Exemple #1
0
void Element::CalculateStiffnessMatrix(const Eigen::Matrix3f& D, std::vector<Eigen::Triplet<float> >& triplets)
{
	Eigen::Vector3f x, y;
	x << nodesX[nodesIds[0]], nodesX[nodesIds[1]], nodesX[nodesIds[2]];
	y << nodesY[nodesIds[0]], nodesY[nodesIds[1]], nodesY[nodesIds[2]];
	
	Eigen::Matrix3f C;
	C << Eigen::Vector3f(1.0f, 1.0f, 1.0f), x, y;
	
	Eigen::Matrix3f IC = C.inverse();

	for (int i = 0; i < 3; i++)
	{
		B(0, 2 * i + 0) = IC(1, i);
		B(0, 2 * i + 1) = 0.0f;
		B(1, 2 * i + 0) = 0.0f;
		B(1, 2 * i + 1) = IC(2, i);
		B(2, 2 * i + 0) = IC(2, i);
		B(2, 2 * i + 1) = IC(1, i);
	}
	Eigen::Matrix<float, 6, 6> K = B.transpose() * D * B * C.determinant() / 2.0f;

	for (int i = 0; i < 3; i++)
	{
		for (int j = 0; j < 3; j++)
		{
			Eigen::Triplet<float> trplt11(2 * nodesIds[i] + 0, 2 * nodesIds[j] + 0, K(2 * i + 0, 2 * j + 0));
			Eigen::Triplet<float> trplt12(2 * nodesIds[i] + 0, 2 * nodesIds[j] + 1, K(2 * i + 0, 2 * j + 1));
			Eigen::Triplet<float> trplt21(2 * nodesIds[i] + 1, 2 * nodesIds[j] + 0, K(2 * i + 1, 2 * j + 0));
			Eigen::Triplet<float> trplt22(2 * nodesIds[i] + 1, 2 * nodesIds[j] + 1, K(2 * i + 1, 2 * j + 1));

			triplets.push_back(trplt11);
			triplets.push_back(trplt12);
			triplets.push_back(trplt21);
			triplets.push_back(trplt22);
		}
	}
}
bool PositionBasedElasticRod::ComputeDarbouxVector(const Eigen::Matrix3f& dA, const Eigen::Matrix3f& dB, const float mid_edge_length, Eigen::Vector3f& darboux_vector)
{

	float factor = 1.0f + dA.col(0).dot(dB.col(0)) + dA.col(1).dot(dB.col(1)) + dA.col(2).dot(dB.col(2));

	factor = 2.0f / (mid_edge_length * factor);

	for (int c = 0; c < 3; ++c)
	{
		const int i = permutation[c][0];
		const int j = permutation[c][1];
		const int k = permutation[c][2];

		darboux_vector[i] = dA.col(j).dot(dB.col(k)) - dA.col(k).dot(dB.col(j));
	}

	darboux_vector *= factor;
	return true;
}
Exemple #3
0
void transformOrientationToGroundFrame(const VirtualRobot::RobotPtr& robot,
                                       const Eigen::Matrix6Xf& leftFootTrajectory,
                                       const VirtualRobot::RobotNodePtr& leftFoot,
                                       const VirtualRobot::RobotNodePtr& rightFoot,
                                       const VirtualRobot::RobotNodeSetPtr& bodyJoints,
                                       const Eigen::MatrixXf& bodyTrajectory,
                                       const Eigen::Matrix3Xf& trajectory,
                                       const std::vector<SupportInterval>& intervals,
                                       Eigen::Matrix3Xf& relativeTrajectory)
{
    Eigen::Matrix4f leftInitialPose = bodyJoints->getKinematicRoot()->getGlobalPose();
    int N = trajectory.cols();
    int M = trajectory.rows();
    relativeTrajectory.resize(M, N);

    BOOST_ASSERT(M > 0 && M <= 3);

    auto intervalIter = intervals.begin();
    for (int i = 0; i < N; i++)
    {
        while (i >= intervalIter->endIdx)
        {
            intervalIter = std::next(intervalIter);
        }
        // Move basis along with the left foot
        Eigen::Matrix4f leftFootPose = Eigen::Matrix4f::Identity();
        VirtualRobot::MathTools::posrpy2eigen4f(1000 * leftFootTrajectory.block(0, i, 3, 1),
                                                leftFootTrajectory.block(3, i, 3, 1),  leftFootPose);
        robot->setGlobalPose(leftFootPose);
        bodyJoints->setJointValues(bodyTrajectory.col(i));
        Eigen::Matrix3f worldToRef = computeGroundFrame(leftFoot->getGlobalPose(),
                                                        rightFoot->getGlobalPose(),
                                                        intervalIter->phase).block(0, 0, 3, 3);
        relativeTrajectory.block(0, i, M, 1) = worldToRef.colPivHouseholderQr().solve(trajectory.col(i)).block(0, 0, M, 1);
    }
}
template <typename PointT> void
pcl::SampleConsensusModelRegistration<PointT>::estimateRigidTransformationSVD (
    const pcl::PointCloud<PointT> &cloud_src, 
    const std::vector<int> &indices_src, 
    const pcl::PointCloud<PointT> &cloud_tgt,
    const std::vector<int> &indices_tgt, 
    Eigen::VectorXf &transform)
{
  transform.resize (16);
  Eigen::Vector4f centroid_src, centroid_tgt;
  // Estimate the centroids of source, target
  compute3DCentroid (cloud_src, indices_src, centroid_src);
  compute3DCentroid (cloud_tgt, indices_tgt, centroid_tgt);

