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

232 lines
8.0 KiB
C++

/// @file
/// Calculation of biinvariant means.
#ifndef SOPHUS_AVERAGE_HPP
#define SOPHUS_AVERAGE_HPP
#include "common.hpp"
#include "rxso2.hpp"
#include "rxso3.hpp"
#include "se2.hpp"
#include "se3.hpp"
#include "sim2.hpp"
#include "sim3.hpp"
#include "so2.hpp"
#include "so3.hpp"
namespace Sophus {
/// Calculates mean iteratively.
///
/// Returns ``nullopt`` if it does not converge.
///
template <class SequenceContainer>
optional<typename SequenceContainer::value_type> iterativeMean(
SequenceContainer const& foo_Ts_bar, int max_num_iterations) {
size_t N = foo_Ts_bar.size();
SOPHUS_ENSURE(N >= 1, "N must be >= 1.");
using Group = typename SequenceContainer::value_type;
using Scalar = typename Group::Scalar;
using Tangent = typename Group::Tangent;
// This implements the algorithm in the beginning of Sec. 4.2 in
// ftp://ftp-sop.inria.fr/epidaure/Publications/Arsigny/arsigny_rr_biinvariant_average.pdf.
Group foo_T_average = foo_Ts_bar.front();
Scalar w = Scalar(1. / N);
for (int i = 0; i < max_num_iterations; ++i) {
Tangent average;
setToZero<Tangent>(average);
for (Group const& foo_T_bar : foo_Ts_bar) {
average += w * (foo_T_average.inverse() * foo_T_bar).log();
}
Group foo_T_newaverage = foo_T_average * Group::exp(average);
if (squaredNorm<Tangent>(
(foo_T_newaverage.inverse() * foo_T_average).log()) <
Constants<Scalar>::epsilon()) {
return foo_T_newaverage;
}
foo_T_average = foo_T_newaverage;
}
// LCOV_EXCL_START
return nullopt;
// LCOV_EXCL_STOP
}
#ifdef DOXYGEN_SHOULD_SKIP_THIS
/// Mean implementation for any Lie group.
template <class SequenceContainer, class Scalar>
optional<typename SequenceContainer::value_type> average(
SequenceContainer const& foo_Ts_bar);
#else
// Mean implementation for SO(2).
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
enable_if_t<
std::is_same<typename SequenceContainer::value_type, SO2<Scalar> >::value,
optional<typename SequenceContainer::value_type> >
average(SequenceContainer const& foo_Ts_bar) {
// This implements rotational part of Proposition 12 from Sec. 6.2 of
// ftp://ftp-sop.inria.fr/epidaure/Publications/Arsigny/arsigny_rr_biinvariant_average.pdf.
size_t N = std::distance(std::begin(foo_Ts_bar), std::end(foo_Ts_bar));
SOPHUS_ENSURE(N >= 1, "N must be >= 1.");
SO2<Scalar> foo_T_average = foo_Ts_bar.front();
Scalar w = Scalar(1. / N);
Scalar average(0);
for (SO2<Scalar> const& foo_T_bar : foo_Ts_bar) {
average += w * (foo_T_average.inverse() * foo_T_bar).log();
}
return foo_T_average * SO2<Scalar>::exp(average);
}
// Mean implementation for RxSO(2).
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
enable_if_t<
std::is_same<typename SequenceContainer::value_type, RxSO2<Scalar> >::value,
optional<typename SequenceContainer::value_type> >
average(SequenceContainer const& foo_Ts_bar) {
size_t N = std::distance(std::begin(foo_Ts_bar), std::end(foo_Ts_bar));
SOPHUS_ENSURE(N >= 1, "N must be >= 1.");
RxSO2<Scalar> foo_T_average = foo_Ts_bar.front();
Scalar w = Scalar(1. / N);
Vector2<Scalar> average(Scalar(0), Scalar(0));
for (RxSO2<Scalar> const& foo_T_bar : foo_Ts_bar) {
average += w * (foo_T_average.inverse() * foo_T_bar).log();
}
return foo_T_average * RxSO2<Scalar>::exp(average);
}
namespace details {
template <class T>
void getQuaternion(T const&);
template <class Scalar>
Eigen::Quaternion<Scalar> getUnitQuaternion(SO3<Scalar> const& R) {
return R.unit_quaternion();
}
template <class Scalar>
Eigen::Quaternion<Scalar> getUnitQuaternion(RxSO3<Scalar> const& sR) {
return sR.so3().unit_quaternion();
}
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
Eigen::Quaternion<Scalar> averageUnitQuaternion(
SequenceContainer const& foo_Ts_bar) {
// This: http://stackoverflow.com/a/27410865/1221742
size_t N = std::distance(std::begin(foo_Ts_bar), std::end(foo_Ts_bar));
SOPHUS_ENSURE(N >= 1, "N must be >= 1.");
Eigen::Matrix<Scalar, 4, Eigen::Dynamic> Q(4, N);
int i = 0;
Scalar w = Scalar(1. / N);
for (auto const& foo_T_bar : foo_Ts_bar) {
Q.col(i) = w * details::getUnitQuaternion(foo_T_bar).coeffs();
++i;
}
Eigen::Matrix<Scalar, 4, 4> QQt = Q * Q.transpose();
// TODO: Figure out why we can't use SelfAdjointEigenSolver here.
