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916ec81d09
opencv/modules/features2d/doc/common_interfaces_of_feature_detectors.rst
Elena Fedotova 916ec81d09 Purpose: updated the feature2d chapter
2011-05-04 19:22:51 +00:00

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Common Interfaces of Feature Detectors
======================================
.. highlight:: cpp
Feature detectors in OpenCV have wrappers with a common interface that enables you to easily switch
between different algorithms solving the same problem. All objects that implement keypoint detectors
inherit the
:ref:`FeatureDetector` interface.
.. index:: KeyPoint
.. KeyPoint:
KeyPoint
--------
.. c:type:: KeyPoint
Data structure for salient point detectors ::
class KeyPoint
{
public:
// the default constructor
KeyPoint() : pt(0,0), size(0), angle(-1), response(0), octave(0),
class_id(-1) {}
// the full constructor
KeyPoint(Point2f _pt, float _size, float _angle=-1,
float _response=0, int _octave=0, int _class_id=-1)
: pt(_pt), size(_size), angle(_angle), response(_response),
octave(_octave), class_id(_class_id) {}
// another form of the full constructor
KeyPoint(float x, float y, float _size, float _angle=-1,
float _response=0, int _octave=0, int _class_id=-1)
: pt(x, y), size(_size), angle(_angle), response(_response),
octave(_octave), class_id(_class_id) {}
// converts vector of keypoints to vector of points
static void convert(const std::vector<KeyPoint>& keypoints,
std::vector<Point2f>& points2f,
const std::vector<int>& keypointIndexes=std::vector<int>());
// converts vector of points to the vector of keypoints, where each
// keypoint is assigned to the same size and the same orientation
static void convert(const std::vector<Point2f>& points2f,
std::vector<KeyPoint>& keypoints,
float size=1, float response=1, int octave=0,
int class_id=-1);
// computes overlap for pair of keypoints;
// overlap is a ratio between area of keypoint regions intersection and
// area of keypoint regions union (now keypoint region is a circle)
static float overlap(const KeyPoint& kp1, const KeyPoint& kp2);
Point2f pt; // coordinates of the keypoints
float size; // diameter of the meaningful keypoint neighborhood
float angle; // computed orientation of the keypoint (-1 if not applicable)
float response; // the response by which the most strong keypoints
// have been selected. Can be used for further sorting
// or subsampling
int octave; // octave (pyramid layer) from which the keypoint has been extracted
int class_id; // object class (if the keypoints need to be clustered by
// an object they belong to)
};
// writes vector of keypoints to the file storage
void write(FileStorage& fs, const string& name, const vector<KeyPoint>& keypoints);
// reads vector of keypoints from the specified file storage node
void read(const FileNode& node, CV_OUT vector<KeyPoint>& keypoints);
..
.. index:: FeatureDetector
.. _FeatureDetector:
FeatureDetector
---------------
.. c:type:: FeatureDetector
Abstract base class for 2D image feature detectors ::
class CV_EXPORTS FeatureDetector
{
public:
virtual ~FeatureDetector();
void detect( const Mat& image, vector<KeyPoint>& keypoints,
const Mat& mask=Mat() ) const;
void detect( const vector<Mat>& images,
vector<vector<KeyPoint> >& keypoints,
const vector<Mat>& masks=vector<Mat>() ) const;
virtual void read(const FileNode&);
virtual void write(FileStorage&) const;
static Ptr<FeatureDetector> create( const string& detectorType );
protected:
...
};
.. index:: FeatureDetector::detect
FeatureDetector::detect
---------------------------
.. c:function:: void FeatureDetector::detect( const Mat\& image, vector<KeyPoint>\& keypoints, const Mat\& mask=Mat() ) const
Detects keypoints in an image (first variant) or image set (second variant).
:param image: Image.
:param keypoints: Detected keypoints.
:param mask: Mask specifying where to look for keypoints (optional). It must be a char matrix with non-zero values in the region of interest.
.. c:function:: void FeatureDetector::detect( const vector<Mat>\& images, vector<vector<KeyPoint> >\& keypoints, const vector<Mat>\& masks=vector<Mat>() ) const
:param images: Image set.
:param keypoints: Collection of keypoints detected in input images. ``keypoints[i]`` is a set of keypoints detected in ``images[i]`` .