  // Subtract the centroids from source, target
  Eigen::MatrixXf cloud_src_demean;
  demeanPointCloud (cloud_src, indices_src, centroid_src, cloud_src_demean);

  Eigen::MatrixXf cloud_tgt_demean;
  demeanPointCloud (cloud_tgt, indices_tgt, centroid_tgt, cloud_tgt_demean);

  // Assemble the correlation matrix H = source * target'
  Eigen::Matrix3f H = (cloud_src_demean * cloud_tgt_demean.transpose ()).topLeftCorner<3, 3>();

  // Compute the Singular Value Decomposition
  Eigen::JacobiSVD<Eigen::Matrix3f> svd (H, Eigen::ComputeFullU | Eigen::ComputeFullV);
  Eigen::Matrix3f u = svd.matrixU ();
  Eigen::Matrix3f v = svd.matrixV ();

  // Compute R = V * U'
  if (u.determinant () * v.determinant () < 0)
  {
    for (int x = 0; x < 3; ++x)
      v (x, 2) *= -1;
  }

  Eigen::Matrix3f R = v * u.transpose ();

  // Return the correct transformation
  transform.segment<3> (0) = R.row (0); transform[12]  = 0;
  transform.segment<3> (4) = R.row (1); transform[13]  = 0;
  transform.segment<3> (8) = R.row (2); transform[14] = 0;

  Eigen::Vector3f t = centroid_tgt.head<3> () - R * centroid_src.head<3> ();
  transform[3] = t[0]; transform[7] = t[1]; transform[11] = t[2]; transform[15] = 1.0;
}
// ----------------------------------------------------------------------------------------------
bool PositionBasedElasticRod::ComputeMaterialFrame(
	const Eigen::Vector3f& pA, 
	const Eigen::Vector3f& pB, 
	const Eigen::Vector3f& pG, 
	Eigen::Matrix3f& frame)
{

	frame.col(2) = (pB - pA);
	frame.col(2).normalize();

	frame.col(1) = (frame.col(2).cross(pG - pA));
	frame.col(1).normalize();

	frame.col(0) = frame.col(1).cross(frame.col(2));
//	frame.col(0).normalize();
	return true;
}
bool FruitDetector::enhanceAlignment(
  const Eigen::Matrix3f& new_rotation, const boost::shared_ptr<Fruit>& f) {
  // get euler angles. (Z-Y-X) convention --> (Yaw, Pitch, Roll)
  const Eigen::Vector3f euler_angles = new_rotation.eulerAngles(2, 1, 0);
  const float new_yaw = euler_angles[0];
  const float new_pitch = euler_angles[1];
  const float new_roll = euler_angles[2];

  const float old_roll = f->get_RPY().roll;
  const float old_pitch = f->get_RPY().pitch;
  // check if the new aligned model is less tilted
  if (new_roll < old_roll && new_pitch < old_pitch)
    return true;
  return false;
}
bool ObjectFinder::find_toy_block(float surface_height, geometry_msgs::PoseStamped &object_pose) {
    Eigen::Vector3f plane_normal;
    double plane_dist;
    //bool valid_plane;
    Eigen::Vector3f major_axis;
    Eigen::Vector3f centroid;
    bool found_object = true; //should verify this
    double block_height = 0.035; //this height is specific to the TOY_BLOCK model
    //if insufficient points in plane, find_plane_fit returns "false"
    //should do more sanity testing on found_object status
    //hard-coded search bounds based on a block of width 0.035
    found_object = pclUtils_.find_plane_fit(0.4, 1, -0.5, 0.5, surface_height + 0.025, surface_height + 0.045, 0.001,
            plane_normal, plane_dist, major_axis, centroid);
    //should have put a return value on find_plane_fit;
    //
    if (plane_normal(2) < 0) plane_normal(2) *= -1.0; //in world frame, normal must point UP
    Eigen::Matrix3f R;
    Eigen::Vector3f y_vec;
    R.col(0) = major_axis;
    R.col(2) = plane_normal;
    R.col(1) = plane_normal.cross(major_axis);
    Eigen::Quaternionf quat(R);
    object_pose.header.frame_id = "base_link";
    object_pose.pose.position.x = centroid(0);
    object_pose.pose.position.y = centroid(1);
    //the TOY_BLOCK model has its origin in the middle of the block, not the top surface
    //so lower the block model origin by half the block height from upper surface
    object_pose.pose.position.z = centroid(2)-0.5*block_height;
    //create R from normal and major axis, then convert R to quaternion

