26 #include "ndarray/eigen.h" 39 FlagDefinitionList flagDefinitions;
44 flagDefinitions.add(
"flag_edge",
"Object too close to edge");
46 flagDefinitions.add(
"flag_noSecondDerivative",
"Vanishing second derivative");
48 flagDefinitions.add(
"flag_almostNoSecondDerivative",
"Almost vanishing second derivative");
50 flagDefinitions.add(
"flag_notAtMaximum",
"Object is not at a maximum");
58 float const AMPAST4 = 1.33;
67 static int inter4(
float vm,
float v0,
float vp,
float *cen,
bool negative =
false) {
68 float const sp = v0 - vp;
69 float const sm = v0 - vm;
70 float const d2 = sp + sm;
71 float const s = 0.5 * (vp - vm);
73 if ((!negative && (d2 <= 0.0f || v0 <= 0.0f)) || (negative && (d2 >= 0.0f || v0 >= 0.0f))) {
77 *cen = s / d2 * (1.0 + AMPAST4 * sp * sm / (d2 * v0));
79 return fabs(*cen) < 1 ? 0 : 1;
86 float astrom_errors(
float skyVar,
96 double const k = quarticBad ? 0 : AMPAST4;
109 sVar += 0.5 * sourceVar * exp(-1 / (2 * tau2));
110 dVar += sourceVar * (4 * exp(-1 / (2 * tau2)) + 2 * exp(-1 / (2 * tau2)));
113 dVar = skyVar / (2 *
geom::PI *
sigma2) * (3 - 4 * exp(-1 / (4 * sigma2)) + exp(-1 / sigma2));
115 sVar += sourceVar / (12 *
geom::PI *
sigma2) * (exp(-1 / (3 * sigma2)) - exp(-1 / sigma2));
116 dVar += sourceVar / (3 *
geom::PI *
sigma2) * (2 - 3 * exp(-1 / (3 * sigma2)) + exp(-1 / sigma2));
119 xVar = sVar * pow(1 / d + k / (4 * As) * (1 - 12 * s * s / (d * d)), 2) +
120 dVar * pow(s / (d * d) - k / (4 * As) * 8 * s * s / (d * d * d), 2);
122 return (xVar >= 0 ? sqrt(xVar) : NAN);
130 template <
typename ImageXy_locatorT,
typename VarImageXy_locatorT>
131 void doMeasureCentroidImpl(
double *xCenter,
135 double *sizeX2,
double *sizeY2,
137 VarImageXy_locatorT vim,
138 double smoothingSigma,
143 double const d2x = 2 * im(0, 0) - im(-1, 0) - im(1, 0);
144 double const d2y = 2 * im(0, 0) - im(0, -1) - im(0, 1);
145 double const sx = 0.5 * (im(1, 0) - im(-1, 0));
146 double const sy = 0.5 * (im(0, 1) - im(0, -1));
148 if (d2x == 0.0 || d2y == 0.0) {
150 SdssCentroidAlgorithm::NO_SECOND_DERIVATIVE.number);
152 if (d2x < 0.0 || d2y < 0.0) {
154 SdssCentroidAlgorithm::NOT_AT_MAXIMUM.doc +
156 SdssCentroidAlgorithm::NOT_AT_MAXIMUM.number);
159 double const dx0 = sx / d2x;
160 double const dy0 = sy / d2y;
162 if (fabs(dx0) > 10.0 || fabs(dy0) > 10.0) {
165 SdssCentroidAlgorithm::ALMOST_NO_SECOND_DERIVATIVE.doc +
166 (
boost::format(
": sx, d2x, sy, d2y = %f %f %f %f") % sx % d2x % sy % d2y).
