LSST Applications  21.0.0-147-g0e635eb1+1acddb5be5,22.0.0+052faf71bd,22.0.0+1ea9a8b2b2,22.0.0+6312710a6c,22.0.0+729191ecac,22.0.0+7589c3a021,22.0.0+9f079a9461,22.0.1-1-g7d6de66+b8044ec9de,22.0.1-1-g87000a6+536b1ee016,22.0.1-1-g8e32f31+6312710a6c,22.0.1-10-gd060f87+016f7cdc03,22.0.1-12-g9c3108e+df145f6f68,22.0.1-16-g314fa6d+c825727ab8,22.0.1-19-g93a5c75+d23f2fb6d8,22.0.1-19-gb93eaa13+aab3ef7709,22.0.1-2-g8ef0a89+b8044ec9de,22.0.1-2-g92698f7+9f079a9461,22.0.1-2-ga9b0f51+052faf71bd,22.0.1-2-gac51dbf+052faf71bd,22.0.1-2-gb66926d+6312710a6c,22.0.1-2-gcb770ba+09e3807989,22.0.1-20-g32debb5+b8044ec9de,22.0.1-23-gc2439a9a+fb0756638e,22.0.1-3-g496fd5d+09117f784f,22.0.1-3-g59f966b+1e6ba2c031,22.0.1-3-g849a1b8+f8b568069f,22.0.1-3-gaaec9c0+c5c846a8b1,22.0.1-32-g5ddfab5d3+60ce4897b0,22.0.1-4-g037fbe1+64e601228d,22.0.1-4-g8623105+b8044ec9de,22.0.1-5-g096abc9+d18c45d440,22.0.1-5-g15c806e+57f5c03693,22.0.1-7-gba73697+57f5c03693,master-g6e05de7fdc+c1283a92b8,master-g72cdda8301+729191ecac,w.2021.39
LSST Data Management Base Package
DipoleAlgorithms.h
Go to the documentation of this file.
1 // -*- LSST-C++ -*-
2 
3 /*
4  * LSST Data Management System
5  * Copyright 2008-2015 AURA/LSST
6  *
7  * This product includes software developed by the
8  * LSST Project (http://www.lsst.org/).
9  *
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24 
25 #ifndef LSST_IP_DIFFIM_DIPOLEALGORITHMS_H
26 #define LSST_IP_DIFFIM_DIPOLEALGORITHMS_H
28 // Control/algorithm hierarchy for dipole measurement.
29 //
30 
31 #include <stdio.h>
32 #include <execinfo.h>
33 #include <signal.h>
34 #include <stdlib.h>
35 #include <unistd.h>
36 #include <array>
37 
38 #include "lsst/base.h"
39 #include "lsst/pex/config.h"
40 #include "ndarray/eigen.h"
41 #include "lsst/afw/table/Source.h"
47 
48 namespace lsst {
49 namespace ip {
50 namespace diffim {
51 
53 public:
54 
55  explicit DipoleCentroidControl() {}
56 };
57 
59 public:
60 
61  explicit DipoleFluxControl() {}
62 };
63 
68 public:
69  LSST_CONTROL_FIELD(stepSizeCoord, float, "Default initial step size for coordinates in non-linear fitter");
70  LSST_CONTROL_FIELD(stepSizeFlux, float, "Default initial step size for flux in non-linear fitter");
71  LSST_CONTROL_FIELD(errorDef, double, "How many sigma the error bars of the non-linear fitter represent");
72  LSST_CONTROL_FIELD(maxFnCalls, int, "Maximum function calls for non-linear fitter; 0 = unlimited");
74  stepSizeCoord(0.1), stepSizeFlux(1.0), errorDef(1.0), maxFnCalls(100000) {}
75 };
76 
81 public:
82 
87 
89 
90  DipoleCentroidAlgorithm(Control const & ctrl, std::string const & name,
91  afw::table::Schema & schema, std::string const & doc);
92 
94 
96  ResultKey const & getPositiveKeys() const { return _positiveKeys; }
97  ResultKey const & getNegativeKeys() const { return _negativeKeys; }
98 
99 protected:
102  std::string const & doc, ResultKey const & positiveKeys, ResultKey const & negativeKeys);
103 
110 };
111 
116 public:
117 
122 
126 
128  std::string const & doc);
129 
130  // A typedef for the FunctorKey which returns the result of this algorithm
133  ResultKey const & getPositiveKeys() const { return _positiveKeys; }
134  ResultKey const & getNegativeKeys() const { return _negativeKeys; }
135 
136 protected:
137 
139  DipoleFluxAlgorithm(Control const & ctrl, std::string const & name,
140  afw::table::Schema & schema, std::string const & doc,
