/* * matrix3.cpp * Copyright (C) Andrew Tridgell 2012 * * This file is free software: you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This file is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * See the GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program. If not, see . */ #pragma GCC optimize("O2") #include "AP_Math.h" // create a rotation matrix given some euler angles // this is based on https://github.com/ArduPilot/Datasheets/blob/main/References/EulerAngles.pdf template void Matrix3::from_euler(T roll, T pitch, T yaw) { const T cp = cosF(pitch); const T sp = sinF(pitch); const T sr = sinF(roll); const T cr = cosF(roll); const T sy = sinF(yaw); const T cy = cosF(yaw); a.x = cp * cy; a.y = (sr * sp * cy) - (cr * sy); a.z = (cr * sp * cy) + (sr * sy); b.x = cp * sy; b.y = (sr * sp * sy) + (cr * cy); b.z = (cr * sp * sy) - (sr * cy); c.x = -sp; c.y = sr * cp; c.z = cr * cp; } // calculate euler angles from a rotation matrix // this is based on https://github.com/ArduPilot/Datasheets/blob/main/References/EulerAngles.pdf template void Matrix3::to_euler(T *roll, T *pitch, T *yaw) const { if (pitch != nullptr) { *pitch = -safe_asin(c.x); } if (roll != nullptr) { *roll = atan2F(c.y, c.z); } if (yaw != nullptr) { *yaw = atan2F(b.x, a.x); } } template void Matrix3::from_rotation(enum Rotation rotation) { (*this).a = {1,0,0}; (*this).b = {0,1,0}; (*this).c = {0,0,1}; (*this).a.rotate(rotation); (*this).b.rotate(rotation); (*this).c.rotate(rotation); (*this).transpose(); } /* calculate Euler angles (312 convention) for the matrix. See http://www.atacolorado.com/eulersequences.doc vector is returned in r, p, y order */ template Vector3 Matrix3::to_euler312() const { return Vector3(asinF(c.y), atan2F(-c.x, c.z), atan2F(-a.y, b.y)); } /* fill the matrix from Euler angles in radians in 312 convention */ template void Matrix3::from_euler312(T roll, T pitch, T yaw) { const T c3 = cosF(pitch); const T s3 = sinF(pitch); const T s2 = sinF(roll); const T c2 = cosF(roll); const T s1 = sinF(yaw); const T c1 = cosF(yaw); a.x = c1 * c3 - s1 * s2 * s3; b.y = c1 * c2; c.z = c3 * c2; a.y = -c2*s1; a.z = s3*c1 + c3*s2*s1; b.x = c3*s1 + s3*s2*c1; b.z = s1*s3 - s2*c1*c3; c.x = -s3*c2; c.y = s2; } // apply an additional rotation from a body frame gyro vector // to a rotation matrix. template void Matrix3::rotate(const Vector3 &g) { (*this) += Matrix3{ a.y * g.z - a.z * g.y, a.z * g.x - a.x * g.z, a.x * g.y - a.y * g.x, b.y * g.z - b.z * g.y, b.z * g.x - b.x * g.z, b.x * g.y - b.y * g.x, c.y * g.z - c.z * g.y, c.z * g.x - c.x * g.z, c.x * g.y - c.y * g.x }; } /* re-normalise a rotation matrix */ template void Matrix3::normalize(void) { const T error = a * b; const Vector3 t0 = a - (b * (0.5f * error)); const Vector3 t1 = b - (a * (0.5f * error)); const Vector3 t2 = t0 % t1; a = t0 * (1.0f / t0.length()); b = t1 * (1.0f / t1.length()); c = t2 * (1.0f / t2.length()); } // multiplication by a vector template Vector3 Matrix3::operator *(const Vector3 &v) const { return Vector3(a.x * v.x + a.y * v.y + a.z * v.z, b.x * v.x + b.y * v.y + b.z * v.z, c.x * v.x + c.y * v.y + c.z * v.z); } // multiplication by a vector, extracting only the xy components template Vector2 Matrix3::mulXY(const Vector3 &v) const { return Vector2(a.x * v.x + a.y * v.y + a.z * v.z, b.x * v.x + b.y * v.y + b.z * v.z); } // multiplication of transpose by a vector template Vector3 Matrix3::mul_transpose(const Vector3 &v) const { return Vector3(a.x * v.x + b.x * v.y + c.x * v.z, a.y * v.x + b.y * v.y + c.y * v.z, a.z * v.x + b.z * v.y + c.z * v.z); } // multiplication by another Matrix3 template Matrix3 Matrix3::operator *(const Matrix3 &m) const { Matrix3 temp (Vector3(a.x * m.a.x + a.y * m.b.x + a.z * m.c.x, a.x * m.a.y + a.y * m.b.y + a.z * m.c.y, a.x * m.a.z + a.y * m.b.z + a.z * m.c.z), Vector3(b.x * m.a.x + b.y * m.b.x + b.z * m.c.x, b.x * m.a.y + b.y * m.b.y + b.z * m.c.y, b.x * m.a.z + b.y * m.b.z + b.z * m.c.z), Vector3(c.x * m.a.x + c.y * m.b.x + c.z * m.c.x, c.x * m.a.y + c.y * m.b.y + c.z * m.c.y, c.x * m.a.z + c.y * m.b.z + c.z * m.c.z)); return temp; } template Matrix3 Matrix3::transposed(void) const { return Matrix3(Vector3(a.x, b.x, c.x), Vector3(a.y, b.y, c.y), Vector3(a.z, b.z, c.z)); } template T Matrix3::det() const { return a.x * (b.y * c.z - b.z * c.y) + a.y * (b.z * c.x - b.x * c.z) + a.z * (b.x * c.y - b.y * c.x); } template bool Matrix3::inverse(Matrix3& inv) const { const T d = det(); if (is_zero(d)) { return false; } inv.a.x = (b.y * c.z - c.y * b.z) / d; inv.a.y = (a.z * c.y - a.y * c.z) / d; inv.a.z = (a.y * b.z - a.z * b.y) / d; inv.b.x = (b.z * c.x - b.x * c.z) / d; inv.b.y = (a.x * c.z - a.z * c.x) / d; inv.b.z = (b.x * a.z - a.x * b.z) / d; inv.c.x = (b.x * c.y - c.x * b.y) / d; inv.c.y = (c.x * a.y - a.x * c.y) / d; inv.c.z = (a.x * b.y - b.x * a.y) / d; return true; } template bool Matrix3::invert() { Matrix3 inv; bool success = inverse(inv); if (success) { *this = inv; } return success; } template void Matrix3::zero(void) { a.x = a.y = a.z = 0; b.x = b.y = b.z = 0; c.x = c.y = c.z = 0; } // create rotation matrix for rotation about the vector v by angle theta // See: http://www.euclideanspace.com/maths/geometry/rotations/conversions/angleToMatrix/ template void Matrix3::from_axis_angle(const Vector3 &v, T theta) { const T C = cosF(theta); const T S = sinF(theta); const T t = 1.0f - C; const Vector3 normv = v.normalized(); const T x = normv.x; const T y = normv.y; const T z = normv.z; a.x = t*x*x + C; a.y = t*x*y - z*S; a.z = t*x*z + y*S; b.x = t*x*y + z*S; b.y = t*y*y + C; b.z = t*y*z - x*S; c.x = t*x*z - y*S; c.y = t*y*z + x*S; c.z = t*z*z + C; } // define for float and double template class Matrix3; template class Matrix3;