94 lines
No EOL
3.2 KiB
C++
94 lines
No EOL
3.2 KiB
C++
#pragma once
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#include <cgv/math/fvec.h>
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#include <cgv/math/quaternion.h>
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#include <cgv/math/fmat.h>
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#include <cgv/math/det.h>
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#include <cgv/math/svd.h>
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namespace cgv {
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namespace math {
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/// mean of point set
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template <typename T>
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fvec<T, 3> mean(const std::vector<fvec<T, 3> >& P, T inv_n = T(1) / P.size())
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{
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fvec<T, 3> mu(T(0));
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for (unsigned i = 0; i < P.size(); ++i)
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mu += P[i];
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mu *= inv_n;
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return mu;
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}
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/// svd wrapper
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template <typename T, cgv::type::uint32_type N, cgv::type::uint32_type M>
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void svd(const fmat<T, N, M>& A, fmat<T, N, N>& U, fvec<T, M>& D, fmat<T, M, M>& V_t, bool ordering = true, int maxiter = 30)
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{
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mat<T> _A(N, M, &A(0, 0)), _U, _V;
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diag_mat<T> _D;
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svd(_A, _U, _D, _V, ordering, maxiter);
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U = fmat<T, N, N>(&_U(0, 0));
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cgv::type::uint32_type i, j;
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for (j = 0; j < M; ++j) {
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D(j) = _D(j);
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for (i = 0; i < M; ++i)
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V_t(j, i) = _V(i, j);
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}
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}
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//! compute rigid body transformation and optionally uniform scaling to align source point set to target point set in least squares sense
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/*! Given source points X and target points Y find orthogonal matrix O\in O(3), translation vector t\in R^3 and optionally scale factor s > 0
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to minimize
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\sum_i ||y_i - (s*O*x_i + t)||^2
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Optionally, one can enforce O to be a rotation. Algorithm taken from
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Umeyama, Shinji. "Least-squares estimation of transformation parameters between two point patterns."
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IEEE Transactions on pattern analysis and machine intelligence 13.4 (1991): 376-380.
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Second template argument allows to specify a different number type for svd computation
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*/
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template <typename T, typename T_SVD = T>
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void align(
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const std::vector<fvec<T, 3> >& source_points, const std::vector<fvec<T, 3> >& target_points, // input point sets
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fmat<T, 3, 3>& O, fvec<T, 3>& t, T* scale_ptr = nullptr, // output transformation
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bool allow_reflection = false) // configuration
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{
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// ensure that source_points and target_points have same number of points and that we have at least 3 point pairs
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assert(source_points.size() == target_points.size() && source_points.size() > 2);
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T inv_n = T(1) / source_points.size();
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// compute mean points
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fvec<T, 3> mu_source = mean(source_points, inv_n);
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fvec<T, 3> mu_target = mean(target_points, inv_n);
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// compute covariance matrix and variances of point sets
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fmat<T, 3, 3> Sigma(T(0));
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T sigma_S = 0, sigma_T = 0;
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for (size_t i = 0; i < source_points.size(); ++i) {
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Sigma += fmat<T, 3, 3>(target_points[i] - mu_target, source_points[i] - mu_source);
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sigma_S += sqr_length(source_points[i] - mu_source);
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sigma_T += sqr_length(target_points[i] - mu_target);
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}
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Sigma *= inv_n;
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sigma_S *= inv_n;
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sigma_T *= inv_n;
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// compute SVD of covariance matrix
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fvec<T_SVD, 3> D;
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fmat<T_SVD, 3, 3> U, V_t;
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svd(fmat<T_SVD,3,3>(Sigma), U, D, V_t);
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// account for reflections
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fmat<T_SVD, 3, 3> S;
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S.identity();
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if (!allow_reflection && det(mat<T>(3,3,&Sigma(0,0))) < 0)
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S(2, 2) = T_SVD(-1);
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// compute results
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O = fmat<T,3,3>(U*S*V_t);
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if (scale_ptr) {
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*scale_ptr = T(D(0) + D(1) + S(2, 2)*D(2)) / sigma_S;
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t = mu_target - *scale_ptr * O * mu_source;
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}
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else
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t = mu_target - O*mu_source;
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}
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}
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} |