opencv/modules/gpuoptflow/doc/optflow.rst
Roman Donchenko 6b5ac42a9b Merge remote-tracking branch 'origin/2.4' into merge-2.4
Conflicts:
	modules/calib3d/doc/camera_calibration_and_3d_reconstruction.rst
	modules/features2d/doc/common_interfaces_of_descriptor_extractors.rst
	modules/features2d/doc/object_categorization.rst
	modules/gpu/doc/camera_calibration_and_3d_reconstruction.rst
	modules/gpu/doc/image_filtering.rst
	modules/gpu/doc/image_processing.rst
	modules/gpu/doc/video.rst
	modules/imgproc/doc/miscellaneous_transformations.rst
	modules/imgproc/doc/object_detection.rst
	modules/imgproc/doc/structural_analysis_and_shape_descriptors.rst
	modules/imgproc/src/samplers.cpp
	modules/ml/doc/k_nearest_neighbors.rst
	modules/nonfree/doc/feature_detection.rst
	modules/ocl/include/opencv2/ocl/ocl.hpp
	modules/photo/doc/inpainting.rst
	modules/ts/include/opencv2/ts.hpp
	platforms/scripts/camera_build.conf
	samples/android/camera-calibration/AndroidManifest.xml
2013-08-13 12:56:39 +04:00

230 lines
7.8 KiB
ReStructuredText
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

Optical Flow
============
.. highlight:: cpp
.. note::
* A general optical flow example can be found at opencv_source_code/samples/gpu/optical_flow.cpp
* A general optical flow example using the Nvidia API can be found at opencv_source_code/samples/gpu/opticalflow_nvidia_api.cpp
gpu::BroxOpticalFlow
--------------------
.. ocv:class:: gpu::BroxOpticalFlow
Class computing the optical flow for two images using Brox et al Optical Flow algorithm ([Brox2004]_). ::
class BroxOpticalFlow
{
public:
BroxOpticalFlow(float alpha_, float gamma_, float scale_factor_, int inner_iterations_, int outer_iterations_, int solver_iterations_);
//! Compute optical flow
//! frame0 - source frame (supports only CV_32FC1 type)
//! frame1 - frame to track (with the same size and type as frame0)
//! u - flow horizontal component (along x axis)
//! v - flow vertical component (along y axis)
void operator ()(const GpuMat& frame0, const GpuMat& frame1, GpuMat& u, GpuMat& v, Stream& stream = Stream::Null());
//! flow smoothness
float alpha;
//! gradient constancy importance
float gamma;
//! pyramid scale factor
float scale_factor;
//! number of lagged non-linearity iterations (inner loop)
int inner_iterations;
//! number of warping iterations (number of pyramid levels)
int outer_iterations;
//! number of linear system solver iterations
int solver_iterations;
GpuMat buf;
};
.. note::
* An example illustrating the Brox et al optical flow algorithm can be found at opencv_source_code/samples/gpu/brox_optical_flow.cpp
gpu::FarnebackOpticalFlow
-------------------------
.. ocv:class:: gpu::FarnebackOpticalFlow
Class computing a dense optical flow using the Gunnar Farnebacks algorithm. ::
class CV_EXPORTS FarnebackOpticalFlow
{
public:
FarnebackOpticalFlow()
{
numLevels = 5;
pyrScale = 0.5;
fastPyramids = false;
winSize = 13;
numIters = 10;
polyN = 5;
polySigma = 1.1;
flags = 0;
}
int numLevels;
double pyrScale;
bool fastPyramids;
int winSize;
int numIters;
int polyN;
double polySigma;
int flags;
void operator ()(const GpuMat &frame0, const GpuMat &frame1, GpuMat &flowx, GpuMat &flowy, Stream &s = Stream::Null());
void releaseMemory();
private:
/* hidden */
};
gpu::FarnebackOpticalFlow::operator ()
--------------------------------------
Computes a dense optical flow using the Gunnar Farnebacks algorithm.
.. ocv:function:: void gpu::FarnebackOpticalFlow::operator ()(const GpuMat &frame0, const GpuMat &frame1, GpuMat &flowx, GpuMat &flowy, Stream &s = Stream::Null())
:param frame0: First 8-bit gray-scale input image
:param frame1: Second 8-bit gray-scale input image
:param flowx: Flow horizontal component
:param flowy: Flow vertical component
:param s: Stream
.. seealso:: :ocv:func:`calcOpticalFlowFarneback`
gpu::FarnebackOpticalFlow::releaseMemory
----------------------------------------
Releases unused auxiliary memory buffers.
