ORB-SLAM3-UESTC/Workspace/Thirdparty/Sophus/sophus/rotation_matrix.hpp

85 lines
2.6 KiB
C++

/// @file
/// Rotation matrix helper functions.
#ifndef SOPHUS_ROTATION_MATRIX_HPP
#define SOPHUS_ROTATION_MATRIX_HPP
#include <Eigen/Dense>
#include <Eigen/SVD>
#include "types.hpp"
namespace Sophus {
/// Takes in arbitrary square matrix and returns true if it is
/// orthogonal.
template <class D>
SOPHUS_FUNC bool isOrthogonal(Eigen::MatrixBase<D> const& R) {
using Scalar = typename D::Scalar;
static int const N = D::RowsAtCompileTime;
static int const M = D::ColsAtCompileTime;
static_assert(N == M, "must be a square matrix");
static_assert(N >= 2, "must have compile time dimension >= 2");
return (R * R.transpose() - Matrix<Scalar, N, N>::Identity()).norm() <
Constants<Scalar>::epsilon();
}
/// Takes in arbitrary square matrix and returns true if it is
/// "scaled-orthogonal" with positive determinant.
///
template <class D>
SOPHUS_FUNC bool isScaledOrthogonalAndPositive(Eigen::MatrixBase<D> const& sR) {
using Scalar = typename D::Scalar;
static int const N = D::RowsAtCompileTime;
static int const M = D::ColsAtCompileTime;
using std::pow;
using std::sqrt;
Scalar det = sR.determinant();
if (det <= Scalar(0)) {
return false;
}
Scalar scale_sqr = pow(det, Scalar(2. / N));
static_assert(N == M, "must be a square matrix");
static_assert(N >= 2, "must have compile time dimension >= 2");
return (sR * sR.transpose() - scale_sqr * Matrix<Scalar, N, N>::Identity())
.template lpNorm<Eigen::Infinity>() <
sqrt(Constants<Scalar>::epsilon());
}
/// Takes in arbitrary square matrix (2x2 or larger) and returns closest
/// orthogonal matrix with positive determinant.
template <class D>
SOPHUS_FUNC enable_if_t<
std::is_floating_point<typename D::Scalar>::value,
Matrix<typename D::Scalar, D::RowsAtCompileTime, D::RowsAtCompileTime>>
makeRotationMatrix(Eigen::MatrixBase<D> const& R) {
using Scalar = typename D::Scalar;
static int const N = D::RowsAtCompileTime;
static int const M = D::ColsAtCompileTime;
static_assert(N == M, "must be a square matrix");
static_assert(N >= 2, "must have compile time dimension >= 2");
Eigen::JacobiSVD<Matrix<Scalar, N, N>> svd(
R, Eigen::ComputeFullU | Eigen::ComputeFullV);
// Determine determinant of orthogonal matrix U*V'.
Scalar d = (svd.matrixU() * svd.matrixV().transpose()).determinant();
// Starting from the identity matrix D, set the last entry to d (+1 or
// -1), so that det(U*D*V') = 1.
Matrix<Scalar, N, N> Diag = Matrix<Scalar, N, N>::Identity();
Diag(N - 1, N - 1) = d;
return svd.matrixU() * Diag * svd.matrixV().transpose();
}
} // namespace Sophus
#endif // SOPHUS_ROTATION_MATRIX_HPP