#include "opencv2/ccalib/omnidir.hpp"
#include "opencv2/core.hpp"
#include "opencv2/imgproc.hpp"
#include "opencv2/highgui.hpp"
#include "opencv2/calib3d.hpp"
#include <vector>
#include <iostream>
#include <string>
#include <time.h>
using namespace cv;
using namespace std;
const char * usage =
"\n example command line for calibrate a pair of omnidirectional camera.\n"
" omni_stereo_calibration -w 8 -h 6 -sw 2.4399 -sh 2.4399 imagelist_left.xml imagelist_right.xml\n"
" \n"
" the file image_list_1.xml and image_list_2.xml generated by imagelist_creator as\n"
"imagelist_creator image_list_1.xml *.*";
static void help()
{
printf("\n This is a sample for omnidirectional camera calibration.\n"
"Usage: omni_calibration\n"
" -w <board_width> # the number of inner corners per one of board dimension\n"
" -h <board_height> # the number of inner corners per another board dimension\n"
" [-sw <square_width>] # the width of square in some user-defined units (1 by default)\n"
" [-sh <square_height>] # the height of square in some user-defined units (1 by default)\n"
" [-o <out_camera_params>] # the output filename for intrinsic [and extrinsic] parameters\n"
" [-fs <fix_skew>] # fix skew\n"
" [-fp ] # fix the principal point at the center\n"
" input_data_1 # input data - text file with a list of the images of the first camera, which is generated by imagelist_creator"
" input_data_2 # input data - text file with a list of the images of the second camera, which is generated by imagelist_creator"
);
printf("\n %s", usage);
}
static void calcChessboardCorners(Size boardSize, double square_width, double square_height,
Mat& corners)
{
// corners has type of CV_64FC3
corners.release();
int n = boardSize.width * boardSize.height;
corners.create(n, 1, CV_64FC3);
Vec3d *ptr = corners.ptr<Vec3d>();
for (int i = 0; i < boardSize.height; ++i)
{
for (int j = 0; j < boardSize.width; ++j)
{
ptr[i*boardSize.width + j] = Vec3d(double(j * square_width), double(i * square_height), 0.0);
}
}
}
static bool detecChessboardCorners(const vector<string>& list1, vector<string>& list_detected_1,
const vector<string>& list2, vector<string>& list_detected_2,
vector<Mat>& image_points_1, vector<Mat>& image_points_2, Size boardSize, Size& imageSize1, Size& imageSize2)
{
image_points_1.resize(0);
image_points_2.resize(0);
list_detected_1.resize(0);
list_detected_2.resize(0);
int n_img = (int)list1.size();
Mat img_l, img_r;
for(int i = 0; i < n_img; ++i)
{
Mat points_1, points_2;
img_l = imread(list1[i], IMREAD_GRAYSCALE);
img_r = imread(list2[i], IMREAD_GRAYSCALE);
bool found_l = findChessboardCorners( img_l, boardSize, points_1);
bool found_r = findChessboardCorners( img_r, boardSize, points_2);
if (found_l && found_r)
{
if (points_1.type() != CV_64FC2)
points_1.convertTo(points_1, CV_64FC2);
if (points_2.type() != CV_64FC2)
points_2.convertTo(points_2, CV_64FC2);
image_points_1.push_back(points_1);
image_points_2.push_back(points_2);
list_detected_1.push_back(list1[i]);
list_detected_2.push_back(list2[i]);
}
}
if (!img_l.empty())
imageSize1 = img_l.size();
if (!img_r.empty())
{
imageSize2 = img_r.size();
}
if (image_points_1.size() < 3)
return false;
else
return true;
}
static bool readStringList( const string& filename, vector<string>& l )
