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e805a55a5b
Found via `codespell`
694 lines
25 KiB
C++
694 lines
25 KiB
C++
/*M///////////////////////////////////////////////////////////////////////////////////////
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//
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// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
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//
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// By downloading, copying, installing or using the software you agree to this license.
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// If you do not agree to this license, do not download, install,
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// copy or use the software.
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//
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//
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// License Agreement
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// For Open Source Computer Vision Library
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//
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// Copyright (C) 2000-2008, Intel Corporation, all rights reserved.
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// Copyright (C) 2009-2011, Willow Garage Inc., all rights reserved.
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// Third party copyrights are property of their respective owners.
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//
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// Redistribution and use in source and binary forms, with or without modification,
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// are permitted provided that the following conditions are met:
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//
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// * Redistribution's of source code must retain the above copyright notice,
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// this list of conditions and the following disclaimer.
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//
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// * Redistribution's in binary form must reproduce the above copyright notice,
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// this list of conditions and the following disclaimer in the documentation
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// and/or other materials provided with the distribution.
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//
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// * The name of the copyright holders may not be used to endorse or promote products
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// derived from this software without specific prior written permission.
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//
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// This software is provided by the copyright holders and contributors "as is" and
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// any express or implied warranties, including, but not limited to, the implied
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// warranties of merchantability and fitness for a particular purpose are disclaimed.
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// In no event shall the Intel Corporation or contributors be liable for any direct,
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// indirect, incidental, special, exemplary, or consequential damages
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// (including, but not limited to, procurement of substitute goods or services;
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// loss of use, data, or profits; or business interruption) however caused
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// and on any theory of liability, whether in contract, strict liability,
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// or tort (including negligence or otherwise) arising in any way out of
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// the use of this software, even if advised of the possibility of such damage.
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//
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//M*/
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#include "test_precomp.hpp"
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#include "opencv2/ts/cuda_test.hpp" // EXPECT_MAT_NEAR
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namespace opencv_test { namespace {
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#define NUM_DIST_COEFF_TILT 14
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/**
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Some conventions:
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- the first camera determines the world coordinate system
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- y points down, hence top means minimal y value (negative) and
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bottom means maximal y value (positive)
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- the field of view plane is tilted around x such that it
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intersects the xy-plane in a line with a large (positive)
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y-value
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- image sensor and object are both modelled in the halfspace
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z > 0
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**/
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class cameraCalibrationTiltTest : public ::testing::Test {
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protected:
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cameraCalibrationTiltTest()
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: m_toRadian(acos(-1.0)/180.0)
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, m_toDegree(180.0/acos(-1.0))
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{}
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virtual void SetUp();
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protected:
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static const cv::Size m_imageSize;