    object_pose.pose.orientation.x = quat.x();
    object_pose.pose.orientation.y = quat.y();
    object_pose.pose.orientation.z = quat.z();
    object_pose.pose.orientation.w = quat.w();
    return found_object;
}
Exemple #8
0
std::vector<Point3f> PnPUtil::BackprojectPts(const std::vector<Point2f>& pts, const Eigen::Matrix4f& camTf, const Eigen::Matrix3f& K, const Mat& depth)
{
  std::vector<Point3f> pts3d;
  for(std::size_t i = 0; i < pts.size(); i++)
  {
    Point2f pt = pts[i];
    Eigen::Vector3f hkp(pt.x, pt.y, 1);
    Eigen::Vector3f backproj = K.inverse()*hkp;
    backproj /= backproj(2);    
    backproj *= depth.at<float>(pt.y, pt.x);
    if(depth.at<float>(pt.y, pt.x) == 0)
      std::cout << "Bad depth (0)" << std::endl;
    Eigen::Vector4f backproj_h(backproj(0), backproj(1), backproj(2), 1);
    backproj_h = camTf*backproj_h;
    pts3d.push_back(Point3f(backproj_h(0), backproj_h(1), backproj_h(2)));
  }
  return pts3d;
}
void SQ_fitter<PointT>::getBoundingBox(const PointCloudPtr &_cloud,
				       double _dim[3],
				       double _trans[3],
				       double _rot[3] ) {

  // 1. Compute the bounding box center
  Eigen::Vector4d centroid;
  pcl::compute3DCentroid( *_cloud, centroid );
  _trans[0] = centroid(0);
  _trans[1] = centroid(1); 
  _trans[2] = centroid(2);

  // 2. Compute main axis orientations
  pcl::PCA<PointT> pca;
  pca.setInputCloud( _cloud );
  Eigen::Vector3f eigVal = pca.getEigenValues();
  Eigen::Matrix3f eigVec = pca.getEigenVectors();
  // Make sure 3 vectors are normal w.r.t. each other
  Eigen::Vector3f temp;
  eigVec.col(2) = eigVec.col(0); // Z
  Eigen::Vector3f v3 = (eigVec.col(1)).cross( eigVec.col(2) );
  eigVec.col(0) = v3;
  Eigen::Vector3f rpy = eigVec.eulerAngles(2,1,0);
 
  _rot[0] = (double)rpy(2);
  _rot[1] = (double)rpy(1);
  _rot[2] = (double)rpy(0);

  // Transform _cloud
  Eigen::Matrix4f transf = Eigen::Matrix4f::Identity();
  transf.block(0,3,3,1) << (float)centroid(0), (float)centroid(1), (float)centroid(2);
  transf.block(0,0,3,3) = eigVec;

  Eigen::Matrix4f tinv; tinv = transf.inverse();
  PointCloudPtr cloud_temp( new pcl::PointCloud<PointT>() );
  pcl::transformPointCloud( *_cloud, *cloud_temp, tinv );

  // Get maximum and minimum
  PointT minPt; PointT maxPt;
  pcl::getMinMax3D( *cloud_temp, minPt, maxPt );
  
  _dim[0] = ( maxPt.x - minPt.x ) / 2.0;
  _dim[1] = ( maxPt.y - minPt.y ) / 2.0;
  _dim[2] = ( maxPt.z - minPt.z ) / 2.0;

}
Exemple #10
0
pcl::PointCloud<pcl::PointXYZRGB> createPointCloud(
  const Eigen::Matrix3f K, const cv::Mat &depth, const cv::Mat &color
) {
  pcl::PointCloud<pcl::PointXYZRGB> pointCloud;

  int w = depth.cols;
  int h = depth.rows;

  float *pDepth = (float*)depth.data;
  float *pColor = (float*)color.data;

  for (int y = 0; y < h; ++y) {
    for (int x = 0; x < w; ++x) {
      size_t off = (y*w + x);
      size_t off3 = off * 3;

      // Check depth value validity
      float d = pDepth[x + y*w];
      if (d == 0.0f || std::isnan(d)) { continue; }

      // RGBXYZ point
      pcl::PointXYZRGB point;

