Eigne Matrix Class Library
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src/Geometry/EulerAngles.h
- Committer:
- ykuroda
- Date:
- 2016-10-13
- Revision:
- 0:13a5d365ba16
File content as of revision 0:13a5d365ba16:
// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr> // // This Source Code Form is subject to the terms of the Mozilla // Public License v. 2.0. If a copy of the MPL was not distributed // with this file, You can obtain one at http://mozilla.org/MPL/2.0/. #ifndef EIGEN_EULERANGLES_H #define EIGEN_EULERANGLES_H namespace Eigen { /** \geometry_module \ingroup Geometry_Module * * * \returns the Euler-angles of the rotation matrix \c *this using the convention defined by the triplet (\a a0,\a a1,\a a2) * * Each of the three parameters \a a0,\a a1,\a a2 represents the respective rotation axis as an integer in {0,1,2}. * For instance, in: * \code Vector3f ea = mat.eulerAngles(2, 0, 2); \endcode * "2" represents the z axis and "0" the x axis, etc. The returned angles are such that * we have the following equality: * \code * mat == AngleAxisf(ea[0], Vector3f::UnitZ()) * * AngleAxisf(ea[1], Vector3f::UnitX()) * * AngleAxisf(ea[2], Vector3f::UnitZ()); \endcode * This corresponds to the right-multiply conventions (with right hand side frames). * * The returned angles are in the ranges [0:pi]x[-pi:pi]x[-pi:pi]. * * \sa class AngleAxis */ template<typename Derived> inline Matrix<typename MatrixBase<Derived>::Scalar,3,1> MatrixBase<Derived>::eulerAngles(Index a0, Index a1, Index a2) const { using std::atan2; using std::sin; using std::cos; /* Implemented from Graphics Gems IV */ EIGEN_STATIC_ASSERT_MATRIX_SPECIFIC_SIZE(Derived,3,3) Matrix<Scalar,3,1> res; typedef Matrix<typename Derived::Scalar,2,1> Vector2; const Index odd = ((a0+1)%3 == a1) ? 0 : 1; const Index i = a0; const Index j = (a0 + 1 + odd)%3; const Index k = (a0 + 2 - odd)%3; if (a0==a2) { res[0] = atan2(coeff(j,i), coeff(k,i)); if((odd && res[0]<Scalar(0)) || ((!odd) && res[0]>Scalar(0))) { res[0] = (res[0] > Scalar(0)) ? res[0] - Scalar(M_PI) : res[0] + Scalar(M_PI); Scalar s2 = Vector2(coeff(j,i), coeff(k,i)).norm(); res[1] = -atan2(s2, coeff(i,i)); } else { Scalar s2 = Vector2(coeff(j,i), coeff(k,i)).norm(); res[1] = atan2(s2, coeff(i,i)); } // With a=(0,1,0), we have i=0; j=1; k=2, and after computing the first two angles, // we can compute their respective rotation, and apply its inverse to M. Since the result must // be a rotation around x, we have: // // c2 s1.s2 c1.s2 1 0 0 // 0 c1 -s1 * M = 0 c3 s3 // -s2 s1.c2 c1.c2 0 -s3 c3 // // Thus: m11.c1 - m21.s1 = c3 & m12.c1 - m22.s1 = s3 Scalar s1 = sin(res[0]); Scalar c1 = cos(res[0]); res[2] = atan2(c1*coeff(j,k)-s1*coeff(k,k), c1*coeff(j,j) - s1 * coeff(k,j)); } else { res[0] = atan2(coeff(j,k), coeff(k,k)); Scalar c2 = Vector2(coeff(i,i), coeff(i,j)).norm(); if((odd && res[0]<Scalar(0)) || ((!odd) && res[0]>Scalar(0))) { res[0] = (res[0] > Scalar(0)) ? res[0] - Scalar(M_PI) : res[0] + Scalar(M_PI); res[1] = atan2(-coeff(i,k), -c2); } else res[1] = atan2(-coeff(i,k), c2); Scalar s1 = sin(res[0]); Scalar c1 = cos(res[0]); res[2] = atan2(s1*coeff(k,i)-c1*coeff(j,i), c1*coeff(j,j) - s1 * coeff(k,j)); } if (!odd) res = -res; return res; } } // end namespace Eigen #endif // EIGEN_EULERANGLES_H