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static const double m_pixelSize;
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static const double m_circleConfusionPixel;
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static const double m_lensFocalLength;
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static const double m_lensFNumber;
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static const double m_objectDistance;
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static const double m_planeTiltDegree;
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static const double m_pointTargetDist;
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static const int m_pointTargetNum;
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/** image distance corresponding to working distance */
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double m_imageDistance;
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/** image tilt angle corresponding to the tilt of the object plane */
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double m_imageTiltDegree;
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/** center of the field of view, near and far plane */
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std::vector<cv::Vec3d> m_fovCenter;
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/** normal of the field of view, near and far plane */
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std::vector<cv::Vec3d> m_fovNormal;
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/** points on a plane calibration target */
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std::vector<cv::Point3d> m_pointTarget;
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/** rotations for the calibration target */
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std::vector<cv::Vec3d> m_pointTargetRvec;
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/** translations for the calibration target */
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std::vector<cv::Vec3d> m_pointTargetTvec;
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/** camera matrix */
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cv::Matx33d m_cameraMatrix;
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/** distortion coefficients */
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cv::Vec<double, NUM_DIST_COEFF_TILT> m_distortionCoeff;
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/** random generator */
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cv::RNG m_rng;
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/** degree to radian conversion factor */
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const double m_toRadian;
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/** radian to degree conversion factor */
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const double m_toDegree;
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/**
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computes for a given distance of an image or object point
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the distance of the corresponding object or image point
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*/
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double opticalMap(double dist) {
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return m_lensFocalLength*dist/(dist - m_lensFocalLength);
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}
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/** magnification of the optical map */
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double magnification(double dist) {
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return m_lensFocalLength/(dist - m_lensFocalLength);
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}
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/**
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Changes given distortion coefficients randomly by adding
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a uniformly distributed random variable in [-max max]
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\param coeff input
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\param max limits for the random variables
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*/
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void randomDistortionCoeff(
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cv::Vec<double, NUM_DIST_COEFF_TILT>& coeff,
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const cv::Vec<double, NUM_DIST_COEFF_TILT>& max)
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{
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for (int i = 0; i < coeff.rows; ++i)
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coeff(i) += m_rng.uniform(-max(i), max(i));
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}
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/** numerical jacobian */
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void numericalDerivative(
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cv::Mat& jac,
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double eps,
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const std::vector<cv::Point3d>& obj,
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const cv::Vec3d& rvec,
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const cv::Vec3d& tvec,
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const cv::Matx33d& camera,
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const cv::Vec<double, NUM_DIST_COEFF_TILT>& distor);
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/** remove points with projection outside the sensor array */
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void removeInvalidPoints(
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std::vector<cv::Point2d>& imagePoints,
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std::vector<cv::Point3d>& objectPoints);
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/** add uniform distribute noise in [-halfWidthNoise, halfWidthNoise]
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to the image points and remove out of range points */
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void addNoiseRemoveInvalidPoints(
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std::vector<cv::Point2f>& imagePoints,
