/*--------------------------------------------------------------- The operator u'="this"+u is the pose/point compounding operator. ---------------------------------------------------------------*/ CPoint2D CPose2D::operator + (const CPoint2D& u)const { update_cached_cos_sin(); return CPoint2D( m_coords[0] + u.x() * m_cosphi - u.y() * m_sinphi, m_coords[1] + u.x() * m_sinphi + u.y() * m_cosphi ); }
/*--------------------------------------------------------------- drawSingleSample ---------------------------------------------------------------*/ void CPoint2DPDFGaussian::drawSingleSample(CPoint2D &outSample) const { MRPT_START // Eigen3 emits an out-of-array warning here, but it seems to be a false warning? (WTF) CVectorDouble vec; randomGenerator.drawGaussianMultivariate(vec,cov); ASSERT_(vec.size()==2); outSample.x( mean.x() + vec[0] ); outSample.y( mean.y() + vec[1] ); MRPT_END }
double poses_test_compose2Dpoint(int a1, int a2) { const long N = 500000; CTicTac tictac; CPose2D a(1.0,2.0,DEG2RAD(10)); CPoint2D b(8.0,-5.0); CPoint2D p; for (long i=0;i<N;i++) { p = a+b; } double T = tictac.Tac()/N; dummy_do_nothing_with_string( mrpt::format("%f",p.x()) ); return T; }
PointPosition CViewSegment2D::position( CPoint2D const& t_Point ) const { auto aPosition = PointPosition::OnLine; if ( !( t_Point.sameCoordinates( *m_StartPoint ) || t_Point.sameCoordinates( *m_EndPoint ) ) ) { auto dx = m_EndPoint->x() - m_StartPoint->x(); auto dy = m_EndPoint->y() - m_StartPoint->y(); auto position = dx * ( t_Point.y() - m_StartPoint->y() ) - dy * ( t_Point.x() - m_StartPoint->x() ); if ( position > ViewerConstants::DISTANCE_TOLERANCE ) { aPosition = PointPosition::Invisible; } else if ( position < -ViewerConstants::DISTANCE_TOLERANCE ) { aPosition = PointPosition::Visible; } } return aPosition; }
CPose2D::CPose2D(const CPoint2D &p) : m_phi(0),m_cossin_uptodate(false) { m_coords[0] = p.x(); m_coords[1] = p.y(); }
float R = randomGenerator.drawGaussian1D( m_dataPerBeacon[m_drawIndex].radiusAtRobotPlane, m_sigmaRanges); // This is the point where the SENSOR is: outSample.x( m_dataPerBeacon[m_drawIndex].beaconPosition.x + cos(ang) * R ); outSample.y( m_dataPerBeacon[m_drawIndex].beaconPosition.y + sin(ang) * R ); outSample.phi( randomGenerator.drawGaussian1D( m_oldPose.phi(), DEG2RAD(2) ) ); // Compute the robot pose P. // P = SAMPLE - ROT ยท SENSOR_ON_ROBOT CPoint2D on(m_dataPerBeacon[m_drawIndex].sensorOnRobot.x,m_dataPerBeacon[m_drawIndex].sensorOnRobot.y); CPoint2D S(outSample.x(),outSample.y()); on = CPose2D(0,0,outSample.phi()) + on; S = S - on; outSample.x( S.x() ); outSample.y( S.y() ); MRPT_END } /*--------------------------------------------------------------- RS_observationLikelihood ---------------------------------------------------------------*/ double CRejectionSamplingRangeOnlyLocalization::RS_observationLikelihood( const CPose2D &x) { MRPT_START double lik = 1.0; double m_sigmaRanges2 = square(m_sigmaRanges);
// avoid headers include loops. CPoint3D::CPoint3D(const CPoint2D& p) { m_coords[0] = p.x(); m_coords[1] = p.y(); m_coords[2] = 0; }
CPoint2D::CPoint2D(const CPoint2D &p) { m_x = p.x(); m_y = p.y(); }
double CPoint2D::measure_from(CPoint2D& o) { return sqrt(pow((m_x - o.x()), 2) + pow((m_y - o.y()), 2)); }
CPoint2D CPoint2D::rotate_about(CPoint2D& o, double rad) { return CPoint2D((m_x-o.x()) * cos(rad) - (m_y - o.y()) * sin(rad) + o.x(), (m_y-o.y()) * cos(rad) + (m_x - o.x()) * sin(rad) + o.y()); }
const CPoint2D CPoint2D::operator-(const CPoint2D &other) const { return CPoint2D(m_x - other.x(), m_y - other.y()); }
const CPoint2D CPoint2D::operator+(const CPoint2D &other) const { return CPoint2D(m_x + other.x(), m_y + other.y()); }