141  ResultKey const & positiveKeys, ResultKey const & negativeKeys);
142 
146 
149 };
150 
152  Control const & ctrl, std::string const & name, afw::table::Schema & schema, std::string const & doc
153  ) :
154  _ctrl(ctrl)
155 {
161  _positiveKeys = ResultKey(schema[name+"_pos"]);
162  _negativeKeys = ResultKey(schema[name+"_neg"]);
163 }
164 
166  Control const & ctrl, std::string const & name, afw::table::Schema & schema, std::string const & doc,
167  ResultKey const & positiveKeys, ResultKey const & negativeKeys
168  ) :
169  _ctrl(ctrl)
170 {
176 
177  _positiveKeys = ResultKey(schema[name+"_pos"]);
178  _negativeKeys = ResultKey(schema[name+"_neg"]);
179 }
180 
182  Control const & ctrl, std::string const & name, afw::table::Schema & schema,
183  std::string const & doc, ResultKey const & positiveKeys, ResultKey const & negativeKeys
184  ) :
185  _ctrl(ctrl)
186 {
188  meas::base::FluxResultKey::addFields(schema, name+"_pos", doc+": positive lobe");
189  meas::base::FluxResultKey::addFields(schema, name+"_neg", doc+": negative lobe");
190  _positiveKeys = ResultKey(positiveKeys);
191  _negativeKeys = ResultKey(negativeKeys);
192 }
193 
195  Control const & ctrl, std::string const & name, afw::table::Schema & schema,
196  std::string const & doc
197  ) :
198  _ctrl(ctrl)
199 {
201  meas::base::FluxResultKey::addFields(schema, name+"_pos", doc+": positive lobe");
202  meas::base::FluxResultKey::addFields(schema, name+"_neg", doc+": negative lobe");
203  _positiveKeys = ResultKey(schema[name+"_pos"]);
204  _negativeKeys = ResultKey(schema[name+"_neg"]);
205 }
206 
207 /*
208 class that knows how to calculate centroids as a simple unweighted first
209  * moment of the 3x3 region around the peaks
210  */
212 public:
213 
215 
217  DipoleFluxAlgorithm(ctrl, name, schema, "raw flux counts"),
218  _numPositiveKey(schema.addField<int>(name+"_npos", "number of positive pixels", "count")),
219  _numNegativeKey(schema.addField<int>(name+"_nneg", "number of negative pixels", "count"))
220  {
221  }
222 
223  void measure(
224  afw::table::SourceRecord & measRecord,
225  afw::image::Exposure<float> const & exposure
226  ) const;
227 
228  void fail(
229  afw::table::SourceRecord & measRecord,
231  ) const;
232 
233 private:
234 
235  Control _ctrl;
236  afw::table::Key<int> _numPositiveKey;
237  afw::table::Key<int> _numNegativeKey;
238 };
239 
244 public:
245 
253 
255  ResultKey const & getCenterKeys() const { return _centerKeys; }
256  ResultKey const & getPositiveKeys() const { return _positiveKeys; }
257  ResultKey const & getNegativeKeys() const { return _negativeKeys; }
258 
259  void measure(
260  afw::table::SourceRecord & measRecord,
261  afw::image::Exposure<float> const & exposure
262  ) const;
263 
264  void mergeCentroids(afw::table::SourceRecord & source, double posValue, double negValue) const;
265 
266  void fail(
267  afw::table::SourceRecord & measRecord,
269  ) const;
270 
271 protected:
274  ResultKey const & positiveKeys, ResultKey const & negativeKeys);
275 
276 private:
277 
278  Control _ctrl;
279  meas::base::FluxResultKey _fluxResultKey;
280  meas::base::FlagHandler _flagHandler;
281 };
282 
283 
284 
285 
290 public:
291 
293 
295  DipoleFluxAlgorithm(ctrl, name, schema, "jointly fitted psf flux counts"),
296  _ctrl(ctrl),
297  _chi2dofKey(schema.addField<float>(name+"_chi2dof",
