Here is the function that finds translation and rotation. Generalization to scaling, weighted points, and RANSAC are straight forward. I used openCV library for visualization and SVD. The function below combines data generation, Unit Test , and actual solution.
// rotation and translation in 2D from point correspondences
void rigidTransform2D(const int N) {
// Algorithm: http://igl.ethz.ch/projects/ARAP/svd_rot.pdf
const bool debug = false; // print more debug info
const bool add_noise = true; // add noise to imput and output
srand(time(NULL)); // randomize each time
/*********************************
* Creat data with some noise
**********************************/
// Simulated transformation
Point2f T(1.0f, -2.0f);
float a = 30.0; // [-180, 180], see atan2(y, x)
float noise_level = 0.1f;
cout<<"True parameters: rot = "<<a<<"deg., T = "<<T<<
"; noise level = "<<noise_level<<endl;
// noise
vector<Point2f> noise_src(N), noise_dst(N);
for (int i=0; i<N; i++) {
noise_src[i] = Point2f(randf(noise_level), randf(noise_level));
noise_dst[i] = Point2f(randf(noise_level), randf(noise_level));
}
// create data with noise
vector<Point2f> src(N), dst(N);
float Rdata = 10.0f; // radius of data
float cosa = cos(a*DEG2RAD);
float sina = sin(a*DEG2RAD);
for (int i=0; i<N; i++) {
// src
float x1 = randf(Rdata);
float y1 = randf(Rdata);
src[i] = Point2f(x1,y1);
if (add_noise)
src[i] += noise_src[i];
// dst
float x2 = x1*cosa - y1*sina;
float y2 = x1*sina + y1*cosa;
dst[i] = Point2f(x2,y2) + T;
if (add_noise)
dst[i] += noise_dst[i];
if (debug)
cout<<i<<": "<<src[i]<<"---"<<dst[i]<<endl;
}
// Calculate data centroids
Scalar centroid_src = mean(src);
Scalar centroid_dst = mean(dst);
Point2f center_src(centroid_src[0], centroid_src[1]);
Point2f center_dst(centroid_dst[0], centroid_dst[1]);
if (debug)
cout<<"Centers: "<<center_src<<", "<<center_dst<<endl;
/*********************************
* Visualize data
**********************************/
// Visualization
namedWindow("data", 1);
float w = 400, h = 400;
Mat Mdata(w, h, CV_8UC3); Mdata = Scalar(0);
Point2f center_img(w/2, h/2);
float scl = 0.4*min(w/Rdata, h/Rdata); // compensate for noise
scl/=sqrt(2); // compensate for rotation effect
Point2f dT = (center_src+center_dst)*0.5; // compensate for translation
for (int i=0; i<N; i++) {
Point2f p1(scl*(src[i] - dT));
Point2f p2(scl*(dst[i] - dT));
// invert Y axis
p1.y = -p1.y; p2.y = -p2.y;
// add image center
p1+=center_img; p2+=center_img;
circle(Mdata, p1, 1, Scalar(0, 255, 0));
circle(Mdata, p2, 1, Scalar(0, 0, 255));
line(Mdata, p1, p2, Scalar(100, 100, 100));
}
/*********************************
* Get 2D rotation and translation
**********************************/
markTime();
// subtract centroids from data
for (int i=0; i<N; i++) {
src[i] -= center_src;
dst[i] -= center_dst;
}
// compute a covariance matrix
float Cxx = 0.0, Cxy = 0.0, Cyx = 0.0, Cyy = 0.0;
for (int i=0; i<N; i++) {
Cxx += src[i].x*dst[i].x;
Cxy += src[i].x*dst[i].y;
Cyx += src[i].y*dst[i].x;
Cyy += src[i].y*dst[i].y;
}
Mat Mcov = (Mat_<float>(2, 2)<<Cxx, Cxy, Cyx, Cyy);
if (debug)
cout<<"Covariance Matrix "<<Mcov<<endl;
// SVD
cv::SVD svd;
svd = SVD(Mcov, SVD::FULL_UV);
if (debug) {
cout<<"U = "<<svd.u<<endl;
cout<<"W = "<<svd.w<<endl;
cout<<"V transposed = "<<svd.vt<<endl;