      // Color
      point.b = max(0, min(255, (int)(pColor[off3  ]*255)));
      point.g = max(0, min(255, (int)(pColor[off3+1]*255)));
      point.r = max(0, min(255, (int)(pColor[off3+2]*255)));

      // Position
      Eigen::Vector3f pos = K.inverse() * Eigen::Vector3f(x*d, y*d, d);
      point.x = pos[0];
      point.y = pos[1];
      point.z = pos[2];

      pointCloud.push_back(point);
    }
  }

  return pointCloud;
}
Exemple #11
0
void computeSensorOffsetAndK(Eigen::Isometry3f &sensorOffset, Eigen::Matrix3f &cameraMatrix, ParameterCamera *cameraParam, int reduction) {
  sensorOffset = Isometry3f::Identity();
  cameraMatrix.setZero();
      
  int cmax = 4;
  int rmax = 3;
  for (int c=0; c<cmax; c++){
    for (int r=0; r<rmax; r++){
      sensorOffset.matrix()(r, c) = cameraParam->offset()(r, c);
      if (c<3)
	cameraMatrix(r,c) = cameraParam->Kcam()(r, c);
    }
  }
  sensorOffset.translation() = Vector3f(0.15f, 0.0f, 0.05f);
  Quaternionf quat = Quaternionf(0.5, -0.5, 0.5, -0.5);
  sensorOffset.linear() = quat.toRotationMatrix();
  sensorOffset.matrix().block<1, 4>(3, 0) << 0.0f, 0.0f, 0.0f, 1.0f;
	
  float scale = 1./reduction;
  cameraMatrix *= scale;
  cameraMatrix(2,2) = 1;
}
Exemple #12
0
 /** \brief Computes and sets the multilevel Shi-Tomasi Score \ref s_, considering a defined pyramid level interval.
  *
  * @param l1 - Start level (l1<l2)
  * @param l2 - End level (l1<l2)
  */
 void computeMultilevelShiTomasiScore(const int l1 = 0, const int l2 = nLevels_-1) const{
   H_.setZero();
   int count = 0;
   for(int i=l1;i<=l2;i++){
     if(isValidPatch_[i]){
       H_ += pow(0.25,i)*patches_[i].getHessian();
       count++;
     }
   }
   if(count > 0){
     const float dXX = H_(0,0)/(count*patchSize*patchSize);
     const float dYY = H_(1,1)/(count*patchSize*patchSize);
     const float dXY = H_(0,1)/(count*patchSize*patchSize);
     e0_ = 0.5 * (dXX + dYY - sqrtf((dXX + dYY) * (dXX + dYY) - 4 * (dXX * dYY - dXY * dXY)));
     e1_ = 0.5 * (dXX + dYY + sqrtf((dXX + dYY) * (dXX + dYY) - 4 * (dXX * dYY - dXY * dXY)));
     s_ = e0_;
   } else {
     e0_ = 0;
     e1_ = 0;
     s_ = -1;
   }
 }
Exemple #13
0
/**
 * ComputeCovarianceMatrix
 */
void ZAdaptiveNormals::computeCovarianceMatrix (const v4r::DataMatrix2D<Eigen::Vector3f> &cloud, const std::vector<int> &indices, const Eigen::Vector3f &mean, Eigen::Matrix3f &cov)
{
  Eigen::Vector3f pt;
  cov.setZero ();

  for (unsigned i = 0; i < indices.size (); ++i)
  {
    pt = cloud.data[indices[i]] - mean;

    cov(1,1) += pt[1] * pt[1];
    cov(1,2) += pt[1] * pt[2];
    cov(2,2) += pt[2] * pt[2];

    pt *= pt[0];
    cov(0,0) += pt[0];
    cov(0,1) += pt[1];
    cov(0,2) += pt[2];
  }

  cov(1,0) = cov(0,1);
  cov(2,0) = cov(0,2);
  cov(2,1) = cov(1,2);
}
Exemple #14
0
/**
 * computeCovarianceMatrix
 */
void PlaneEstimationRANSAC::computeCovarianceMatrix (const std::vector<Eigen::Vector3f> &pts, const std::vector<int> &indices, const Eigen::Vector3f &mean, Eigen::Matrix3f &cov)
{
  Eigen::Vector3f pt;
  cov.setZero ();

  for (unsigned i = 0; i < indices.size (); ++i)
  {
    pt = pts[indices[i]] - mean;

    cov(1,1) += pt[1] * pt[1];
    cov(1,2) += pt[1] * pt[2];

    cov(2,2) += pt[2] * pt[2];

    pt *= pt[0];
    cov(0,0) += pt[0];
    cov(0,1) += pt[1];
    cov(0,2) += pt[2];
  }

  cov(1,0) = cov(0,1);
  cov(2,0) = cov(0,2);
  cov(2,1) = cov(1,2);
}
int main(int argc, char **argv){