298  "chi2 per degree of freedom of fit"))
299  {
300  meas::base::CentroidResultKey::addFields(schema, name+"_pos_centroid", "psf fitted center of positive lobe", meas::base::SIGMA_ONLY);
301  meas::base::CentroidResultKey::addFields(schema, name+"_neg_centroid", "psf fitted center of negative lobe", meas::base::SIGMA_ONLY);
302  meas::base::CentroidResultKey::addFields(schema, name+"_centroid", "average of negative and positive lobe positions", meas::base::SIGMA_ONLY);
303  _posCentroid = meas::base::CentroidResultKey(schema[name+"_pos_centroid"]);
304  _negCentroid = meas::base::CentroidResultKey(schema[name+"_neg_centroid"]);
305  _avgCentroid = meas::base::CentroidResultKey(schema[name+"_centroid"]);
306  }
308  afw::image::Exposure<float> const & exposure,
309  double negCenterX, double negCenterY, double negFlux,
310  double posCenterX, double poCenterY, double posFlux
311  ) const;
312 
313  void measure(
314  afw::table::SourceRecord & measRecord,
315  afw::image::Exposure<float> const & exposure
316  ) const;
317 
318  void fail(
319  afw::table::SourceRecord & measRecord,
321  ) const;
322 
323 private:
324 
325  Control _ctrl;
326  afw::table::Key<float> _chi2dofKey;
327  meas::base::CentroidResultKey _avgCentroid;
328  meas::base::CentroidResultKey _negCentroid;
329  meas::base::CentroidResultKey _posCentroid;
330 
331 };
332 
333 }}}// namespace lsst::ip::diffim
334 
335 #endif // !LSST_IP_DIFFIM_DIPOLEALGORITHMS_H
table::Key< std::string > name
Definition: Amplifier.cc:116
table::Schema schema
Definition: python.h:134
Basic LSST definitions.
Defines the fields and offsets for a table.
Definition: Schema.h:51
Record class that contains measurements made on a single exposure.
Definition: Source.h:78
Intermediate base class for algorithms that compute a centroid.
static meas::base::FlagDefinition const FAILURE
ResultKey const & getPositiveKeys() const
Return the standard centroid keys registered by this algorithm.
meas::base::CentroidResultKey ResultKey
ResultKey const & getNegativeKeys() const
static meas::base::FlagDefinition const POS_FLAG
static meas::base::FlagDefinition const NEG_FLAG
static meas::base::FlagDefinitionList const & getFlagDefinitions()
DipoleCentroidAlgorithm(Control const &ctrl, std::string const &name, afw::table::Schema &schema, std::string const &doc)
Intermediate base class for algorithms that compute a flux.
meas::base::FluxResultKey ResultKey
static meas::base::FlagDefinitionList const & getFlagDefinitions()
DipoleFluxControl Control
A typedef to the Control object for this algorithm, defined above.
static meas::base::FlagDefinition const POS_FLAG
static meas::base::FlagDefinition const NEG_FLAG
meas::base::FluxResultKey _fluxResultKey
DipoleFluxAlgorithm(Control const &ctrl, std::string const &name, afw::table::Schema &schema, std::string const &doc)
ResultKey const & getNegativeKeys() const
static meas::base::FlagDefinition const FAILURE
ResultKey const & getPositiveKeys() const
Return the standard flux keys registered by this algorithm.
Intermediate base class for algorithms that compute a centroid.
ResultKey const & getNegativeKeys() const
NaiveDipoleCentroid(Control const &ctrl, std::string const &name, afw::table::Schema &schema)
ResultKey const & getCenterKeys() const
Return the standard centroid keys registered by this algorithm.