str(),
167 SdssCentroidAlgorithm::ALMOST_NO_SECOND_DERIVATIVE.number);
170 double vpk = im(0, 0) + 0.5 * (sx * dx0 + sy * dy0);
177 float m0x = 0, m1x = 0, m2x = 0;
178 float m0y = 0, m1y = 0, m2y = 0;
181 quarticBad += inter4(im(-1, -1), im(0, -1), im(1, -1), &m0x);
182 quarticBad += inter4(im(-1, 0), im(0, 0), im(1, 0), &m1x);
183 quarticBad += inter4(im(-1, 1), im(0, 1), im(1, 1), &m2x);
185 quarticBad += inter4(im(-1, -1), im(-1, 0), im(-1, 1), &m0y);
186 quarticBad += inter4(im(0, -1), im(0, 0), im(0, 1), &m1y);
187 quarticBad += inter4(im(1, -1), im(1, 0), im(1, 1), &m2y);
190 double sigmaX2, sigmaY2;
198 double const smx = 0.5 * (m2x - m0x);
199 double const smy = 0.5 * (m2y - m0y);
200 double const dm2x = m1x - 0.5 * (m0x + m2x);
201 double const dm2y = m1y - 0.5 * (m0y + m2y);
202 double const dx = m1x + dy0 * (smx - dy0 * dm2x);
203 double const dy = m1y + dx0 * (smy - dx0 * dm2y);
204 double const dx4 = m1x + dy * (smx - dy * dm2x);
205 double const dy4 = m1y + dx * (smy - dx * dm2y);
209 sigmaX2 = vpk / d2x - (1 + 6 * dx0 * dx0) / 4;
210 sigmaY2 = vpk / d2y - (1 + 6 * dy0 * dy0) / 4;
215 float tauX2 = sigmaX2;
216 float tauY2 = sigmaY2;
217 tauX2 -= smoothingSigma * smoothingSigma;
218 tauY2 -= smoothingSigma * smoothingSigma;
220 if (tauX2 <= smoothingSigma * smoothingSigma) {
221 tauX2 = smoothingSigma * smoothingSigma;
223 if (tauY2 <= smoothingSigma * smoothingSigma) {
224 tauY2 = smoothingSigma * smoothingSigma;
227 float const skyVar = (vim(-1, -1) + vim(0, -1) + vim(1, -1) + vim(-1, 0) + vim(1, 0) + vim(-1, 1) +
228 vim(0, 1) + vim(1, 1)) /
230 float const sourceVar = vim(0, 0);
231 float const A = vpk * sqrt((sigmaX2 / tauX2) * (sigmaY2 / tauY2));
236 *dxc = astrom_errors(skyVar, sourceVar, A, tauX2, vpk, sx, d2x, fabs(smoothingSigma), quarticBad);
237 *dyc = astrom_errors(skyVar, sourceVar, A, tauY2, vpk, sy, d2y, fabs(smoothingSigma), quarticBad);
243 template <
typename MaskedImageXy_locatorT>
244 void doMeasureCentroidImpl(
double *xCenter,
248 double *sizeX2,
double *sizeY2,
250 MaskedImageXy_locatorT mim,
251 double smoothingSigma,
256 double const d2x = 2 * mim.image(0, 0) - mim.image(-1, 0) - mim.image(1, 0);
257 double const d2y = 2 * mim.image(0, 0) - mim.image(0, -1) - mim.image(0, 1);
258 double const sx = 0.5 * (mim.image(1, 0) - mim.image(-1, 0));
259 double const sy = 0.5 * (mim.image(0, 1) - mim.image(0, -1));
261 if (d2x == 0.0 || d2y == 0.0) {
263 SdssCentroidAlgorithm::NO_SECOND_DERIVATIVE.number);
265 if ((!negative && (d2x < 0.0 || d2y < 0.0)) || (negative && (d2x > 0.0 || d2y > 0.0))) {
267 SdssCentroidAlgorithm::NOT_AT_MAXIMUM.doc +
269 SdssCentroidAlgorithm::NOT_AT_MAXIMUM.number);
272 double const dx0 = sx / d2x;
273 double const dy0 = sy / d2y;
275 if (fabs(dx0) > 10.0 || fabs(dy0) > 10.0) {
278 SdssCentroidAlgorithm::NO_SECOND_DERIVATIVE.doc +
279 (
boost::format(
": sx, d2x, sy, d2y = %f %f %f %f") % sx % d2x % sy % d2y).