#if 0
  DOF6::TFLinkvf rot1,rot2;
  Eigen::Matrix4f tf1 = build_random_tflink(rot1,3);
  Eigen::Matrix4f tf2 = build_random_tflink(rot2,3);

  DOF6::DOF6_Source<DOF6::TFLinkvf,DOF6::TFLinkvf,float> abc(rot1.makeShared(), rot2.makeShared());
  abc.getRotation();
  abc.getTranslation();

  std::cout<<"tf1\n"<<tf1<<"\n";
  std::cout<<"tf2\n"<<tf2<<"\n";
  std::cout<<"tf1*2\n"<<tf1*tf2<<"\n";
  std::cout<<"tf2*1\n"<<tf2*tf1<<"\n";

  std::cout<<"tf1\n"<<rot1.getTransformation()<<"\n";
  std::cout<<"tf2\n"<<rot2.getTransformation()<<"\n";
  std::cout<<"tf1*2\n"<<(rot1+rot2).getTransformation()<<"\n";

  rot1.check();
  rot2.check();

  return 0;

  pcl::RotationFromCorrespondences rfc;
  Eigen::Vector3f n, nn, v,n2,n3,z,y,tv;
  float a = 0.1f;

  z.fill(0);y.fill(0);
  z(2)=1;y(1)=1;
  nn.fill(0);
  nn(0) = 1;
  Eigen::AngleAxisf aa(a,nn);

  nn.fill(100);

  n.fill(0);
  n(0) = 1;
  n2.fill(0);
  n2=n;
  n2(1) = 0.2;
  n3.fill(0);
  n3=n;
  n3(2) = 0.2;

  n2.normalize();
  n3.normalize();

  tv.fill(1);
  tv.normalize();

#if 0

#if 0
  rfc.add(n,aa.toRotationMatrix()*n+nn,
          1*n.cross(y),1*n.cross(z),
          1*(aa.toRotationMatrix()*n).cross(y),1*(aa.toRotationMatrix()*n).cross(z),
          1,1/sqrtf(3));
#else
  rfc.add(n,aa.toRotationMatrix()*n,
          0*n.cross(y),0*n.cross(z),
          0*(aa.toRotationMatrix()*n).cross(y),0*(aa.toRotationMatrix()*n).cross(z),
          1,0);
#endif

#if 1
  rfc.add(n2,aa.toRotationMatrix()*n2+nn,
          tv,tv,
          tv,tv,
          1,1);
#else
  rfc.add(n2,aa.toRotationMatrix()*n2+nn,
          1*n2.cross(y),1*n2.cross(z),
          1*(aa.toRotationMatrix()*n2).cross(y),1*(aa.toRotationMatrix()*n2).cross(z),
          1,1/sqrtf(3));
#endif

#else
  float f=1;
  Eigen::Vector3f cyl;
  cyl.fill(1);
  cyl(0)=1;
  Eigen::Matrix3f cylM;
  cylM.fill(0);
  cylM.diagonal() = cyl;
  rfc.add(n,aa.toRotationMatrix()*n,
          f*n.cross(y),f*n.cross(z),
          f*(aa.toRotationMatrix()*n).cross(y),f*(aa.toRotationMatrix()*n).cross(z),
          1,0);
  rfc.add(n2,aa.toRotationMatrix()*n2+nn,
          1*n2.cross(y),1*n2.cross(z),
          1*(aa.toRotationMatrix()*n2).cross(y),1*(aa.toRotationMatrix()*n2).cross(z),
          1,1);
#endif
  rfc.add(n3,aa.toRotationMatrix()*n3+nn,
          //tv,tv,
          //tv,tv,
          n3.cross(y),n3.cross(z),
          1*(aa.toRotationMatrix()*n3).cross(y),1*(aa.toRotationMatrix()*n3).cross(z),
          1,1);

  std::cout<<"comp matrix:\n"<<rfc.getTransformation()<<"\n\n";
  std::cout<<"real matrix:\n"<<aa.toRotationMatrix()<<"\n\n";

  return 0;

  //rfc.covariance_.normalize();
  rfc.covariance_ = (rfc.var_*rfc.covariance_.inverse().transpose()*rfc.covariance_);
  std::cout<<"comp matrix: "<<rfc.getTransformation()<<"\n\n";
  std::cout<<"real matrix: "<<aa.toRotationMatrix()*aa.toRotationMatrix()<<"\n\n";

  return 0;
#endif

  testing::InitGoogleTest(&argc, argv);
  return RUN_ALL_TESTS();
}
  void onGMM(const gaussian_mixture_model::GaussianMixture & mix)
  {
    visualization_msgs::MarkerArray msg;
    ROS_INFO("gmm_rviz_converter: Received message.");

    uint i;

    for (i = 0; i < mix.gaussians.size(); i++)
    {
      visualization_msgs::Marker marker;

      marker.header.frame_id = m_frame_id;
      marker.header.stamp = ros::Time::now();
      marker.ns = m_rviz_namespace;
      marker.id = i;
      marker.type = visualization_msgs::Marker::SPHERE;
      marker.action = visualization_msgs::Marker::ADD;
      marker.lifetime = ros::Duration();