:param masks: Masks for each input image specifying where to look for keypoints (optional). ``masks[i]`` is a mask for ``images[i]`` . Each element of the ``masks`` vector must be a char matrix with non-zero values in the region of interest.
.. index:: FeatureDetector::read
FeatureDetector::read
-------------------------
.. c:function:: void FeatureDetector::read( const FileNode\& fn )
Reads a feature detector object from a file node.
:param fn: File node from which the detector is read.
.. index:: FeatureDetector::write
FeatureDetector::write
--------------------------
.. c:function:: void FeatureDetector::write( FileStorage\& fs ) const
Writes a feature detector object to a file storage.
:param fs: File storage where the detector is written.
.. index:: FeatureDetector::create
FeatureDetector::create
---------------------------
.. c:function:: Ptr<FeatureDetector> FeatureDetector::create( const string\& detectorType )
Creates a feature detector of a given type with the default parameters (or using the default constructor).??
:param detectorType: Feature detector type.
The following detector types are supported:
* ``"FAST"`` -- :func:`FastFeatureDetector`
* ``"STAR"`` -- :func:`StarFeatureDetector`
* ``"SIFT"`` -- :func:`SiftFeatureDetector`
* ``"SURF"`` -- :func:`SurfFeatureDetector`
* ``"MSER"`` -- :func:`MserFeatureDetector`
* ``"GFTT"`` -- :func:`GfttFeatureDetector`
* ``"HARRIS"`` -- :func:`HarrisFeatureDetector`
Also a combined format is supported: feature detector adapter name ( ``"Grid"`` --
:func:`GridAdaptedFeatureDetector`, ``"Pyramid"`` --
:func:`PyramidAdaptedFeatureDetector` ) + feature detector name (see above),
for example, ``"GridFAST"``, ``"PyramidSTAR"`` .
.. index:: FastFeatureDetector
.. _FastFeatureDetector:
FastFeatureDetector
-------------------
.. c:type:: FastFeatureDetector
Wrapping class for feature detection using the
:func:`FAST` method ::
class FastFeatureDetector : public FeatureDetector
{
public:
FastFeatureDetector( int threshold=1, bool nonmaxSuppression=true );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: GoodFeaturesToTrackDetector
.. _GoodFeaturesToTrackDetector:
GoodFeaturesToTrackDetector
---------------------------
.. c:type:: GoodFeaturesToTrackDetector
Wrapping class for feature detection using the
:func:`goodFeaturesToTrack` function ::
class GoodFeaturesToTrackDetector : public FeatureDetector
{
public:
class Params
{
public:
Params( int maxCorners=1000, double qualityLevel=0.01,
double minDistance=1., int blockSize=3,
bool useHarrisDetector=false, double k=0.04 );
void read( const FileNode& fn );
void write( FileStorage& fs ) const;
int maxCorners;
double qualityLevel;
double minDistance;
int blockSize;
bool useHarrisDetector;
double k;
};
GoodFeaturesToTrackDetector( const GoodFeaturesToTrackDetector::Params& params=
GoodFeaturesToTrackDetector::Params() );
GoodFeaturesToTrackDetector( int maxCorners, double qualityLevel,
double minDistance, int blockSize=3,
bool useHarrisDetector=false, double k=0.04 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: MserFeatureDetector
.. _MserFeatureDetector:
MserFeatureDetector
-------------------
.. c:type:: MserFeatureDetector
Wrapping class for feature detection using the
:func:`MSER` class ::
class MserFeatureDetector : public FeatureDetector
{
public:
MserFeatureDetector( CvMSERParams params=cvMSERParams() );
MserFeatureDetector( int delta, int minArea, int maxArea,
double maxVariation, double minDiversity,
int maxEvolution, double areaThreshold,
double minMargin, int edgeBlurSize );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: StarFeatureDetector
.. _StarFeatureDetector:
StarFeatureDetector
-------------------
.. c:type:: StarFeatureDetector
Wrapping class for feature detection using the
:func:`StarDetector` class ::
class StarFeatureDetector : public FeatureDetector
{
public:
StarFeatureDetector( int maxSize=16, int responseThreshold=30,
int lineThresholdProjected = 10,
int lineThresholdBinarized=8, int suppressNonmaxSize=5 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: SiftFeatureDetector
.. _SiftFeatureDetector:
SiftFeatureDetector
-------------------
.. c:type:: SiftFeatureDetector
Wrapping class for feature detection using the
:func:`SIFT` class ::
class SiftFeatureDetector : public FeatureDetector
{
public:
SiftFeatureDetector(
