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LSST Data Management Base Package
SimplePhotometryModel.cc
Go to the documentation of this file.
1// -*- LSST-C++ -*-
2/*
3 * This file is part of jointcal.
4 *
5 * Developed for the LSST Data Management System.
6 * This product includes software developed by the LSST Project
7 * (https://www.lsst.org).
8 * See the COPYRIGHT file at the top-level directory of this distribution
9 * for details of code ownership.
10 *
11 * This program is free software: you can redistribute it and/or modify
12 * it under the terms of the GNU General Public License as published by
13 * the Free Software Foundation, either version 3 of the License, or
14 * (at your option) any later version.
15 *
16 * This program is distributed in the hope that it will be useful,
17 * but WITHOUT ANY WARRANTY; without even the implied warranty of
18 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 * GNU General Public License for more details.
20 *
21 * You should have received a copy of the GNU General Public License
22 * along with this program. If not, see <https://www.gnu.org/licenses/>.
23 */
24
25#include <iostream>
26#include <cmath>
27
28#include "lsst/log/Log.h"
34
35namespace lsst {
36namespace jointcal {
37
38Eigen::Index SimplePhotometryModel::assignIndices(std::string const &whatToFit, Eigen::Index firstIndex) {
39 Eigen::Index ipar = firstIndex;
40 for (auto const &i : _myMap) {
41 auto mapping = i.second.get();
42 mapping->setIndex(ipar);
43 ipar += mapping->getNpar();
44 }
45 return ipar;
46}
47
48void SimplePhotometryModel::offsetParams(Eigen::VectorXd const &delta) {
49 for (auto &i : _myMap) {
50 auto mapping = i.second.get();
51 mapping->offsetParams(delta.segment(mapping->getIndex(), mapping->getNpar()));
52 }
53}
54
56 for (auto &i : _myMap) {
57 i.second->freezeErrorTransform();
58 }
59}
60
62 std::vector<Eigen::Index> &indices) const {
63 auto mapping = findMapping(ccdImage);
64 if (indices.size() < mapping->getNpar()) indices.resize(mapping->getNpar());
65 indices[0] = mapping->getIndex();
66}
67
69 std::size_t total = 0;
70 for (auto &i : _myMap) {
71 total += i.second->getNpar();
72 }
73 return total;
74}
75
77 CcdImage const &ccdImage,
78 Eigen::VectorXd &derivatives) const {
79 auto mapping = findMapping(ccdImage);
80 mapping->computeParameterDerivatives(measuredStar, measuredStar.getInstFlux(), derivatives);
81}
82
84 for (auto &i : _myMap) {
85 out << i.first << ": ";
86 i.second->print(out);
87 out << std::endl;
88 }
89}
90
92 auto i = _myMap.find(ccdImage.getHashKey());
93 if (i == _myMap.end())
95 "SimplePhotometryModel cannot find CcdImage " + ccdImage.getName());
96 return i->second.get();
97}
98
99SimpleFluxModel::SimpleFluxModel(CcdImageList const &ccdImageList, double errorPedestal)
100 : SimplePhotometryModel(ccdImageList, LOG_GET("lsst.jointcal.SimpleFluxModel"), errorPedestal) {
101 for (auto const &ccdImage : ccdImageList) {
102 auto photoCalib = ccdImage->getPhotoCalib();
103 // Use the single-frame processing calibration from the PhotoCalib as the initial value.