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std::vector<cv::Point3f>& objectPoints,
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std::vector<cv::Point2f>& noisyImagePoints,
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double halfWidthNoise);
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};
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/** Number of Pixel of the sensor */
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const cv::Size cameraCalibrationTiltTest::m_imageSize(1600, 1200);
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/** Size of a pixel in mm */
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const double cameraCalibrationTiltTest::m_pixelSize(.005);
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/** Diameter of the circle of confusion */
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const double cameraCalibrationTiltTest::m_circleConfusionPixel(3);
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/** Focal length of the lens */
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const double cameraCalibrationTiltTest::m_lensFocalLength(16.4);
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/** F-Number */
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const double cameraCalibrationTiltTest::m_lensFNumber(8);
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/** Working distance */
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const double cameraCalibrationTiltTest::m_objectDistance(200);
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/** Angle between optical axis and object plane normal */
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const double cameraCalibrationTiltTest::m_planeTiltDegree(55);
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/** the calibration target are points on a square grid with this side length */
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const double cameraCalibrationTiltTest::m_pointTargetDist(5);
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/** the calibration target has (2*n + 1) x (2*n + 1) points */
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const int cameraCalibrationTiltTest::m_pointTargetNum(15);
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void cameraCalibrationTiltTest::SetUp()
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{
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m_imageDistance = opticalMap(m_objectDistance);
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m_imageTiltDegree = m_toDegree * atan2(
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m_imageDistance * tan(m_toRadian * m_planeTiltDegree),
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m_objectDistance);
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// half sensor height
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double tmp = .5 * (m_imageSize.height - 1) * m_pixelSize
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* cos(m_toRadian * m_imageTiltDegree);
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// y-Value of tilted sensor
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double yImage[2] = {tmp, -tmp};
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// change in z because of the tilt
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tmp *= sin(m_toRadian * m_imageTiltDegree);
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// z-values of the sensor lower and upper corner
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double zImage[2] = {
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m_imageDistance + tmp,
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m_imageDistance - tmp};
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// circle of confusion
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double circleConfusion = m_circleConfusionPixel*m_pixelSize;
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// aperture of the lense
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double aperture = m_lensFocalLength/m_lensFNumber;
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// near and far factor on the image side
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double nearFarFactorImage[2] = {
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aperture/(aperture - circleConfusion),
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aperture/(aperture + circleConfusion)};
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// on the object side - points that determine the field of
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// view
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std::vector<cv::Vec3d> fovBottomTop(6);
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std::vector<cv::Vec3d>::iterator itFov = fovBottomTop.begin();
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for (size_t iBottomTop = 0; iBottomTop < 2; ++iBottomTop)
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{
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// mapping sensor to field of view
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*itFov = cv::Vec3d(0,yImage[iBottomTop],zImage[iBottomTop]);
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*itFov *= magnification((*itFov)(2));
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++itFov;
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for (size_t iNearFar = 0; iNearFar < 2; ++iNearFar, ++itFov)
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{
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// scaling to the near and far distance on the
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// image side
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*itFov = cv::Vec3d(0,yImage[iBottomTop],zImage[iBottomTop]) *
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nearFarFactorImage[iNearFar];
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// scaling to the object side
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*itFov *= magnification((*itFov)(2));
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}
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}
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m_fovCenter.resize(3);
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m_fovNormal.resize(3);
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for (size_t i = 0; i < 3; ++i)