const SIFT::DetectorParams& detectorParams=SIFT::DetectorParams(),
const SIFT::CommonParams& commonParams=SIFT::CommonParams() );
SiftFeatureDetector( double threshold, double edgeThreshold,
int nOctaves=SIFT::CommonParams::DEFAULT_NOCTAVES,
int nOctaveLayers=SIFT::CommonParams::DEFAULT_NOCTAVE_LAYERS,
int firstOctave=SIFT::CommonParams::DEFAULT_FIRST_OCTAVE,
int angleMode=SIFT::CommonParams::FIRST_ANGLE );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: SurfFeatureDetector
.. _SurfFeatureDetector:
SurfFeatureDetector
-------------------
.. c:type:: SurfFeatureDetector
Wrapping class for feature detection using the
:func:`SURF` class ::
class SurfFeatureDetector : public FeatureDetector
{
public:
SurfFeatureDetector( double hessianThreshold = 400., int octaves = 3,
int octaveLayers = 4 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: GridAdaptedFeatureDetector
.. _GridAdaptedFeatureDetector:
GridAdaptedFeatureDetector
--------------------------
.. c:type:: GridAdaptedFeatureDetector
Class adapting a detector to partition the source image into a grid and detect points in each cell ::
class GridAdaptedFeatureDetector : public FeatureDetector
{
public:
/*
* detector Detector that will be adapted.
* maxTotalKeypoints Maximum count of keypoints detected on the image.
* Only the strongest keypoints will be kept.
* gridRows Grid row count.
* gridCols Grid column count.
*/
GridAdaptedFeatureDetector( const Ptr<FeatureDetector>& detector,
int maxTotalKeypoints, int gridRows=4,
int gridCols=4 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: PyramidAdaptedFeatureDetector
.. _PyramidAdaptedFeatureDetector:
PyramidAdaptedFeatureDetector
-----------------------------
.. c:type:: PyramidAdaptedFeatureDetector
Class adapting a detector to detect points over multiple levels of a Gaussian pyramid. Consider using this class for detectors that are not inherently scaled. ::
class PyramidAdaptedFeatureDetector : public FeatureDetector
{
public:
PyramidAdaptedFeatureDetector( const Ptr<FeatureDetector>& detector,
int levels=2 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: DynamicAdaptedFeatureDetector
DynamicAdaptedFeatureDetector
-----------------------------
.. c:type:: DynamicAdaptedFeatureDetector
Adaptively adjusting detector that iteratively detects features until the desired number is found ::
class DynamicAdaptedFeatureDetector: public FeatureDetector
{
public:
DynamicAdaptedFeatureDetector( const Ptr<AdjusterAdapter>& adjaster,
int min_features=400, int max_features=500, int max_iters=5 );
...
};
If the detector is persisted, it will "remember" the parameters
used for the last detection. In this case, the detector may be used for consistent numbers
of keypoints in a set of temporally related images, such as video streams or
panorama series.
``DynamicAdaptedFeatureDetector`` uses another detector such as FAST or SURF to do the dirty work,
with the help of ``AdjusterAdapter`` .
If the detected number of features is not enough,??
``AdjusterAdapter`` adjusts the detection parameters so that the next detection
results in more or less features. This is repeated until either the number of desired features are found
or the parameters are maxed out.
Adapters can be easily implemented for any detector via the
``AdjusterAdapter`` interface.
Beware that this is not thread-safe since the adjustment of parameters breaks the const??
of the detection routine.
Here is a sample of how to create ``DynamicAdaptedFeatureDetector`` : ::
//sample usage:
//will create a detector that attempts to find
//100 - 110 FAST Keypoints, and will at most run
//FAST feature detection 10 times until that
//number of keypoints are found
Ptr<FeatureDetector> detector(new DynamicAdaptedFeatureDetector (100, 110, 10,
new FastAdjuster(20,true)));
.. index:: DynamicAdaptedFeatureDetector::DynamicAdaptedFeatureDetector
DynamicAdaptedFeatureDetector::DynamicAdaptedFeatureDetector
----------------------------------------------------------------
.. c:function:: DynamicAdaptedFeatureDetector::DynamicAdaptedFeatureDetector( const Ptr<AdjusterAdapter>\& adjaster, int min_features, int max_features, int max_iters )
``DynamicAdaptedFeatureDetector`` constructor
:param adjaster: :func:`AdjusterAdapter` that detects features and adjusts parameters.??parameter formatting is broken here
:param min_features: Minimum desired number features.