str(),
280 SdssCentroidAlgorithm::ALMOST_NO_SECOND_DERIVATIVE.number);
283 double vpk = mim.image(0, 0) + 0.5 * (sx * dx0 + sy * dy0);
290 float m0x = 0, m1x = 0, m2x = 0;
291 float m0y = 0, m1y = 0, m2y = 0;
294 quarticBad += inter4(mim.image(-1, -1), mim.image(0, -1), mim.image(1, -1), &m0x, negative);
295 quarticBad += inter4(mim.image(-1, 0), mim.image(0, 0), mim.image(1, 0), &m1x, negative);
296 quarticBad += inter4(mim.image(-1, 1), mim.image(0, 1), mim.image(1, 1), &m2x, negative);
298 quarticBad += inter4(mim.image(-1, -1), mim.image(-1, 0), mim.image(-1, 1), &m0y, negative);
299 quarticBad += inter4(mim.image(0, -1), mim.image(0, 0), mim.image(0, 1), &m1y, negative);
300 quarticBad += inter4(mim.image(1, -1), mim.image(1, 0), mim.image(1, 1), &m2y, negative);
303 double sigmaX2, sigmaY2;
311 double const smx = 0.5 * (m2x - m0x);
312 double const smy = 0.5 * (m2y - m0y);
313 double const dm2x = m1x - 0.5 * (m0x + m2x);
314 double const dm2y = m1y - 0.5 * (m0y + m2y);
315 double const dx = m1x + dy0 * (smx - dy0 * dm2x);
316 double const dy = m1y + dx0 * (smy - dx0 * dm2y);
317 double const dx4 = m1x + dy * (smx - dy * dm2x);
318 double const dy4 = m1y + dx * (smy - dx * dm2y);
322 sigmaX2 = vpk / d2x - (1 + 6 * dx0 * dx0) / 4;
323 sigmaY2 = vpk / d2y - (1 + 6 * dy0 * dy0) / 4;
328 float tauX2 = sigmaX2;
329 float tauY2 = sigmaY2;
330 tauX2 -= smoothingSigma * smoothingSigma;
331 tauY2 -= smoothingSigma * smoothingSigma;
333 if (tauX2 <= smoothingSigma * smoothingSigma) {
334 tauX2 = smoothingSigma * smoothingSigma;
336 if (tauY2 <= smoothingSigma * smoothingSigma) {
337 tauY2 = smoothingSigma * smoothingSigma;
341 (mim.variance(-1, -1) + mim.variance(0, -1) + mim.variance(1, -1) + mim.variance(-1, 0) +
342 mim.variance(1, 0) + mim.variance(-1, 1) + mim.variance(0, 1) + mim.variance(1, 1)) /
344 float const sourceVar = mim.variance(0, 0);
345 float const A = vpk * sqrt((sigmaX2 / tauX2) * (sigmaY2 / tauY2));
350 *dxc = astrom_errors(skyVar, sourceVar, A, tauX2, vpk, sx, d2x, fabs(smoothingSigma), quarticBad);
351 *dyc = astrom_errors(skyVar, sourceVar, A, tauY2, vpk, sy, d2y, fabs(smoothingSigma), quarticBad);
359 template <
typename MaskedImageT>
361 const int y, MaskedImageT
const &mimage,
int binX,
int binY,
363 geom::Point2D const center(x + mimage.getX0(), y + mimage.getY0());
367 double const nEffective = psf->computeEffectiveArea();
369 double const nEffective = 4 *
M_PI * smoothingSigma * smoothingSigma;
373 int const kWidth = kernel->getWidth();
374 int const kHeight = kernel->getHeight();
377 geom::ExtentI(binX * (3 + kWidth + 1), binY * (3 + kHeight + 1)));
380 PTR(MaskedImageT) subImage;
385 SdssCentroidAlgorithm::EDGE.number);
388 binnedImage->setXY0(subImage->getXY0());
390 MaskedImageT smoothedImage = MaskedImageT(*binnedImage,
true);
391 assert(smoothedImage.getWidth() / 2 == kWidth / 2 + 2);
392 assert(smoothedImage.getHeight() / 2 == kHeight / 2 + 2);
395 *smoothedImage.getVariance() *= binX * binY * nEffective;
406 _centroidKey(
CentroidResultKey::addFields(schema, name,
"centroid from Sdss Centroid algorithm",
409 _centroidExtractor(schema, name, true),
410 _centroidChecker(schema, name, ctrl.doFootprintCheck, ctrl.maxDistToPeak) {}
414 geom::Point2D center = _centroidExtractor(measRecord, _flagHandler);
416 result.