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{
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m_fovCenter[i] = .5*(fovBottomTop[i] + fovBottomTop[i+3]);
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m_fovNormal[i] = fovBottomTop[i+3] - fovBottomTop[i];
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m_fovNormal[i] = cv::normalize(m_fovNormal[i]);
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m_fovNormal[i] = cv::Vec3d(
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m_fovNormal[i](0),
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-m_fovNormal[i](2),
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m_fovNormal[i](1));
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// one target position in each plane
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m_pointTargetTvec.push_back(m_fovCenter[i]);
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cv::Vec3d rvec = cv::Vec3d(0,0,1).cross(m_fovNormal[i]);
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rvec = cv::normalize(rvec);
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rvec *= acos(m_fovNormal[i](2));
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m_pointTargetRvec.push_back(rvec);
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}
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// calibration target
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size_t num = 2*m_pointTargetNum + 1;
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m_pointTarget.resize(num*num);
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std::vector<cv::Point3d>::iterator itTarget = m_pointTarget.begin();
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for (int iY = -m_pointTargetNum; iY <= m_pointTargetNum; ++iY)
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{
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for (int iX = -m_pointTargetNum; iX <= m_pointTargetNum; ++iX, ++itTarget)
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{
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*itTarget = cv::Point3d(iX, iY, 0) * m_pointTargetDist;
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}
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}
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// oblique target positions
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// approximate distance to the near and far plane
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double dist = std::max(
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std::abs(m_fovNormal[0].dot(m_fovCenter[0] - m_fovCenter[1])),
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std::abs(m_fovNormal[0].dot(m_fovCenter[0] - m_fovCenter[2])));
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// maximal angle such that target border "reaches" near and far plane
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double maxAngle = atan2(dist, m_pointTargetNum*m_pointTargetDist);
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std::vector<double> angle;
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angle.push_back(-maxAngle);
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angle.push_back(maxAngle);
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cv::Matx33d baseMatrix;
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cv::Rodrigues(m_pointTargetRvec.front(), baseMatrix);
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for (std::vector<double>::const_iterator itAngle = angle.begin(); itAngle != angle.end(); ++itAngle)
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{
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cv::Matx33d rmat;
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for (int i = 0; i < 2; ++i)
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{
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cv::Vec3d rvec(0,0,0);
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rvec(i) = *itAngle;
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cv::Rodrigues(rvec, rmat);
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rmat = baseMatrix*rmat;
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cv::Rodrigues(rmat, rvec);
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m_pointTargetTvec.push_back(m_fovCenter.front());
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m_pointTargetRvec.push_back(rvec);
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}
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}
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// camera matrix
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double cx = .5 * (m_imageSize.width - 1);
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double cy = .5 * (m_imageSize.height - 1);
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double f = m_imageDistance/m_pixelSize;
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m_cameraMatrix = cv::Matx33d(
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f,0,cx,
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0,f,cy,
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0,0,1);
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// distortion coefficients
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m_distortionCoeff = cv::Vec<double, NUM_DIST_COEFF_TILT>::all(0);
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// tauX
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m_distortionCoeff(12) = -m_toRadian*m_imageTiltDegree;
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}
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void cameraCalibrationTiltTest::numericalDerivative(
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cv::Mat& jac,
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double eps,
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const std::vector<cv::Point3d>& obj,
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const cv::Vec3d& rvec,
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const cv::Vec3d& tvec,
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const cv::Matx33d& camera,
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const cv::Vec<double, NUM_DIST_COEFF_TILT>& distor)
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{
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cv::Vec3d r(rvec);
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cv::Vec3d t(tvec);