:param max_features: Maximum desired number of features.
:param max_iters: Maximum number of times to try adjusting the feature detector parameters. For :func:`FastAdjuster` , this number can be high, but with ``Star`` or ``Surf`` , many iterations can be time-comsuming. At each iteration the detector is rerun.
.. index:: AdjusterAdapter
AdjusterAdapter
---------------
.. c:type:: AdjusterAdapter
Class providing an interface for adjusting parameters of a feature detector. This interface is used by :func:`DynamicAdaptedFeatureDetector` . It is a wrapper for :func:`FeatureDetector` that enables adjusting parameters after detection.?? ::
class AdjusterAdapter: public FeatureDetector
{
public:
virtual ~AdjusterAdapter() {}
virtual void tooFew(int min, int n_detected) = 0;
virtual void tooMany(int max, int n_detected) = 0;
virtual bool good() const = 0;
};
See
:func:`FastAdjuster`,
:func:`StarAdjuster`,
:func:`SurfAdjuster` for concrete implementations.
.. index:: AdjusterAdapter::tooFew
AdjusterAdapter::tooFew
---------------------------
.. c:function:: virtual void tooFew(int min, int n_detected) = 0
Adjusts the detector parameters to detect more features.
:param min: Minimum desired number of features.
:param n_detected: Number of features detected during the latest run.
Example: ::
void FastAdjuster::tooFew(int min, int n_detected)
{
thresh_--;
}
.. index:: AdjusterAdapter::tooMany
AdjusterAdapter::tooMany
----------------------------
.. c:function:: virtual void tooMany(int max, int n_detected) = 0
Adjusts the detector parameters detect less features.
:param max: Maximum desired number of features.
:param n_detected: Number of features detected during the latest run.
Example: ::
void FastAdjuster::tooMany(int min, int n_detected)
{
thresh_++;
}
.. index:: AdjusterAdapter::good
AdjusterAdapter::good
-------------------------
.. c:function:: virtual bool good() const = 0
Returns false if the detector parameters cannot be adjusted any more.
Example: ::
bool FastAdjuster::good() const
{
return (thresh_ > 1) && (thresh_ < 200);
}
.. index:: FastAdjuster
FastAdjuster
------------
.. c:type:: FastAdjuster
:func:`AdjusterAdapter` for :func:`FastFeatureDetector`. This class decrements or increments the threshhold by 1.?? ::
class FastAdjuster FastAdjuster: public AdjusterAdapter
{
public:
FastAdjuster(int init_thresh = 20, bool nonmax = true);
...
};
.. index:: StarAdjuster
StarAdjuster
------------
.. c:type:: StarAdjuster
:func:`AdjusterAdapter` for :func:`StarFeatureDetector` . This class adjusts the ``responseThreshhold`` of ``StarFeatureDetector`` . ::
class StarAdjuster: public AdjusterAdapter
{
StarAdjuster(double initial_thresh = 30.0);
...
};
.. index:: SurfAdjuster
SurfAdjuster
------------
.. c:type:: SurfAdjuster
:func:`AdjusterAdapter` for :func:`SurfFeatureDetector` . This class adjusts the ``hessianThreshold`` of ``SurfFeatureDetector`` . ::
class SurfAdjuster: public SurfAdjuster
{
SurfAdjuster();
...
};
.. index:: FeatureDetector
FeatureDetector
---------------
.. c:type:: FeatureDetector
Abstract base class for 2D image feature detectors ::
class CV_EXPORTS FeatureDetector
{
public:
virtual ~FeatureDetector();
void detect( const Mat& image, vector<KeyPoint>& keypoints,
const Mat& mask=Mat() ) const;
void detect( const vector<Mat>& images,
vector<vector<KeyPoint> >& keypoints,
const vector<Mat>& masks=vector<Mat>() ) const;
virtual void read(const FileNode&);
virtual void write(FileStorage&) const;
static Ptr<FeatureDetector> create( const string& detectorType );
protected:
...