}
// rotation = V*Ut
Mat V = svd.vt.t();
Mat Ut = svd.u.t();
float det_VUt = determinant(V*Ut);
Mat W = (Mat_<float>(2, 2)<<1.0, 0.0, 0.0, det_VUt);
float rot[4];
Mat R_est(2, 2, CV_32F, rot);
R_est = V*W*Ut;
if (debug)
cout<<"Rotation matrix: "<<R_est<<endl;
float cos_est = rot[0];
float sin_est = rot[2];
float ang = atan2(sin_est, cos_est);
// translation = mean_dst - R*mean_src
Point2f center_srcRot = Point2f(
cos_est*center_src.x - sin_est*center_src.y,
sin_est*center_src.x + cos_est*center_src.y);
Point2f T_est = center_dst - center_srcRot;
// RMSE
double RMSE = 0.0;
for (int i=0; i<N; i++) {
Point2f dst_est(
cos_est*src[i].x - sin_est*src[i].y,
sin_est*src[i].x + cos_est*src[i].y);
RMSE += SQR(dst[i].x - dst_est.x) + SQR(dst[i].y - dst_est.y);
}
if (N>0)
RMSE = sqrt(RMSE/N);
// Final estimate msg
cout<<"Estimate = "<<ang*RAD2DEG<<"deg., T = "<<T_est<<"; RMSE = "<<RMSE<<endl;
// show image
printTime(1);
imshow("data", Mdata);
waitKey(-1);
return;
} // rigidTransform2D()
// --------------------------- 3DOF
// calculates squared error from two point mapping; assumes rotation around Origin.
inline float sqErr_3Dof(Point2f p1, Point2f p2,
float cos_alpha, float sin_alpha, Point2f T) {
float x2_est = T.x + cos_alpha * p1.x - sin_alpha * p1.y;
float y2_est = T.y + sin_alpha * p1.x + cos_alpha * p1.y;
Point2f p2_est(x2_est, y2_est);
Point2f dp = p2_est-p2;
float sq_er = dp.dot(dp); // squared distance
//cout<<dp<<endl;
return sq_er;
}
// calculate RMSE for point-to-point metrics
float RMSE_3Dof(const vector<Point2f>& src, const vector<Point2f>& dst,
const float* param, const bool* inliers, const Point2f center) {
const bool all_inliers = (inliers==NULL); // handy when we run QUADRTATIC will all inliers
unsigned int n = src.size();
assert(n>0 && n==dst.size());
float ang_rad = param[0];
Point2f T(param[1], param[2]);
float cos_alpha = cos(ang_rad);
float sin_alpha = sin(ang_rad);
double RMSE = 0.0;
int ninliers = 0;
for (unsigned int i=0; i<n; i++) {
if (all_inliers || inliers[i]) {
RMSE += sqErr_3Dof(src[i]-center, dst[i]-center, cos_alpha, sin_alpha, T);
ninliers++;
}
}
//cout<<"RMSE = "<<RMSE<<endl;
if (ninliers>0)
return sqrt(RMSE/ninliers);
else
return LARGE_NUMBER;
}
// Sets inliers and returns their count
inline int setInliers3Dof(const vector<Point2f>& src, const vector <Point2f>& dst,
bool* inliers,
const float* param,
const float max_er,
const Point2f center) {
float ang_rad = param[0];
Point2f T(param[1], param[2]);
// set inliers
unsigned int ninliers = 0;
unsigned int n = src.size();
assert(n>0 && n==dst.size());
float cos_ang = cos(ang_rad);
float sin_ang = sin(ang_rad);
float max_sqErr = max_er*max_er; // comparing squared values
if (inliers==NULL) {
// just get the number of inliers (e.g. after QUADRATIC fit only)
for (unsigned int i=0; i<n; i++) {
float sqErr = sqErr_3Dof(src[i]-center, dst[i]-center, cos_ang, sin_ang, T);
if ( sqErr < max_sqErr)
ninliers++;
}
} else {
// get the number of inliers and set them (e.g. for RANSAC)
for (unsigned int i=0; i<n; i++) {
float sqErr = sqErr_3Dof(src[i]-center, dst[i]-center, cos_ang, sin_ang, T);
if ( sqErr < max_sqErr) {
inliers[i] = 1;
ninliers++;
} else {
inliers[i] = 0;
}
}
}
return ninliers;
}
// fits 3DOF (rotation and translation in 2D) with least squares.