      Eigen::Vector3f coords;
      for (uint ir = 0; ir < NUM_OUTPUT_COORDINATES; ir++)
        coords[ir] = m_conversion_mask[ir]->GetMean(m_conversion_mask,mix.gaussians[i]);
      marker.pose.position.x = coords.x();
      marker.pose.position.y = coords.y();
      marker.pose.position.z = coords.z();

      Eigen::Matrix3f covmat;
      for (uint ir = 0; ir < NUM_OUTPUT_COORDINATES; ir++)
        for (uint ic = 0; ic < NUM_OUTPUT_COORDINATES; ic++)
          covmat(ir,ic) = m_conversion_mask[ir]->GetCov(m_conversion_mask,mix.gaussians[i],ic);

      Eigen::EigenSolver<Eigen::Matrix3f> evsolver(covmat);

      Eigen::Matrix3f eigenvectors = evsolver.eigenvectors().real();
      if (eigenvectors.determinant() < 0.0)
        eigenvectors.col(0) = - eigenvectors.col(0);
      Eigen::Matrix3f rotation = eigenvectors;
      Eigen::Quaternionf quat = Eigen::Quaternionf(Eigen::AngleAxisf(rotation));

      marker.pose.orientation.x = quat.x();
      marker.pose.orientation.y = quat.y();
      marker.pose.orientation.z = quat.z();
      marker.pose.orientation.w = quat.w();

      Eigen::Vector3f eigenvalues = evsolver.eigenvalues().real();
      Eigen::Vector3f scale = Eigen::Vector3f(eigenvalues.array().abs().sqrt());
      if (m_normalize)
        scale.normalize();
      marker.scale.x = mix.weights[i] * scale.x() * m_scale;
      marker.scale.y = mix.weights[i] * scale.y() * m_scale;
      marker.scale.z = mix.weights[i] * scale.z() * m_scale;

      marker.color.a = 1.0;
      rainbow(float(i) / float(mix.gaussians.size()),marker.color.r,marker.color.g,marker.color.b);

      msg.markers.push_back(marker);
    }

    // this a waste of resources, but we need to delete old markers in some way
    // someone should add a "clear all" command to rviz
    // (using expiration time is not an option, here)
    for ( ; i < m_max_markers; i++)
    {
      visualization_msgs::Marker marker;
      marker.id = i;
      marker.action = visualization_msgs::Marker::DELETE;
      marker.lifetime = ros::Duration();
      marker.header.frame_id = m_frame_id;
      marker.header.stamp = ros::Time::now();
      marker.ns = m_rviz_namespace;
      msg.markers.push_back(marker);
    }

    m_pub.publish(msg);
    ROS_INFO("gmm_rviz_converter: Sent message.");
  }
Exemple #17
0
osgpcl::PointCloudGeometry* osgpcl::SurfelFactoryFF<PointT, NormalT, RadiusT>::buildGeometry(
        bool unique_state)   {

    typename pcl::PointCloud<NormalT>::ConstPtr normals = this->getInputCloud<NormalT>();
    typename pcl::PointCloud<PointT>::ConstPtr  xyz = this->getInputCloud<PointT>();
    typename pcl::PointCloud<RadiusT>::ConstPtr rads = this->getInputCloud<RadiusT>();

        if (xyz ==NULL) return NULL;
        if (normals ==NULL) return NULL;
        if (rads ==NULL) return NULL;

        if (xyz->points.size() != normals->points.size()) return NULL;
        if (rads->points.size() != normals->points.size()) return NULL;

          pcl::IndicesConstPtr indices = indices_;
        {
            bool rebuild_indices= false;
        if (indices_ == NULL) rebuild_indices=true;
        else if (indices_ ->size() != xyz->points.size() ) rebuild_indices=true;
        if (rebuild_indices){
            pcl::IndicesPtr idxs(new std::vector<int>);
            idxs->reserve(xyz->points.size());
            for(int i=0; i<xyz->points.size(); i++) idxs->push_back(i);
            indices= idxs;
        }
        }

        osg::Vec3Array* pts = new osg::Vec3Array;
        osg::Vec3Array* npts = new osg::Vec3Array;
        int fan_size = 1+ circle_cache.rows();
        pts->reserve(indices->size()*fan_size );
        npts->reserve(indices->size()*fan_size);

        osg::Geometry* geom = new osg::Geometry;

        for(int i=0, pstart=0; i<indices->size(); i++){
            const int& idx = (*indices)[i];
          const PointT& pt =  xyz->points[idx];
          const NormalT& npt = normals->points[idx];
          pts->push_back(osg::Vec3(pt.x, pt.y, pt.z));
          npts->push_back(osg::Vec3(npt.normal_x, npt.normal_y, npt.normal_z));

          pcl::Normal nt;