};
.. index:: FeatureDetector::detect
FeatureDetector::detect
---------------------------
.. c:function:: void FeatureDetector::detect( const Mat\& image, vector<KeyPoint>\& keypoints, const Mat\& mask=Mat() ) const
Detects keypoints in an image (first variant) or image set (second variant).
:param image: Image.
:param keypoints: Detected keypoints.
:param mask: Mask specifying where to look for keypoints (optional). It must be a char matrix
with non-zero values in the region of interest.
.. c:function:: void FeatureDetector::detect( const vector<Mat>\& images, vector<vector<KeyPoint> >\& keypoints, const vector<Mat>\& masks=vector<Mat>() ) const
:param images: Image set.
:param keypoints: Collection of keypoints detected in an input image. ``keypoints[i]`` is a set of keypoints detected in ``images[i]`` .
:param masks: Masks for each input image specifying where to look for keypoints (optional). ``masks[i]`` is a mask for ``images[i]`` .
Each element of ``masks`` vector must be a char matrix with non-zero values in the region of interest.
.. index:: FeatureDetector::read
FeatureDetector::read
-------------------------
.. c:function:: void FeatureDetector::read( const FileNode\& fn )
Reads a feature detector object from a file node.
:param fn: File node from which the detector is read.
.. index:: FeatureDetector::write
FeatureDetector::write
--------------------------
.. c:function:: void FeatureDetector::write( FileStorage\& fs ) const
Writes a feature detector object to a file storage.
:param fs: File storage where the detector is written.
.. index:: FeatureDetector::create
FeatureDetector::create
---------------------------
.. c:function:: Ptr<FeatureDetector> FeatureDetector::create( const string\& detectorType )??
Creates a feature detector of a given type with the default parameters (or using the default constructor).??
:param detectorType: Feature detector type.
Now the following detector types are supported:
* ``"FAST"`` -- :func:`FastFeatureDetector`
* ``"STAR"`` -- :func:`StarFeatureDetector`
* ``"SIFT"`` -- :func:`SiftFeatureDetector`
* ``"SURF"`` -- :func:`SurfFeatureDetector`
* ``"MSER"`` -- :func:`MserFeatureDetector`
* ``"GFTT"`` -- :func:`GfttFeatureDetector`
* ``"HARRIS"`` -- :func:`HarrisFeatureDetector`
A combined format is also supported: feature detector adapter name ( ``"Grid"`` --
:func:`GridAdaptedFeatureDetector` , ``"Pyramid"`` --
:func:`PyramidAdaptedFeatureDetector` ) + feature detector name (see above),
for example, ``"GridFAST"`` , ``"PyramidSTAR"`` .
.. index:: FastFeatureDetector
FastFeatureDetector
-------------------
.. c:type:: FastFeatureDetector
Wrapping class for feature detection using the
:func:`FAST` method ::
class FastFeatureDetector : public FeatureDetector
{
public:
FastFeatureDetector( int threshold=1, bool nonmaxSuppression=true );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: GoodFeaturesToTrackDetector
GoodFeaturesToTrackDetector
---------------------------
.. c:type:: GoodFeaturesToTrackDetector
Wrapping class for feature detection using the :func:`goodFeaturesToTrack` function ::
class GoodFeaturesToTrackDetector : public FeatureDetector
{
public:
class Params
{
public:
Params( int maxCorners=1000, double qualityLevel=0.01,
double minDistance=1., int blockSize=3,
bool useHarrisDetector=false, double k=0.04 );
void read( const FileNode& fn );
void write( FileStorage& fs ) const;
int maxCorners;
double qualityLevel;
double minDistance;
int blockSize;
bool useHarrisDetector;
double k;
};
GoodFeaturesToTrackDetector( const GoodFeaturesToTrackDetector::Params& params=
GoodFeaturesToTrackDetector::Params() );
GoodFeaturesToTrackDetector( int maxCorners, double qualityLevel,
double minDistance, int blockSize=3,
bool useHarrisDetector=false, double k=0.04 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: MserFeatureDetector
MserFeatureDetector
-------------------
.. c:type:: MserFeatureDetector
Wrapping class for feature detection using the :func:`MSER` class ::
class MserFeatureDetector : public FeatureDetector
{
public:
MserFeatureDetector( CvMSERParams params=cvMSERParams() );
MserFeatureDetector( int delta, int minArea, int maxArea,
double maxVariation, double minDiversity,
