal(self.wavelengthwavelength, other.wavelength)
313 and numpy.array_equal(self.wavelengthwavelength, other.wavelength))
314
315 @classmethod
316 def fromTable(cls, table):
317 # Docstring inherited from base classs
318 cls._check_cols(['wavelength', 'efficiency'], table)
319 return cls(table['wavelength'], table['efficiency'], table.meta)
320
321 def toTable(self):
322 # Docstring inherited from base classs
323 return QTable({'wavelength': self.wavelengthwavelength, 'efficiency': self.efficiencyefficiency}, meta=self.metadata)
324
325 def evaluate(self, detector, position, wavelength, kind='linear', bounds_error=False, fill_value=0):
326 # Docstring inherited from base classs
327 return self.interpolate(self.wavelengthwavelength, self.efficiencyefficiency, wavelength,
328 kind=kind, bounds_error=bounds_error, fill_value=fill_value)
329
330
332 """Subclass of `Curve` that represents a curve per amp.
333
334 Parameters
335 ----------
336 amp_name_list : iterable of `str`
337 The name of the amp for each entry
338 wavelength : `astropy.units.Quantity`
339 Wavelength values for this curve
340 efficiency : `astropy.units.Quantity`
341 Quantum efficiency values for this curve
342 metadata : `dict`
343 Dictionary of metadata for this curve
344 """
345 mode = 'AMP'
346
347 def __init__(self, amp_name_list, wavelength, efficiency, metadata):
348 super().__init__(wavelength, efficiency, metadata)
349 amp_names = set(amp_name_list)
350 self.data = {}
351 for amp_name in sorted(amp_names):
352 idx = numpy.where(amp_name_list == amp_name)[0]
353 # Deal with the case where the keys are bytes from FITS
354 name = amp_name
355 if isinstance(name, bytes):
356 name = name.decode()
357 self.data[name] = (wavelength[idx], efficiency[idx])
358
359 def __eq__(self, other):
360 if not self.compare_metadata(other):
361 return False
362 for k in self.data:
363 if not numpy.array_equal(self.data[k][0], other.data[k][0]):
364 return False
365 if not numpy.array_equal(self.data[k][1], other.data[k][1]):
366 return False
367 return True
368
369 @classmethod
370 def fromTable(cls, table):
371 # Docstring inherited from base classs
372 cls._check_cols(['amp_name', 'wavelength', 'efficiency'], table)
373 return cls(table['amp_name'], table['wavelength'],
374 table['efficiency'], table.meta)
375
376 def toTable(self):
377 # Docstring inherited from base classs
378 wavelength = None
379 efficiency = None
380 names = numpy.array([])
381 # Loop over the amps and concatenate into three same length columns to feed
382 # to the Table constructor.
383 for amp_name, val in self.data.items():
384 # This will preserve the quantity
385 if wavelength is None:
386 wunit = val[0].unit
387 wavelength = val[0].value
388 else:
389 wavelength = numpy.concatenate([wavelength, val[0].value])
390 if efficiency is None:
391 eunit = val[1].unit
392 efficiency = val[1].value
393 else:
394 efficiency = numpy.concatenate([efficiency, val[1].value])
395 names = numpy.concatenate([names, numpy.full(val[0].shape, amp_name)])
396 names = numpy.array(names)
397 # Note that in future, the astropy.unit should make it through concatenation
398 return QTable({'amp_name': names, 'wavelength': wavelength*wunit, 'efficiency': efficiency*eunit},
399 meta=self.metadata)
400
401 def evaluate(self, detector, position, wavelength, kind='linear', bounds_error=False, fill_value=0):
402 # Docstring inherited from base classs
403 amp = cgUtils.findAmp(detector, Point2I(position)) # cast to Point2I if Point2D passed
404 w, e = self.data[amp.getName()]
405 return self.interpolate(w, e, wavelength, kind=kind, bounds_error=bounds_error,
406 fill_value=fill_value)
407
408
410 mode = 'IMAGE'
411
412 def fromTable(self, table):
413 # Docstring inherited from base classs
414 raise NotImplementedError()
415
416 def toTable(self):
417 # Docstring inherited from base classs
418 raise NotImplementedError()
419
420 def evaluate(self, detector, position, wavelength, kind='linear', bounds_error=False, fill_value=0):
421 # Docstring inherited from base classs
422 raise NotImplementedError()
std::vector< SchemaItem< Flag > > * items
A representation of a detector in a mosaic camera.
Definition Detector.h:185
__init__(self, amp_name_list, wavelength, efficiency, metadata)
evaluate(self, detector, position, wavelength, kind='linear', bounds_error=False, fill_value=0)
evaluate(self, detector, position, wavelength, kind='linear', bounds_error=False, fill_value=0)
compare_metadata(self, other, keys_to_compare=['MODE', 'TYPE', 'CALIBDATE', 'INSTRUME', 'OBSTYPE', 'DETECTOR'])
__init__(self, wavelength, efficiency, metadata)
interpolate(self, wavelengths, values, wavelength, kind, bounds_error, fill_value)
evaluate(self, detector, position, wavelength, kind='linear', bounds_error=False, fill_value=0)
evaluate(self, detector, position, wavelength, kind='linear', bounds_error=False, fill_value=0)
daf::base::PropertySet * set
Definition fits.cc:927
bool strip
Definition fits.cc:926