x = center.getX();
417 result.
y = center.getY();
418 measRecord.
set(_centroidKey, result);
421 typedef MaskedImageT::Image ImageT;
422 typedef MaskedImageT::Variance VarianceT;
423 bool negative =
false;
425 negative = measRecord.
get(measRecord.
getSchema().
find<afw::table::Flag>(
"flags_negative").
key);
430 ImageT
const &
image = *mimage.getImage();
436 if (!image.getBBox().contains(
geom::Extent2I(x, y) + image.getXY0())) {
448 double xc = 0., yc = 0., dxc = 0., dyc = 0.;
449 for (
int binsize = 1; binsize <= _ctrl.
binmax; binsize *= 2) {
451 smoothAndBinImage(
psf, x, y, mimage, binX, binY, _flagHandler);
452 MaskedImageT
const smoothedImage = result.first;
453 double const smoothingSigma = result.second;
455 MaskedImageT::xy_locator mim =
456 smoothedImage.xy_at(smoothedImage.getWidth() / 2, smoothedImage.getHeight() / 2);
458 double sizeX2, sizeY2;
461 doMeasureCentroidImpl(&xc, &dxc, &yc, &dyc, &sizeX2, &sizeY2, &peakVal, mim, smoothingSigma, negative,
466 xc = (xc + 0.5) * binX - 0.5;
468 sizeX2 *= binX * binX;
470 yc = (yc + 0.5) * binY - 0.5;
472 sizeY2 *= binY * binY;
478 double const fac = _ctrl.
wfac * (1 + smoothingSigma * smoothingSigma);
479 double const facX2 = fac * binX * binX;
480 double const facY2 = fac * binY * binY;
482 if (sizeX2 < facX2 && ::pow(xc - x, 2) < facX2 && sizeY2 < facY2 && ::pow(yc - y, 2) < facY2) {
483 if (binsize > 1 || _ctrl.
peakMin < 0.0 || peakVal > _ctrl.
peakMin) {
488 if (sizeX2 >= facX2 || ::pow(xc - x, 2) >= facX2) {
491 if (sizeY2 >= facY2 || ::pow(yc - y, 2) >= facY2) {
498 result.
xErr = sqrt(dxc * dxc);
499 result.
yErr = sqrt(dyc * dyc);
500 measRecord.
set(_centroidKey, result);
501 _centroidChecker(measRecord);
513 if (flag == SdssCentroidAlgorithm::FAILURE)
continue;
514 if (
mapper.getInputSchema().getNames().count(
mapper.getInputSchema().join(
name, flag.
name)) == 0)
517 mapper.getInputSchema().find<afw::table::Flag>(
name +
"_" + flag.
name).key;
std::size_t size() const
return the current size (number of defined elements) of the collection
An ellipse core with quadrupole moments as parameters.
Defines the fields and offsets for a table.
ErrElement yErr
standard deviation of y
SdssCentroidAlgorithm(Control const &ctrl, std::string const &name, afw::table::Schema &schema)
double indexToPosition(double ind)
Convert image index to image position.
A mapping between the keys of two Schemas, used to copy data between them.