.. ocv:function:: void gpu::FarnebackOpticalFlow::releaseMemory()
gpu::PyrLKOpticalFlow
---------------------
.. ocv:class:: gpu::PyrLKOpticalFlow
Class used for calculating an optical flow. ::
class PyrLKOpticalFlow
{
public:
PyrLKOpticalFlow();
void sparse(const GpuMat& prevImg, const GpuMat& nextImg, const GpuMat& prevPts, GpuMat& nextPts,
GpuMat& status, GpuMat* err = 0);
void dense(const GpuMat& prevImg, const GpuMat& nextImg, GpuMat& u, GpuMat& v, GpuMat* err = 0);
Size winSize;
int maxLevel;
int iters;
bool useInitialFlow;
void releaseMemory();
};
The class can calculate an optical flow for a sparse feature set or dense optical flow using the iterative Lucas-Kanade method with pyramids.
.. seealso:: :ocv:func:`calcOpticalFlowPyrLK`
.. note::
* An example of the Lucas Kanade optical flow algorithm can be found at opencv_source_code/samples/gpu/pyrlk_optical_flow.cpp
gpu::PyrLKOpticalFlow::sparse
-----------------------------
Calculate an optical flow for a sparse feature set.
.. ocv:function:: void gpu::PyrLKOpticalFlow::sparse(const GpuMat& prevImg, const GpuMat& nextImg, const GpuMat& prevPts, GpuMat& nextPts, GpuMat& status, GpuMat* err = 0)
:param prevImg: First 8-bit input image (supports both grayscale and color images).
:param nextImg: Second input image of the same size and the same type as ``prevImg`` .
:param prevPts: Vector of 2D points for which the flow needs to be found. It must be one row matrix with CV_32FC2 type.
:param nextPts: Output vector of 2D points (with single-precision floating-point coordinates) containing the calculated new positions of input features in the second image. When ``useInitialFlow`` is true, the vector must have the same size as in the input.
:param status: Output status vector (CV_8UC1 type). Each element of the vector is set to 1 if the flow for the corresponding features has been found. Otherwise, it is set to 0.
:param err: Output vector (CV_32FC1 type) that contains the difference between patches around the original and moved points or min eigen value if ``getMinEigenVals`` is checked. It can be NULL, if not needed.
.. seealso:: :ocv:func:`calcOpticalFlowPyrLK`
gpu::PyrLKOpticalFlow::dense
-----------------------------
Calculate dense optical flow.
.. ocv:function:: void gpu::PyrLKOpticalFlow::dense(const GpuMat& prevImg, const GpuMat& nextImg, GpuMat& u, GpuMat& v, GpuMat* err = 0)
:param prevImg: First 8-bit grayscale input image.
:param nextImg: Second input image of the same size and the same type as ``prevImg`` .
:param u: Horizontal component of the optical flow of the same size as input images, 32-bit floating-point, single-channel
:param v: Vertical component of the optical flow of the same size as input images, 32-bit floating-point, single-channel
:param err: Output vector (CV_32FC1 type) that contains the difference between patches around the original and moved points or min eigen value if ``getMinEigenVals`` is checked. It can be NULL, if not needed.
gpu::PyrLKOpticalFlow::releaseMemory
------------------------------------
Releases inner buffers memory.
.. ocv:function:: void gpu::PyrLKOpticalFlow::releaseMemory()
gpu::interpolateFrames
----------------------
Interpolates frames (images) using provided optical flow (displacement field).
.. ocv:function:: void gpu::interpolateFrames(const GpuMat& frame0, const GpuMat& frame1, const GpuMat& fu, const GpuMat& fv, const GpuMat& bu, const GpuMat& bv, float pos, GpuMat& newFrame, GpuMat& buf, Stream& stream = Stream::Null())
:param frame0: First frame (32-bit floating point images, single channel).
:param frame1: Second frame. Must have the same type and size as ``frame0`` .
:param fu: Forward horizontal displacement.
:param fv: Forward vertical displacement.
:param bu: Backward horizontal displacement.
:param bv: Backward vertical displacement.
:param pos: New frame position.
:param newFrame: Output image.
:param buf: Temporary buffer, will have width x 6*height size, CV_32FC1 type and contain 6 GpuMat: occlusion masks for first frame, occlusion masks for second, interpolated forward horizontal flow, interpolated forward vertical flow, interpolated backward horizontal flow, interpolated backward vertical flow.
:param stream: Stream for the asynchronous version.
.. [Brox2004] T. Brox, A. Bruhn, N. Papenberg, J. Weickert. *High accuracy optical flow estimation based on a theory for warping*. ECCV 2004.