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cv::Matx33d cm(camera);
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cv::Vec<double, NUM_DIST_COEFF_TILT> dc(distor);
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double* param[10+NUM_DIST_COEFF_TILT] = {
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&r(0), &r(1), &r(2),
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&t(0), &t(1), &t(2),
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&cm(0,0), &cm(1,1), &cm(0,2), &cm(1,2),
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&dc(0), &dc(1), &dc(2), &dc(3), &dc(4), &dc(5), &dc(6),
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&dc(7), &dc(8), &dc(9), &dc(10), &dc(11), &dc(12), &dc(13)};
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std::vector<cv::Point2d> pix0, pix1;
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double invEps = .5/eps;
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for (int col = 0; col < 10+NUM_DIST_COEFF_TILT; ++col)
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{
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double save = *(param[col]);
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*(param[col]) = save + eps;
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cv::projectPoints(obj, r, t, cm, dc, pix0);
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*(param[col]) = save - eps;
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cv::projectPoints(obj, r, t, cm, dc, pix1);
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*(param[col]) = save;
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std::vector<cv::Point2d>::const_iterator it0 = pix0.begin();
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std::vector<cv::Point2d>::const_iterator it1 = pix1.begin();
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int row = 0;
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for (;it0 != pix0.end(); ++it0, ++it1)
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{
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cv::Point2d d = invEps*(*it0 - *it1);
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jac.at<double>(row, col) = d.x;
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++row;
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jac.at<double>(row, col) = d.y;
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++row;
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}
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}
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}
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void cameraCalibrationTiltTest::removeInvalidPoints(
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std::vector<cv::Point2d>& imagePoints,
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std::vector<cv::Point3d>& objectPoints)
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{
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// remove object and imgage points out of range
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std::vector<cv::Point2d>::iterator itImg = imagePoints.begin();
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std::vector<cv::Point3d>::iterator itObj = objectPoints.begin();
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while (itImg != imagePoints.end())
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{
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bool ok =
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itImg->x >= 0 &&
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itImg->x <= m_imageSize.width - 1.0 &&
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itImg->y >= 0 &&
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itImg->y <= m_imageSize.height - 1.0;
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if (ok)
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{
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++itImg;
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++itObj;
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}
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else
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{
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itImg = imagePoints.erase(itImg);
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itObj = objectPoints.erase(itObj);
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}
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}
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}
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void cameraCalibrationTiltTest::addNoiseRemoveInvalidPoints(
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std::vector<cv::Point2f>& imagePoints,
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std::vector<cv::Point3f>& objectPoints,
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std::vector<cv::Point2f>& noisyImagePoints,
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double halfWidthNoise)
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{
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std::vector<cv::Point2f>::iterator itImg = imagePoints.begin();
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std::vector<cv::Point3f>::iterator itObj = objectPoints.begin();
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noisyImagePoints.clear();
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noisyImagePoints.reserve(imagePoints.size());
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while (itImg != imagePoints.end())
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{
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cv::Point2f pix = *itImg + cv::Point2f(
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(float)m_rng.uniform(-halfWidthNoise, halfWidthNoise),
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(float)m_rng.uniform(-halfWidthNoise, halfWidthNoise));
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bool ok =
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pix.x >= 0 &&
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pix.x <= m_imageSize.width - 1.0 &&
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pix.y >= 0 &&
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pix.y <= m_imageSize.height - 1.0;
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if (ok)
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{