          Eigen::Matrix3f rot = Eigen::Matrix3f::Identity();
          rot.row(2) << npt.getNormalVector3fMap().transpose();
          Eigen::Vector3f ax2(1,0,0);
          if ( npt.getNormalVector3fMap().dot(ax2 ) > 0.1) {
              ax2 << 0,1,0;
              if ( npt.getNormalVector3fMap().dot(ax2 ) > 0.1) {
                  ax2 << 0,0,1;
              }
          }
          rot.row(1) << ax2.cross(npt.getNormalVector3fMap()).normalized().transpose();
          rot.row(0) = ( ax2 - ax2.dot(npt.getNormalVector3fMap() )*npt.getNormalVector3fMap() ).normalized();
          rot = rot*rads->points[idx].radius;

          for(int j=0; j<circle_cache.rows(); j++){
              Eigen::Vector3f apt = rot*circle_cache.row(j).transpose() + pt.getVector3fMap();
              pts->push_back(osg::Vec3(apt[0],apt[1],apt[2]));
              npts->push_back(osg::Vec3(npt.normal_x, npt.normal_y, npt.normal_z));
          }
            geom->addPrimitiveSet( new osg::DrawArrays( GL_TRIANGLE_FAN, pstart,  fan_size ) );
            pstart+= fan_size;
        }
        geom->setVertexArray( pts );
        geom->setNormalArray(npts);
        geom->setNormalBinding( osg::Geometry::BIND_PER_VERTEX );

        geom->setStateSet(stateset_);
        return geom;
}
Exemple #18
0
///
/// @par Detailed description 
/// ... 
/// @param [in, out] (param1) ...
/// @return ...
/// @note ...
Eigen::Matrix3f
sasmath::Math::
find_u(sasmol::SasMol &mol, int &frame)
{

    Eigen::Matrix3f r ;

    float rxx = (mol._x().col(frame)*_x().col(frame)).sum() ; 
    float rxy = (mol._x().col(frame)*_y().col(frame)).sum() ;
    float rxz = (mol._x().col(frame)*_z().col(frame)).sum() ;
    
    float ryx = (mol._y().col(frame)*_x().col(frame)).sum() ;
    float ryy = (mol._y().col(frame)*_y().col(frame)).sum() ;
    float ryz = (mol._y().col(frame)*_z().col(frame)).sum() ;

    float rzx = (mol._z().col(frame)*_x().col(frame)).sum() ;
    float rzy = (mol._z().col(frame)*_y().col(frame)).sum() ;
    float rzz = (mol._z().col(frame)*_z().col(frame)).sum() ;

    r << rxx,rxy,rxz,
         ryx,ryy,ryz,
         rzx,rzy,rzz;

    Eigen::Matrix3f rtr = r.transpose() * r ;
    
    Eigen::SelfAdjointEigenSolver<Eigen::Matrix3f> eigensolver(rtr);

    if (eigensolver.info() != Eigen::Success)
    {
          std::cout << "find_u calculation failed" << std::endl ;
    }

    Eigen::Matrix<float,3,1> uk ;  // eigenvalues
    Eigen::Matrix3f ak ;          // eigenvectors

    uk = eigensolver.eigenvalues() ; 
    ak = eigensolver.eigenvectors() ;

    Eigen::Matrix3f akt = ak.transpose() ;
    Eigen::Matrix3f new_ak  ;

    new_ak.row(0) = akt.row(2) ; //sort eigenvectors
    new_ak.row(1) = akt.row(1) ;
    new_ak.row(2) = akt.row(0) ;

    // python ak0 --> ak[2] ; ak1 --> ak[1] ; ak2 --> ak[0]

    //Eigen::Matrix<float,3,1> ak2 = akt.row(2).cross(akt.row(1)) ;

    Eigen::MatrixXf rak0 = (r * (akt.row(2).transpose())) ;
    Eigen::MatrixXf rak1 = (r * (akt.row(1).transpose())) ;

    Eigen::Matrix<float,3,1> urak0 ; 
    if(uk[2] == 0.0)
    { 
        urak0 = 1E15 * rak0 ;
    } 
    else
    {    
        urak0 = (1.0/sqrt(fabs(uk[2])))*rak0 ;
    }
    