#define CONST_PTR(...)
A shared pointer to a const object.
static FlagDefinitionList const & getFlagDefinitions()
Simple class used to define and document flags The name and doc constitute the identity of the FlagDe...
Only the diagonal elements of the covariance matrix are provided.
Parameters to control convolution.
A reusable struct for centroid measurements.
Reports attempts to exceed implementation-defined length limits for some classes. ...
ErrElement xErr
standard deviation of x
CentroidElement x
x (column) coordinate of the measured position
A C++ control class to handle SdssCentroidAlgorithm's configuration.
std::shared_ptr< math::Kernel const > getLocalKernel(lsst::geom::Point2D position=makeNullPoint(), image::Color color=image::Color()) const
Return a FixedKernel corresponding to the Psf image at the given point.
Provides consistent interface for LSST exceptions.
int binmax
"maximum allowed binning" ;
table::Key< double > sigma2
static FlagDefinition const ALMOST_NO_SECOND_DERIVATIVE
Exception to be thrown when a measurement algorithm experiences a known failure mode.
static FlagDefinition const NOT_AT_MAXIMUM
Field< T >::Value get(Key< T > const &key) const
Return the value of a field for the given key.
Exception to be thrown when a measurement algorithm experiences a fatal error.
Utility class for handling flag fields that indicate the failure modes of an algorithm.
virtual void fail(afw::table::SourceRecord &measRecord, MeasurementError *error=nullptr) const
Handle an exception thrown by the current algorithm by setting flags in the given record...
SchemaItem< T > find(std::string const &name) const
Find a SchemaItem in the Schema by name.
A base class for image defects.
MaskedImageT getMaskedImage()
Return the MaskedImage.
def format(config, name=None, writeSourceLine=True, prefix="", verbose=False)
Schema getSchema() const
Return the Schema that holds this record's fields and keys.
afw::table::Key< double > sigma
void convolve(OutImageT &convolvedImage, InImageT const &inImage, KernelT const &kernel, ConvolutionControl const &convolutionControl=ConvolutionControl())
Convolve an Image or MaskedImage with a Kernel, setting pixels of an existing output image...
static FlagDefinition const EDGE
static FlagDefinition const NO_SECOND_DERIVATIVE
double peakMin
"if the peak's less than this insist on binning at least once" ;
#define LSST_EXCEPT(type,...)
Create an exception with a given type.
double wfac
"fiddle factor for adjusting the binning" ;
std::shared_ptr< lsst::afw::detection::Psf > getPsf()
Return the Exposure's Psf object.
void handleFailure(afw::table::BaseRecord &record, MeasurementError const *error=nullptr) const
Handle an expected or unexpected Exception thrown by a measurement algorithm.
A FunctorKey for CentroidResult.
void set(Key< T > const &key, U const &value)
Set value of a field for the given key.
CentroidElement y
y (row) coordinate of the measured position
Record class that contains measurements made on a single exposure.
virtual void measure(afw::table::SourceRecord &measRecord, afw::image::Exposure< float > const &exposure) const
Called to measure a single child source in an image.
This implements the SdssCentroid algorithm within the meas_base measurement framework.
Backwards-compatibility support for depersisting the old Calib (FluxMag0/FluxMag0Err) objects...
double getDeterminantRadius() const
Return the radius defined as the 4th root of the determinant of the quadrupole matrix.
vector-type utility class to build a collection of FlagDefinitions
A polymorphic base class for representing an image's Point Spread Function.
An integer coordinate rectangle.
static FlagDefinition const FAILURE
double constexpr PI
The ratio of a circle's circumference to diameter.
geom::ellipses::Quadrupole computeShape(lsst::geom::Point2D position=makeNullPoint(), image::Color color=image::Color()) const
Compute the ellipse corresponding to the second moments of the Psf.
std::shared_ptr< ImageT > binImage(ImageT const &inImage, int const binX, int const binY, lsst::afw::math::Property const flags=lsst::afw::math::MEAN)