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noisyImagePoints.push_back(pix);
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++itImg;
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++itObj;
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}
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else
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{
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itImg = imagePoints.erase(itImg);
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itObj = objectPoints.erase(itObj);
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}
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}
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}
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TEST_F(cameraCalibrationTiltTest, projectPoints)
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{
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std::vector<cv::Point2d> imagePoints;
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std::vector<cv::Point3d> objectPoints = m_pointTarget;
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cv::Vec3d rvec = m_pointTargetRvec.front();
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cv::Vec3d tvec = m_pointTargetTvec.front();
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cv::Vec<double, NUM_DIST_COEFF_TILT> coeffNoiseHalfWidth(
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.1, .1, // k1 k2
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.01, .01, // p1 p2
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.001, .001, .001, .001, // k3 k4 k5 k6
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.001, .001, .001, .001, // s1 s2 s3 s4
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.01, .01); // tauX tauY
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for (size_t numTest = 0; numTest < 10; ++numTest)
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{
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// create random distortion coefficients
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cv::Vec<double, NUM_DIST_COEFF_TILT> distortionCoeff = m_distortionCoeff;
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randomDistortionCoeff(distortionCoeff, coeffNoiseHalfWidth);
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// projection
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cv::projectPoints(
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objectPoints,
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rvec,
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tvec,
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m_cameraMatrix,
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distortionCoeff,
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imagePoints);
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// remove object and imgage points out of range
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removeInvalidPoints(imagePoints, objectPoints);
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int numPoints = (int)imagePoints.size();
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int numParams = 10 + distortionCoeff.rows;
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cv::Mat jacobian(2*numPoints, numParams, CV_64FC1);
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// projection and jacobian
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cv::projectPoints(
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objectPoints,
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rvec,
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tvec,
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m_cameraMatrix,
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distortionCoeff,
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imagePoints,
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jacobian);
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// numerical derivatives
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cv::Mat numericJacobian(2*numPoints, numParams, CV_64FC1);
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double eps = 1e-7;
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numericalDerivative(
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numericJacobian,
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eps,
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objectPoints,
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rvec,
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tvec,
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m_cameraMatrix,
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distortionCoeff);
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#if 0
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for (size_t row = 0; row < 2; ++row)
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{
|
|
std::cout << "------ Row = " << row << " ------\n";
|
|
for (size_t i = 0; i < 10+NUM_DIST_COEFF_TILT; ++i)
|
|
{
|
|
std::cout << i
|
|
<< " jac = " << jacobian.at<double>(row,i)
|
|
<< " num = " << numericJacobian.at<double>(row,i)
|
|
<< " rel. diff = " << abs(numericJacobian.at<double>(row,i) - jacobian.at<double>(row,i))/abs(numericJacobian.at<double>(row,i))
|
|
<< "\n";
|
|
}
|
|
}
|
|
#endif
|
|
// relative difference for large values (rvec and tvec)
|
|
cv::Mat check = abs(jacobian(cv::Range::all(), cv::Range(0,6)) - numericJacobian(cv::Range::all(), cv::Range(0,6)))/
|
|
(1 + abs(jacobian(cv::Range::all(), cv::Range(0,6))));
|
|
double minVal, maxVal;
|
|
cv::minMaxIdx(check, &minVal, &maxVal);
|
|
EXPECT_LE(maxVal, .01);
|
|
// absolute difference for distortion and camera matrix
|
|
EXPECT_MAT_NEAR(jacobian(cv::Range::all(), cv::Range(6,numParams)), numericJacobian(cv::Range::all(), cv::Range(6,numParams)), 1e-5);
|
|
}
|
|
}
|
|
|
|
TEST_F(cameraCalibrationTiltTest, undistortPoints)
|
|
{
|
|
cv::Vec<double, NUM_DIST_COEFF_TILT> coeffNoiseHalfWidth(
|
|
.2, .1, // k1 k2
|
|
.01, .01, // p1 p2
|
|
.01, .01, .01, .01, // k3 k4 k5 k6
|
|
.001, .001, .001, .001, // s1 s2 s3 s4
|
|
.001, .001); // tauX tauY
|
|
double step = 99;
|
|
double toleranceBackProjection = 1e-5;
|
|
|
|
for (size_t numTest = 0; numTest < 10; ++numTest)
|
|
{
|
|
cv::Vec<double, NUM_DIST_COEFF_TILT> distortionCoeff = m_distortionCoeff;
|
|
randomDistortionCoeff(distortionCoeff, coeffNoiseHalfWidth);