104 auto transform = std::make_shared<FluxTransformSpatiallyInvariant>(photoCalib->getCalibrationMean());
105 _myMap.emplace(ccdImage->getHashKey(), std::make_unique<PhotometryMapping>(transform));
106 }
107 LOGLS_INFO(_log, "SimpleFluxModel got " << _myMap.size() << " ccdImage mappings.");
108}
109
110double SimpleFluxModel::computeResidual(CcdImage const &ccdImage, MeasuredStar const &measuredStar) const {
111 return transform(ccdImage, measuredStar) - measuredStar.getFittedStar()->getFlux();
112}
113
114double SimpleFluxModel::transform(CcdImage const &ccdImage, MeasuredStar const &star) const {
115 auto mapping = findMapping(ccdImage);
116 return mapping->transform(star, star.getInstFlux());
117}
118
119double SimpleFluxModel::transformError(CcdImage const &ccdImage, MeasuredStar const &star) const {
120 auto mapping = findMapping(ccdImage);
121 double tempErr = tweakFluxError(star);
122 return mapping->transformError(star, star.getInstFlux(), tempErr);
123}
124
126 double calibration = (findMapping(ccdImage)->getParameters()[0]);
127 auto oldPhotoCalib = ccdImage.getPhotoCalib();
128 return std::make_unique<afw::image::PhotoCalib>(calibration, oldPhotoCalib->getCalibrationErr());
129}
130
132 out << "SimpleFluxModel (" << _myMap.size() << " mappings):" << std::endl;
134}
135
136SimpleMagnitudeModel::SimpleMagnitudeModel(CcdImageList const &ccdImageList, double errorPedestal)
137 : SimplePhotometryModel(ccdImageList, LOG_GET("lsst.jointcal.SimpleMagnitudeModel"), errorPedestal) {
138 for (auto const &ccdImage : ccdImageList) {
139 auto photoCalib = ccdImage->getPhotoCalib();
140 // Use the single-frame processing calibration from the PhotoCalib as the default.
141 double calib = utils::nanojanskyToABMagnitude(photoCalib->getCalibrationMean());
142 auto transform = std::make_shared<MagnitudeTransformSpatiallyInvariant>(calib);
143 _myMap.emplace(ccdImage->getHashKey(), std::make_unique<PhotometryMapping>(transform));
144 }
145 LOGLS_INFO(_log, "SimpleMagnitudeModel got " << _myMap.size() << " ccdImage mappings.");
146}
147
149 MeasuredStar const &measuredStar) const {
150 return transform(ccdImage, measuredStar) - measuredStar.getFittedStar()->getMag();
151}
152
153double SimpleMagnitudeModel::transform(CcdImage const &ccdImage, MeasuredStar const &star) const {
154 auto mapping = findMapping(ccdImage);
155 return mapping->transform(star, star.getInstMag());
156}
157
158double SimpleMagnitudeModel::transformError(CcdImage const &ccdImage, MeasuredStar const &star) const {
159 auto mapping = findMapping(ccdImage);
160 double tempErr = tweakMagnitudeError(star);
161 return mapping->transformError(star, star.getInstMag(), tempErr);
162}
163
165 // NOTE: photocalib is defined as `instFlux * calibration = flux`,
166 // so we have to convert the transform from magnitude space.
167 double calibration = utils::ABMagnitudeToNanojansky(findMapping(ccdImage)->getParameters()[0]);
168 auto oldPhotoCalib = ccdImage.getPhotoCalib();
169 return std::make_unique<afw::image::PhotoCalib>(calibration, oldPhotoCalib->getCalibrationErr());
170}
171
173 out << "SimpleMagnitudeModel (" << _myMap.size() << " mappings):" << std::endl;
175}
176
177} // namespace jointcal
178} // namespace lsst
#define LSST_EXCEPT(type,...)
Create an exception with a given type.
Definition: Exception.h:48
LSST DM logging module built on log4cxx.
#define LOG_GET(logger)
Returns a Log object associated with logger.
Definition: Log.h:75
#define LOGLS_INFO(logger, message)
Log a info-level message using an iostream-based interface.
Definition: Log.h:639
Handler of an actual image from a single CCD.
Definition: CcdImage.h:64
std::shared_ptr< afw::image::PhotoCalib > getPhotoCalib() const
Return the exposure's photometric calibration.
Definition: CcdImage.h:160
std::string getName() const
Return the _name that identifies this ccdImage.
Definition: CcdImage.h:79
CcdImageKey getHashKey() const
Definition: CcdImage.h:152
Sources measured on images.