Eigen::EigenSolver<Eigen::Matrix<Scalar, 4, 4> > es(QQt);
std::complex<Scalar> max_eigenvalue = es.eigenvalues()[0];
Eigen::Matrix<std::complex<Scalar>, 4, 1> max_eigenvector =
es.eigenvectors().col(0);
for (int i = 1; i < 4; i++) {
if (std::norm(es.eigenvalues()[i]) > std::norm(max_eigenvalue)) {
max_eigenvalue = es.eigenvalues()[i];
max_eigenvector = es.eigenvectors().col(i);
}
}
Eigen::Quaternion<Scalar> quat;
quat.coeffs() << //
max_eigenvector[0].real(), //
max_eigenvector[1].real(), //
max_eigenvector[2].real(), //
max_eigenvector[3].real();
return quat;
}
} // namespace details
// Mean implementation for SO(3).
//
// TODO: Detect degenerated cases and return nullopt.
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
enable_if_t<
std::is_same<typename SequenceContainer::value_type, SO3<Scalar> >::value,
optional<typename SequenceContainer::value_type> >
average(SequenceContainer const& foo_Ts_bar) {
return SO3<Scalar>(details::averageUnitQuaternion(foo_Ts_bar));
}
// Mean implementation for R x SO(3).
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
enable_if_t<
std::is_same<typename SequenceContainer::value_type, RxSO3<Scalar> >::value,
optional<typename SequenceContainer::value_type> >
average(SequenceContainer const& foo_Ts_bar) {
size_t N = std::distance(std::begin(foo_Ts_bar), std::end(foo_Ts_bar));
SOPHUS_ENSURE(N >= 1, "N must be >= 1.");
Scalar scale_sum = Scalar(0);
using std::exp;
using std::log;
for (RxSO3<Scalar> const& foo_T_bar : foo_Ts_bar) {
scale_sum += log(foo_T_bar.scale());
}
return RxSO3<Scalar>(exp(scale_sum / Scalar(N)),
SO3<Scalar>(details::averageUnitQuaternion(foo_Ts_bar)));
}
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
enable_if_t<
std::is_same<typename SequenceContainer::value_type, SE2<Scalar> >::value,
optional<typename SequenceContainer::value_type> >
average(SequenceContainer const& foo_Ts_bar, int max_num_iterations = 20) {
// TODO: Implement Proposition 12 from Sec. 6.2 of
// ftp://ftp-sop.inria.fr/epidaure/Publications/Arsigny/arsigny_rr_biinvariant_average.pdf.
return iterativeMean(foo_Ts_bar, max_num_iterations);
}
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
enable_if_t<
std::is_same<typename SequenceContainer::value_type, Sim2<Scalar> >::value,
optional<typename SequenceContainer::value_type> >
average(SequenceContainer const& foo_Ts_bar, int max_num_iterations = 20) {
return iterativeMean(foo_Ts_bar, max_num_iterations);
}
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
enable_if_t<
std::is_same<typename SequenceContainer::value_type, SE3<Scalar> >::value,
optional<typename SequenceContainer::value_type> >
average(SequenceContainer const& foo_Ts_bar, int max_num_iterations = 20) {
return iterativeMean(foo_Ts_bar, max_num_iterations);
}
template <class SequenceContainer,
class Scalar = typename SequenceContainer::value_type::Scalar>
enable_if_t<
std::is_same<typename SequenceContainer::value_type, Sim3<Scalar> >::value,
optional<typename SequenceContainer::value_type> >
average(SequenceContainer const& foo_Ts_bar, int max_num_iterations = 20) {
return iterativeMean(foo_Ts_bar, max_num_iterations);
}
#endif // DOXYGEN_SHOULD_SKIP_THIS
} // namespace Sophus
#endif // SOPHUS_AVERAGE_HPP