ResultKey const & getPositiveKeys() const
meas::base::CentroidResultKey ResultKey
Tuple type that holds the keys that define a standard centroid algorithm.
NaiveDipoleCentroid(Control const &ctrl, std::string const &name, afw::table::Schema &schema, ResultKey const &positiveKeys, ResultKey const &negativeKeys)
Initialize with a manually-constructed key tuple.
void measure(afw::table::SourceRecord &measRecord, afw::image::Exposure< float > const &exposure) const
Given an image and a pixel position, return a Centroid using a naive 3x3 weighted moment.
void mergeCentroids(afw::table::SourceRecord &source, double posValue, double negValue) const
void fail(afw::table::SourceRecord &measRecord, meas::base::MeasurementError *error=NULL) const
Handle an exception thrown by the current algorithm by setting flags in the given record.
void measure(afw::table::SourceRecord &measRecord, afw::image::Exposure< float > const &exposure) const
Given an image and a pixel position, return a Centroid using a naive 3x3 weighted moment.
void fail(afw::table::SourceRecord &measRecord, meas::base::MeasurementError *error=NULL) const
Handle an exception thrown by the current algorithm by setting flags in the given record.
NaiveDipoleFlux(Control const &ctrl, std::string const &name, afw::table::Schema &schema)
C++ control object for PSF dipole fluxes.
float stepSizeCoord
"Default initial step size for coordinates in non-linear fitter" ;
double errorDef
"How many sigma the error bars of the non-linear fitter represent" ;
float stepSizeFlux
"Default initial step size for flux in non-linear fitter" ;
int maxFnCalls
"Maximum function calls for non-linear fitter; 0 = unlimited" ;
Implementation of Psf dipole flux.
std::pair< double, int > chi2(afw::table::SourceRecord &source, afw::image::Exposure< float > const &exposure, double negCenterX, double negCenterY, double negFlux, double posCenterX, double poCenterY, double posFlux) const
void measure(afw::table::SourceRecord &measRecord, afw::image::Exposure< float > const &exposure) const
Called to measure a single child source in an image.
PsfDipoleFlux(PsfDipoleFluxControl const &ctrl, std::string const &name, afw::table::Schema &schema)
void fail(afw::table::SourceRecord &measRecord, meas::base::MeasurementError *error=NULL) const
Handle an exception thrown by the current algorithm by setting flags in the given record.
A FunctorKey for CentroidResult.
static CentroidResultKey addFields(afw::table::Schema &schema, std::string const &name, std::string const &doc, UncertaintyEnum uncertainty)
Add the appropriate fields to a Schema, and return a CentroidResultKey that manages them.
vector-type utility class to build a collection of FlagDefinitions
Definition: FlagHandler.h:60
Utility class for handling flag fields that indicate the failure modes of an algorithm.
Definition: FlagHandler.h:148
static FlagHandler addFields(afw::table::Schema &schema, std::string const &prefix, FlagDefinitionList const &flagDefs, FlagDefinitionList const &exclDefs=FlagDefinitionList::getEmptyList())
Add Flag fields to a schema, creating a FlagHandler object to manage them.
Definition: FlagHandler.cc:37
A FunctorKey for FluxResult.
Definition: FluxUtilities.h:59
static FluxResultKey addFields(afw::table::Schema &schema, std::string const &name, std::string const &doc)
Add a pair of _instFlux, _instFluxErr fields to a Schema, and return a FluxResultKey that points to t...
Exception to be thrown when a measurement algorithm experiences a known failure mode.
Definition: exceptions.h:48
An abstract base classes for which the same implementation can be used for both SingleFrameAlgorithm ...
Definition: Algorithm.h:170
#define LSST_CONTROL_FIELD(NAME, TYPE, DOC)
A preprocessor macro used to define fields in C++ "control object" structs.
Definition: config.h:43
const char * source()
Source function that allows astChannel to source from a Stream.
Definition: Stream.h:224
@ SIGMA_ONLY
Only the diagonal elements of the covariance matrix are provided.
Definition: constants.h:45
A base class for image defects.
Simple class used to define and document flags The name and doc constitute the identity of the FlagDe...
Definition: FlagHandler.h:40