int maxEvolution, double areaThreshold,
double minMargin, int edgeBlurSize );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: StarFeatureDetector
StarFeatureDetector
-------------------
.. c:type:: StarFeatureDetector
Wrapping class for feature detection using the :func:`StarDetector` class ::
class StarFeatureDetector : public FeatureDetector
{
public:
StarFeatureDetector( int maxSize=16, int responseThreshold=30,
int lineThresholdProjected = 10,
int lineThresholdBinarized=8, int suppressNonmaxSize=5 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: SiftFeatureDetector
SiftFeatureDetector
-------------------
.. c:type:: SiftFeatureDetector
Wrapping class for feature detection using the :func:`SIFT` class ::
class SiftFeatureDetector : public FeatureDetector
{
public:
SiftFeatureDetector(
const SIFT::DetectorParams& detectorParams=SIFT::DetectorParams(),
const SIFT::CommonParams& commonParams=SIFT::CommonParams() );
SiftFeatureDetector( double threshold, double edgeThreshold,
int nOctaves=SIFT::CommonParams::DEFAULT_NOCTAVES,
int nOctaveLayers=SIFT::CommonParams::DEFAULT_NOCTAVE_LAYERS,
int firstOctave=SIFT::CommonParams::DEFAULT_FIRST_OCTAVE,
int angleMode=SIFT::CommonParams::FIRST_ANGLE );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: SurfFeatureDetector
SurfFeatureDetector
-------------------
.. c:type:: SurfFeatureDetector
Wrapping class for feature detection using the :func:`SURF` class ::
class SurfFeatureDetector : public FeatureDetector
{
public:
SurfFeatureDetector( double hessianThreshold = 400., int octaves = 3,
int octaveLayers = 4 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: GridAdaptedFeatureDetector
GridAdaptedFeatureDetector
--------------------------
.. c:type:: GridAdaptedFeatureDetector
Class adapting a detector to partition the source image into a grid and detect points in each cell ::
class GridAdaptedFeatureDetector : public FeatureDetector
{
public:
/*
* detector Detector that will be adapted.
* maxTotalKeypoints Maximum count of keypoints detected on the image.
* Only the strongest keypoints are kept.
* gridRows Grid row count.
* gridCols Grid column count.
*/
GridAdaptedFeatureDetector( const Ptr<FeatureDetector>& detector,
int maxTotalKeypoints, int gridRows=4,
int gridCols=4 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: PyramidAdaptedFeatureDetector
PyramidAdaptedFeatureDetector
-----------------------------
.. c:type:: PyramidAdaptedFeatureDetector
Class adapting a detector to detect points over multiple levels of a Gaussian pyramid. Consider using this class for detectors that are not inherently scaled. ::
class PyramidAdaptedFeatureDetector : public FeatureDetector
{
public:
PyramidAdaptedFeatureDetector( const Ptr<FeatureDetector>& detector,
int levels=2 );
virtual void read( const FileNode& fn );
virtual void write( FileStorage& fs ) const;
protected:
...
};
.. index:: DynamicAdaptedFeatureDetector
DynamicAdaptedFeatureDetector
-----------------------------
.. c:type:: DynamicAdaptedFeatureDetector
Adaptively adjusting detector that iteratively detects features until the desired number is found. ::
class DynamicAdaptedFeatureDetector: public FeatureDetector
{
public:
DynamicAdaptedFeatureDetector( const Ptr<AdjusterAdapter>& adjaster,
int min_features=400, int max_features=500, int max_iters=5 );
...
};
If the detector is persisted, it "remembers" the parameters
used on the last detection. In this case, the detector may be used for consistent numbers
of keypoints in a set of images that are temporally related, such as video streams or
panorama series.
``DynamicAdaptedFeatureDetector`` uses another detector such as FAST or SURF to do the dirty work,
with the help of ``AdjusterAdapter`` .
If the number of detected features is not enough,
``AdjusterAdapter`` adjusts the detection parameters so that the next detection
results in a bigger or smaller number of features. This is repeated until either the number of desired features are found
or the parameters are maxed out.
Adapters can easily be implemented for any detector via the
``AdjusterAdapter`` interface.
Beware that this is not thread safe as the adjustment of parameters breaks the const??
of the detection routine.