|
|
|
|
// distorted points
|
|
std::vector<cv::Point2d> distorted;
|
|
for (double x = 0; x <= m_imageSize.width-1; x += step)
|
|
for (double y = 0; y <= m_imageSize.height-1; y += step)
|
|
distorted.push_back(cv::Point2d(x,y));
|
|
std::vector<cv::Point2d> normalizedUndistorted;
|
|
|
|
// undistort
|
|
cv::undistortPoints(distorted,
|
|
normalizedUndistorted,
|
|
m_cameraMatrix,
|
|
distortionCoeff);
|
|
|
|
// copy normalized points to 3D
|
|
std::vector<cv::Point3d> objectPoints;
|
|
for (std::vector<cv::Point2d>::const_iterator itPnt = normalizedUndistorted.begin();
|
|
itPnt != normalizedUndistorted.end(); ++itPnt)
|
|
objectPoints.push_back(cv::Point3d(itPnt->x, itPnt->y, 1));
|
|
|
|
// project
|
|
std::vector<cv::Point2d> imagePoints(objectPoints.size());
|
|
cv::projectPoints(objectPoints,
|
|
cv::Vec3d(0,0,0),
|
|
cv::Vec3d(0,0,0),
|
|
m_cameraMatrix,
|
|
distortionCoeff,
|
|
imagePoints);
|
|
|
|
EXPECT_MAT_NEAR(distorted, imagePoints, toleranceBackProjection);
|
|
}
|
|
}
|
|
|
|
template <typename INPUT, typename ESTIMATE>
|
|
void show(const std::string& name, const INPUT in, const ESTIMATE est)
|
|
{
|
|
std::cout << name << " = " << est << " (init = " << in
|
|
<< ", diff = " << est-in << ")\n";
|
|
}
|
|
|
|
template <typename INPUT>
|
|
void showVec(const std::string& name, const INPUT& in, const cv::Mat& est)
|
|
{
|
|
|
|
for (size_t i = 0; i < in.channels; ++i)
|
|
{
|
|
std::stringstream ss;
|
|
ss << name << "[" << i << "]";
|
|
show(ss.str(), in(i), est.at<double>(i));
|
|
}
|
|
}
|
|
|
|
/**
|
|
For given camera matrix and distortion coefficients
|
|
- project point target in different positions onto the sensor
|
|
- add pixel noise
|
|
- estimate camera model with noisy measurements
|
|
- compare result with initial model parameter
|
|
|
|
Parameter are differently affected by the noise
|
|
*/
|
|
TEST_F(cameraCalibrationTiltTest, calibrateCamera)
|
|
{
|
|
cv::Vec<double, NUM_DIST_COEFF_TILT> coeffNoiseHalfWidth(
|
|
.2, .1, // k1 k2
|
|
.01, .01, // p1 p2
|
|
0, 0, 0, 0, // k3 k4 k5 k6
|
|
.001, .001, .001, .001, // s1 s2 s3 s4
|
|
.001, .001); // tauX tauY
|
|
double pixelNoiseHalfWidth = .5;
|
|
std::vector<cv::Point3f> pointTarget;
|
|
pointTarget.reserve(m_pointTarget.size());
|
|
for (std::vector<cv::Point3d>::const_iterator it = m_pointTarget.begin(); it != m_pointTarget.end(); ++it)
|
|
pointTarget.push_back(cv::Point3f(
|
|
(float)(it->x),
|
|
(float)(it->y),
|
|
(float)(it->z)));
|
|
|
|
for (size_t numTest = 0; numTest < 5; ++numTest)
|
|
{
|
|
// create random distortion coefficients
|
|
cv::Vec<double, NUM_DIST_COEFF_TILT> distortionCoeff = m_distortionCoeff;
|
|
randomDistortionCoeff(distortionCoeff, coeffNoiseHalfWidth);
|
|
|
|
// container for calibration data
|
|
std::vector<std::vector<cv::Point3f> > viewsObjectPoints;
|
|
std::vector<std::vector<cv::Point2f> > viewsImagePoints;
|
|
std::vector<std::vector<cv::Point2f> > viewsNoisyImagePoints;
|
|
|
|
// simulate calibration data with projectPoints
|
|
std::vector<cv::Vec3d>::const_iterator itRvec = m_pointTargetRvec.begin();
|
|
std::vector<cv::Vec3d>::const_iterator itTvec = m_pointTargetTvec.begin();
|
|
// loop over different views
|
|
for (;itRvec != m_pointTargetRvec.end(); ++ itRvec, ++itTvec)
|
|
{
|
|
std::vector<cv::Point3f> objectPoints(pointTarget);
|
|
std::vector<cv::Point2f> imagePoints;
|
|
std::vector<cv::Point2f> noisyImagePoints;
|
|
// project calibration target to sensor
|
|
cv::projectPoints(
|
|
objectPoints,
|
|
*itRvec,
|
|
*itTvec,
|
|
m_cameraMatrix,
|
|
distortionCoeff,
|
|
imagePoints);
|
|
// remove invisible points
|
|
addNoiseRemoveInvalidPoints(
|
|
imagePoints,
|
|
objectPoints,
|
|
noisyImagePoints,
|
|
pixelNoiseHalfWidth);
|
|
// add data for view
|
|
viewsNoisyImagePoints.push_back(noisyImagePoints);
|
|
viewsImagePoints.push_back(imagePoints);
|
|
viewsObjectPoints.push_back(objectPoints);
|
|
}
|
|
|
|
// Output
|
|
std::vector<cv::Mat> outRvecs, outTvecs;
|
|
cv::Mat outCameraMatrix(3, 3, CV_64F, cv::Scalar::all(1)), outDistCoeff;
|
|
|
|
// Stopping criteria
|
|
cv::TermCriteria stop(
|
|
cv::TermCriteria::COUNT+cv::TermCriteria::EPS,
|
|
50000,
|
|
1e-14);
|
|
// model choice
|
|
int flag =
|
|
cv::CALIB_FIX_ASPECT_RATIO |
|
|
// cv::CALIB_RATIONAL_MODEL |
|
|
cv::CALIB_FIX_K3 |
|
|
// cv::CALIB_FIX_K6 |
|
|
cv::CALIB_THIN_PRISM_MODEL |
|
|
cv::CALIB_TILTED_MODEL;
|
|
// estimate
|
|
double backProjErr = cv::calibrateCamera(
|
|
viewsObjectPoints,
|
|
viewsNoisyImagePoints,
|
|
m_imageSize,
|
|
outCameraMatrix,
|
|
outDistCoeff,
|
|
outRvecs,
|
|
outTvecs,
|
|
flag,
|
|
stop);
|
|
|
|
EXPECT_LE(backProjErr, pixelNoiseHalfWidth);
|
|
|
|
#if 0
|
|
std::cout << "------ estimate ------\n";
|
|
std::cout << "back projection error = " << backProjErr << "\n";
|
|
std::cout << "points per view = {" << viewsObjectPoints.front().size();
|
|
for (size_t i = 1; i < viewsObjectPoints.size(); ++i)
|
|
std::cout << ", " << viewsObjectPoints[i].size();
|
|
std::cout << "}\n";
|
|
show("fx", m_cameraMatrix(0,0), outCameraMatrix.at<double>(0,0));
|
|
show("fy", m_cameraMatrix(1,1), outCameraMatrix.at<double>(1,1));
|
|
show("cx", m_cameraMatrix(0,2), outCameraMatrix.at<double>(0,2));
|
|
show("cy", m_cameraMatrix(1,2), outCameraMatrix.at<double>(1,2));
|
|
showVec("distor", distortionCoeff, outDistCoeff);
|
|
#endif
|
|
if (pixelNoiseHalfWidth > 0)
|
|
{
|
|
double tolRvec = pixelNoiseHalfWidth;
|
|
double tolTvec = m_objectDistance * tolRvec;
|
|
// back projection error
|
|
for (size_t i = 0; i < viewsNoisyImagePoints.size(); ++i)
|
|
{
|
|
double dRvec = cv::norm(m_pointTargetRvec[i],
|
|
cv::Vec3d(outRvecs[i].at<double>(0), outRvecs[i].at<double>(1), outRvecs[i].at<double>(2))
|
|
);
|
|
EXPECT_LE(dRvec, tolRvec);
|
|
double dTvec = cv::norm(m_pointTargetTvec[i],
|
|
cv::Vec3d(outTvecs[i].at<double>(0), outTvecs[i].at<double>(1), outTvecs[i].at<double>(2))
|
|
);
|
|
EXPECT_LE(dTvec, tolTvec);
|
|
|
|
std::vector<cv::Point2f> backProjection;
|
|
cv::projectPoints(
|
|
viewsObjectPoints[i],
|
|
outRvecs[i],
|
|
outTvecs[i],
|
|
outCameraMatrix,
|
|
outDistCoeff,
|
|
backProjection);
|
|
EXPECT_MAT_NEAR(backProjection, viewsNoisyImagePoints[i], 1.5*pixelNoiseHalfWidth);
|
|
EXPECT_MAT_NEAR(backProjection, viewsImagePoints[i], 1.5*pixelNoiseHalfWidth);
|
|
}
|
|
}
|
|
pixelNoiseHalfWidth *= .25;
|
|
}
|
|
}
|
|
|
|
}} // namespace
|