Definition: MeasuredStar.h:51
std::shared_ptr< FittedStar > getFittedStar() const
Definition: MeasuredStar.h:118
Relates transform(s) to their position in the fitting matrix and allows interaction with the transfor...
virtual Eigen::VectorXd getParameters()=0
LOG_LOGGER _log
lsst.logging instance, to be created by a subclass so that messages have consistent name.
double tweakFluxError(jointcal::MeasuredStar const &measuredStar) const
Add a fraction of the instrumental flux to the instrumental flux error, in quadrature.
double tweakMagnitudeError(jointcal::MeasuredStar const &measuredStar) const
Add a small magnitude offset to the "instrumental magnitude" error, in quadrature.
void print(std::ostream &out) const override
Print a string representation of the contents of this mapping, for debugging.
double transformError(CcdImage const &ccdImage, MeasuredStar const &measuredStar) const override
Return the on-sky transformed flux uncertainty for measuredStar on ccdImage.
double transform(CcdImage const &ccdImage, MeasuredStar const &measuredStar) const override
Return the on-sky transformed flux for measuredStar on ccdImage.
SimpleFluxModel(CcdImageList const &ccdImageList, double errorPedestal=0)
double computeResidual(CcdImage const &ccdImage, MeasuredStar const &measuredStar) const override
Compute the residual between the model applied to a star and its associated fittedStar.
std::shared_ptr< afw::image::PhotoCalib > toPhotoCalib(CcdImage const &ccdImage) const override
Return the mapping of ccdImage represented as a PhotoCalib.
double computeResidual(CcdImage const &ccdImage, MeasuredStar const &measuredStar) const override
Compute the residual between the model applied to a star and its associated fittedStar.
std::shared_ptr< afw::image::PhotoCalib > toPhotoCalib(CcdImage const &ccdImage) const override
Return the mapping of ccdImage represented as a PhotoCalib.
double transform(CcdImage const &ccdImage, MeasuredStar const &measuredStar) const override
Return the on-sky transformed flux for measuredStar on ccdImage.
SimpleMagnitudeModel(CcdImageList const &ccdImageList, double errorPedestal=0)
double transformError(CcdImage const &ccdImage, MeasuredStar const &measuredStar) const override
Return the on-sky transformed flux uncertainty for measuredStar on ccdImage.
void print(std::ostream &out) const override
Print a string representation of the contents of this mapping, for debugging.
Photometric response model which has a single photometric factor per CcdImage.
void computeParameterDerivatives(MeasuredStar const &measuredStar, CcdImage const &ccdImage, Eigen::VectorXd &derivatives) const override
Compute the parametric derivatives of this model.
std::size_t getTotalParameters() const override
Return the total number of parameters in this model.
PhotometryMappingBase * findMapping(CcdImage const &ccdImage) const override
Return the mapping associated with this ccdImage.
void getMappingIndices(CcdImage const &ccdImage, IndexVector &indices) const override
Get how this set of parameters (of length Npar()) map into the "grand" fit.
void offsetParams(Eigen::VectorXd const &delta) override
Offset the parameters by the provided amounts (by -delta).
Eigen::Index assignIndices(std::string const &whatToFit, Eigen::Index firstIndex) override
Assign indices in the full matrix to the parameters being fit in the mappings, starting at firstIndex...
void freezeErrorTransform() override
Once this routine has been called, the error transform is not modified by offsetParams().
void print(std::ostream &out) const override
Print a string representation of the contents of this mapping, for debugging.
Reports invalid arguments.
Definition: Runtime.h:66
T emplace(T... args)
T end(T... args)
T endl(T... args)
T find(T... args)
double ABMagnitudeToNanojansky(double magnitude)
Convert an AB magnitude to a flux in nanojansky.
Definition: Magnitude.cc:32
double nanojanskyToABMagnitude(double flux)
Convert a flux in nanojansky to AB magnitude.
Definition: Magnitude.cc:30
A base class for image defects.
T resize(T... args)
T size(T... args)
Key< int > photoCalib
Definition: Exposure.cc:67
Key< int > calib
Definition: Exposure.cc:66