{
l.resize(0);
FileStorage fs(filename, FileStorage::READ);
if( !fs.isOpened() )
return false;
FileNode n = fs.getFirstTopLevelNode();
if( n.type() != FileNode::SEQ )
return false;
FileNodeIterator it = n.begin(), it_end = n.end();
for( ; it != it_end; ++it )
l.push_back((string)*it);
return true;
}
static void saveCameraParams( const string & filename, const int flags, const Mat& cameraMatrix1, const Mat& cameraMatrix2, const Mat& distCoeffs1,
const Mat& disCoeffs2, const double xi1, const double xi2, const Vec3d rvec, const Vec3d tvec,
const vector<Vec3d>& rvecs, const vector<Vec3d>& tvecs, vector<string> detec_list_1, vector<string> detec_list_2,
const Mat& idx, const double rms, const vector<Mat>& imagePoints1, const vector<Mat>& imagePoints2)
{
FileStorage fs( filename, FileStorage::WRITE );
time_t tt;
time( &tt );
struct tm *t2 = localtime( &tt );
char buf[1024];
strftime( buf, sizeof(buf)-1, "%c", t2 );
fs << "calibration_time" << buf;
if ( !rvecs.empty())
fs << "nFrames" << (int)rvecs.size();
if ( flags != 0)
{
sprintf( buf, "flags: %s%s%s%s%s%s%s%s%s",
flags & omnidir::CALIB_USE_GUESS ? "+use_intrinsic_guess" : "",
flags & omnidir::CALIB_FIX_SKEW ? "+fix_skew" : "",
flags & omnidir::CALIB_FIX_K1 ? "+fix_k1" : "",
flags & omnidir::CALIB_FIX_K2 ? "+fix_k2" : "",
flags & omnidir::CALIB_FIX_P1 ? "+fix_p1" : "",
flags & omnidir::CALIB_FIX_P2 ? "+fix_p2" : "",
flags & omnidir::CALIB_FIX_XI ? "+fix_xi" : "",
flags & omnidir::CALIB_FIX_GAMMA ? "+fix_gamma" : "",
flags & omnidir::CALIB_FIX_CENTER ? "+fix_center" : "");
//cvWriteComment( *fs, buf, 0 );
}
fs << "flags" << flags;
fs << "camera_matrix_1" << cameraMatrix1;
fs << "distortion_coefficients_1" << distCoeffs1;
fs << "xi_1" << xi1;
fs << "camera_matrix_2" << cameraMatrix2;
fs << "distortion_coefficients_2" << disCoeffs2;
fs << "xi_2" << xi2;
Mat om_t(1, 6, CV_64F);
Mat(rvec).reshape(1, 1).copyTo(om_t.colRange(0, 3));
Mat(tvec).reshape(1, 1).copyTo(om_t.colRange(3, 6));
//cvWriteComment( *fs, "6-tuples (rotation vector + translation vector) for each view", 0 );
fs << "extrinsic_parameters" << om_t;
if ( !rvecs.empty() && !tvecs.empty() )
{
Mat rvec_tvec((int)rvecs.size(), 6, CV_64F);
for (int i = 0; i < (int)rvecs.size(); ++i)
{
Mat(rvecs[i]).reshape(1, 1).copyTo(rvec_tvec(Rect(0, i, 3, 1)));
Mat(tvecs[i]).reshape(1, 1).copyTo(rvec_tvec(Rect(3, i, 3, 1)));
}
//cvWriteComment( *fs, "a set of 6-tuples (rotation vector + translation vector) for each view", 0 );
fs << "extrinsic_parameters_1" << rvec_tvec;
}
fs << "rms" << rms;
//cvWriteComment( *fs, "names of images that are acturally used in calibration", 0 );
fs << "used_imgs_1" << "[";
for (int i = 0; i < (int)idx.total(); ++i)
{
fs << detec_list_1[(int)idx.at<int>(i)];
}
fs << "]";
fs << "used_imgs_2" << "[";
for (int i = 0; i < (int)idx.total(); ++i)
{
fs << detec_list_2[(int)idx.at<int>(i)];
}
fs << "]";
if ( !imagePoints1.empty() )
{
Mat imageMat((int)imagePoints1.size(), (int)imagePoints1[0].total(), CV_64FC2);
for (int i = 0; i < (int)imagePoints1.size(); ++i)
{
Mat r = imageMat.row(i).reshape(2, imageMat.cols);
Mat imagei(imagePoints1[i]);
imagei.copyTo(r);
}
fs << "image_points_1" << imageMat;
}
if ( !imagePoints2.empty() )
{
Mat imageMat((int)imagePoints2.size(), (int)imagePoints2[0].total(), CV_64FC2);