Example of creating ``DynamicAdaptedFeatureDetector``: ::
//sample usage:
//will create a detector that attempts to find
//100 - 110 FAST Keypoints, and will at most run
//FAST feature detection 10 times until that
//number of keypoints are found
Ptr<FeatureDetector> detector(new DynamicAdaptedFeatureDetector (100, 110, 10,
new FastAdjuster(20,true)));
.. index:: DynamicAdaptedFeatureDetector::DynamicAdaptedFeatureDetector
DynamicAdaptedFeatureDetector::DynamicAdaptedFeatureDetector
----------------------------------------------------------------
.. c:function:: DynamicAdaptedFeatureDetector::DynamicAdaptedFeatureDetector( const Ptr<AdjusterAdapter>\& adjaster, int min_features, int max_features, int max_iters )
Provides the ``DynamicAdaptedFeatureDetector`` constructor.??
:param adjaster: :func:`AdjusterAdapter` that detects features and adjusts parameters.??formatting issue again
:param min_features: Minimum desired number features.
:param max_features: Maximum desired number of features.
:param max_iters: Maximum number of times to try adjusting the feature detector parameters. For :func:`FastAdjuster` , this number can be high, but with ``Star`` or ``Surf`` , many iterations can be time-consuming. At each iteration the detector is rerun.
.. index:: AdjusterAdapter
AdjusterAdapter
---------------
.. c:type:: AdjusterAdapter
Class providing an interface for adjusting parameters of a feature detector. This interface is used by :func:`DynamicAdaptedFeatureDetector` . It is a wrapper for :func:`FeatureDetector` that enables adjusting parameters after detection. ::
class AdjusterAdapter: public FeatureDetector
{
public:
virtual ~AdjusterAdapter() {}
virtual void tooFew(int min, int n_detected) = 0;
virtual void tooMany(int max, int n_detected) = 0;
virtual bool good() const = 0;
};
See
:func:`FastAdjuster`,
:func:`StarAdjuster`,
:func:`SurfAdjuster` for concrete implementations.
.. index:: AdjusterAdapter::tooFew
AdjusterAdapter::tooFew
---------------------------
.. c:function:: virtual void tooFew(int min, int n_detected) = 0
Adjusts the detector parameters to detect more features.
:param min: Minimum desired number of features.
:param n_detected: Number of features detected during the latest run.
Example: ::
void FastAdjuster::tooFew(int min, int n_detected)
{
thresh_--;
}
.. index:: AdjusterAdapter::tooMany
AdjusterAdapter::tooMany
----------------------------
.. c:function:: virtual void tooMany(int max, int n_detected) = 0
Too many features were detected so, adjust the detector parameters accordingly - so that the next detection detects less features.
:param max: This maximum desired number features.
:param n_detected: The actual number detected last run.
An example implementation of this is ::
void FastAdjuster::tooMany(int min, int n_detected)
{
thresh_++;
}
.. index:: AdjusterAdapter::good
AdjusterAdapter::good
-------------------------
.. c:function:: virtual bool good() const = 0
Are params maxed out or still valid? Returns false if the parameters can't be adjusted any more. An example implementation of this is ::
bool FastAdjuster::good() const
{
return (thresh > 1) && (thresh < 200);
}
.. index:: FastAdjuster
FastAdjuster
------------
.. c:type:: FastAdjuster
:func:`AdjusterAdapter` for the :func:`FastFeatureDetector`. This will basically decrement or increment the threshhold by 1 ::
class FastAdjuster FastAdjuster: public AdjusterAdapter
{
public:
FastAdjuster(int init_thresh = 20, bool nonmax = true);
...
};
.. index:: StarAdjuster
StarAdjuster
------------
.. c:type:: StarAdjuster
:func:`AdjusterAdapter` for the :func:`StarFeatureDetector` . This adjusts the responseThreshhold of StarFeatureDetector. ::
class StarAdjuster: public AdjusterAdapter
{
StarAdjuster(double initial_thresh = 30.0);
...
};
.. index:: SurfAdjuster
SurfAdjuster
------------
.. c:type:: SurfAdjuster
:func:`AdjusterAdapter` for the :func:`SurfFeatureDetector` . This adjusts the hessianThreshold of SurfFeatureDetector. ::
class SurfAdjuster: public SurfAdjuster
{
SurfAdjuster();
...
};
..
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