float fit3DofQUADRATICold(const vector<Point2f>& src, const vector<Point2f>& dst,
float* param, const bool* inliers, const Point2f center) {
const bool all_inliers = (inliers==NULL); // handy when we run QUADRTATIC will all inliers
unsigned int n = src.size();
assert(dst.size() == n);
// count inliers
int ninliers;
if (all_inliers) {
ninliers = n;
} else {
ninliers = 0;
for (unsigned int i=0; i<n; i++){
if (inliers[i])
ninliers++;
}
}
// under-dermined system
if (ninliers<2) {
// param[0] = 0.0f; // ?
// param[1] = 0.0f;
// param[2] = 0.0f;
return LARGE_NUMBER;
}
/*
* x1*cosx(a)-y1*sin(a) + Tx = X1
* x1*sin(a)+y1*cos(a) + Ty = Y1
*
* approximation for small angle a (radians) sin(a)=a, cos(a)=1;
*
* x1*1 - y1*a + Tx = X1
* x1*a + y1*1 + Ty = Y1
*
* in matrix form M1*h=M2
*
* 2n x 4 4 x 1 2n x 1
*
* -y1 1 0 x1 * a = X1
* x1 0 1 y1 Tx Y1
* Ty
* 1=Z
* ----------------------------
* src1 res src2
*/
// 4 x 1
float res_ar[4]; // alpha, Tx, Ty, 1
Mat res(4, 1, CV_32F, res_ar); // 4 x 1
// 2n x 4
Mat src1(2*ninliers, 4, CV_32F); // 2n x 4
// 2n x 1
Mat src2(2*ninliers, 1, CV_32F); // 2n x 1: [X1, Y1, X2, Y2, X3, Y3]'
for (unsigned int i=0, row_cnt = 0; i<n; i++) {
// use inliers only
if (all_inliers || inliers[i]) {
float x = src[i].x - center.x;
float y = src[i].y - center.y;
// first row
// src1
float* rowPtr = src1.ptr<float>(row_cnt);
rowPtr[0] = -y;
rowPtr[1] = 1.0f;
rowPtr[2] = 0.0f;
rowPtr[3] = x;
// src2
src2.at<float> (0, row_cnt) = dst[i].x - center.x;
// second row
row_cnt++;
// src1
rowPtr = src1.ptr<float>(row_cnt);
rowPtr[0] = x;
rowPtr[1] = 0.0f;
rowPtr[2] = 1.0f;
rowPtr[3] = y;
// src2
src2.at<float> (0, row_cnt) = dst[i].y - center.y;
}
}
cv::solve(src1, src2, res, DECOMP_SVD);
// estimators
float alpha_est;
Point2f T_est;
// original
alpha_est = res.at<float>(0, 0);
T_est = Point2f(res.at<float>(1, 0), res.at<float>(2, 0));
float Z = res.at<float>(3, 0);
if (abs(Z-1.0) > 0.1) {
//cout<<"Bad Z in fit3DOF(), Z should be close to 1.0 = "<<Z<<endl;
//return LARGE_NUMBER;
}
param[0] = alpha_est; // rad
param[1] = T_est.x;
param[2] = T_est.y;
// calculate RMSE
float RMSE = RMSE_3Dof(src, dst, param, inliers, center);
return RMSE;
} // fit3DofQUADRATICOLd()
// fits 3DOF (rotation and translation in 2D) with least squares.
float fit3DofQUADRATIC(const vector<Point2f>& src_, const vector<Point2f>& dst_,
float* param, const bool* inliers, const Point2f center) {
const bool debug = false; // print more debug info
const bool all_inliers = (inliers==NULL); // handy when we run QUADRTATIC will all inliers
assert(dst_.size() == src_.size());
int N = src_.size();
// collect inliers
vector<Point2f> src, dst;
int ninliers;
if (all_inliers) {
ninliers = N;
src = src_; // copy constructor
dst = dst_;
} else {
ninliers = 0;
for (int i=0; i<N; i++){
if (inliers[i]) {
ninliers++;
src.push_back(src_[i]);
dst.push_back(dst_[i]