for (int i = 0; i < (int)imagePoints2.size(); ++i)
{
Mat r = imageMat.row(i).reshape(2, imageMat.cols);
Mat imagei(imagePoints2[i]);
imagei.copyTo(r);
}
fs << "image_points_2" << imageMat;
}
}
int main(int argc, char** argv)
{
Size boardSize, imageSize1, imageSize2;
int flags = 0;
double square_width = 0.0, square_height = 0.0;
const char* outputFilename = "out_camera_params_stereo.xml";
const char* inputFilename1 = 0;
const char* inputFilename2 = 0;
vector<Mat> objectPoints;
vector<Mat> imagePoints1;
vector<Mat> imagePoints2;
if(argc < 2)
{
help();
return 1;
}
bool fist_flag = true;
for(int i = 1; i < argc; i++)
{
const char* s = argv[i];
if( strcmp( s, "-w") == 0)
{
if( sscanf( argv[++i], "%u", &boardSize.width ) != 1 || boardSize.width <= 0 )
return fprintf( stderr, "Invalid board width\n" ), -1;
}
else if( strcmp( s, "-h" ) == 0 )
{
if( sscanf( argv[++i], "%u", &boardSize.height ) != 1 || boardSize.height <= 0 )
return fprintf( stderr, "Invalid board height\n" ), -1;
}
else if( strcmp( s, "-sw" ) == 0 )
{
if( sscanf( argv[++i], "%lf", &square_width ) != 1 || square_width <= 0 )
return fprintf(stderr, "Invalid square width\n"), -1;
}
else if( strcmp( s, "-sh" ) == 0 )
{
if( sscanf( argv[++i], "%lf", &square_height) != 1 || square_height <= 0 )
return fprintf(stderr, "Invalid square height\n"), -1;
}
else if( strcmp( s, "-o" ) == 0 )
{
outputFilename = argv[++i];
}
else if( strcmp( s, "-fs" ) == 0 )
{
flags |= omnidir::CALIB_FIX_SKEW;
}
else if( strcmp( s, "-fp" ) == 0 )
{
flags |= omnidir::CALIB_FIX_CENTER;
}
else if( s[0] != '-' && fist_flag)
{
fist_flag = false;
inputFilename1 = s;
}
else if( s[0] != '-' && !fist_flag)
{
inputFilename2 = s;
}
else
{
return fprintf( stderr, "Unknown option %s\n", s ), -1;
}
}
// get image name list
vector<string> image_list1, detec_list_1, image_list2, detec_list_2;
if((!readStringList(inputFilename1, image_list1)) || (!readStringList(inputFilename2, image_list2)))
return fprintf( stderr, "Failed to read image list\n"), -1;
// find corners in images
// some images may be failed in automatic corner detection, passed cases are in detec_list
if(!detecChessboardCorners(image_list1, detec_list_1, image_list2, detec_list_2,
imagePoints1, imagePoints2, boardSize, imageSize1, imageSize2))
return fprintf(stderr, "Not enough corner detected images\n"), -1;
// calculate object coordinates
Mat object;
calcChessboardCorners(boardSize, square_width, square_height, object);
for(int i = 0; i < (int)detec_list_1.size(); ++i)
{
objectPoints.push_back(object);
}
// run calibration, some images are discarded in calibration process because they are failed
// in initialization. Retained image indexes are in idx variable.
Mat K1, K2, D1, D2, xi1, xi2, idx;
vector<Vec3d> rvecs, tvecs;
Vec3d rvec, tvec;
double _xi1, _xi2, rms;
TermCriteria criteria(3, 200, 1e-8);
rms = omnidir::stereoCalibrate(objectPoints, imagePoints1, imagePoints2, imageSize1, imageSize2, K1, xi1, D1,
K2, xi2, D2, rvec, tvec, rvecs, tvecs, flags, criteria, idx);
_xi1 = xi1.at<double>(0);
_xi2 = xi2.at<double>(0);
saveCameraParams(outputFilename, flags, K1, K2, D1, D2, _xi1, _xi2, rvec, tvec, rvecs, tvecs,
detec_list_1, detec_list_2, idx, rms, imagePoints1, imagePoints2);
}