    Eigen::Matrix<float,3,1> urak1 ; 
    if(uk[1] == 0.0)
    { 
        urak1 = 1E15 * rak1 ;
    } 
    else
    {    
        urak1 = (1.0/sqrt(fabs(uk[1])))*rak1 ;
    }

    Eigen::Matrix<float,3,1> urak2 = urak0.col(0).cross(urak1.col(0)) ;
    Eigen::Matrix3f bk ;

    bk << urak0,urak1,urak2;

    Eigen::Matrix3f u ;

    u =  (bk * new_ak).transpose() ;

    return u ;
/*
u = array([[-0.94513198,  0.31068658,  0.100992  ],
       [-0.3006246 , -0.70612572, -0.64110165],
       [-0.12786863, -0.63628635,  0.76078203]])
check:

u = 
-0.945133  0.310686  0.100992
-0.300624 -0.706126 -0.641102
-0.127869 -0.636287  0.760782 
*/
}
Exemple #19
0
void
LocalRecognitionPipeline<PointT>::correspondenceGrouping ()
{
    if(cg_algorithm_->getRequiresNormals() && (!scene_normals_ || scene_normals_->points.size() != scene_->points.size()))
        computeNormals<PointT>(scene_, scene_normals_, param_.normal_computation_method_);

    typename std::map<std::string, ObjectHypothesis<PointT> >::iterator it;
    for (it = obj_hypotheses_.begin (); it != obj_hypotheses_.end (); it++)
    {
        ObjectHypothesis<PointT> &oh = it->second;

        if(oh.model_scene_corresp_.size() < 3)
            continue;

        std::vector < pcl::Correspondences > corresp_clusters;
        cg_algorithm_->setSceneCloud (scene_);
        cg_algorithm_->setInputCloud (oh.model_->keypoints_);

        if(cg_algorithm_->getRequiresNormals())
            cg_algorithm_->setInputAndSceneNormals(oh.model_->kp_normals_, scene_normals_);

        //we need to pass the keypoints_pointcloud and the specific object hypothesis
        cg_algorithm_->setModelSceneCorrespondences (oh.model_scene_corresp_);
        cg_algorithm_->cluster (corresp_clusters);

        std::vector<Eigen::Matrix4f, Eigen::aligned_allocator<Eigen::Matrix4f> > new_transforms (corresp_clusters.size());
        typename pcl::registration::TransformationEstimationSVD < PointT, PointT > t_est;

        for (size_t i = 0; i < corresp_clusters.size(); i++)
            t_est.estimateRigidTransformation (*oh.model_->keypoints_, *scene_, corresp_clusters[i], new_transforms[i]);

        if(param_.merge_close_hypotheses_) {
            std::vector<Eigen::Matrix4f, Eigen::aligned_allocator<Eigen::Matrix4f> > merged_transforms (corresp_clusters.size());
            std::vector<bool> cluster_has_been_taken(corresp_clusters.size(), false);
            const double angle_thresh_rad = param_.merge_close_hypotheses_angle_ * M_PI / 180.f ;

            size_t kept=0;
            for (size_t i = 0; i < new_transforms.size(); i++) {

                if (cluster_has_been_taken[i])
                    continue;

                cluster_has_been_taken[i] = true;
                const Eigen::Vector3f centroid1 = new_transforms[i].block<3, 1> (0, 3);
                const Eigen::Matrix3f rot1 = new_transforms[i].block<3, 3> (0, 0);

                pcl::Correspondences merged_corrs = corresp_clusters[i];

                for(size_t j=i; j < new_transforms.size(); j++) {
                    const Eigen::Vector3f centroid2 = new_transforms[j].block<3, 1> (0, 3);
                    const Eigen::Matrix3f rot2 = new_transforms[j].block<3, 3> (0, 0);
                    const Eigen::Matrix3f rot_diff = rot2 * rot1.transpose();

                    double rotx = atan2(rot_diff(2,1), rot_diff(2,2));
                    double roty = atan2(-rot_diff(2,0), sqrt(rot_diff(2,1) * rot_diff(2,1) + rot_diff(2,2) * rot_diff(2,2)));
                    double rotz = atan2(rot_diff(1,0), rot_diff(0,0));
                    double dist = (centroid1 - centroid2).norm();

                    if ( (dist < param_.merge_close_hypotheses_dist_) && (rotx < angle_thresh_rad) && (roty < angle_thresh_rad) && (rotz < angle_thresh_rad) ) {
                        merged_corrs.insert( merged_corrs.end(), corresp_clusters[j].begin(), corresp_clusters[j].end() );
                        cluster_has_been_taken[j] = true;
                    }
                }

                t_est.estimateRigidTransformation (*oh.model_->keypoints_, *scene_, merged_corrs, merged_transforms[kept]);
                kept++;
            }
            merged_transforms.resize(kept);
            new_transforms = merged_transforms;
        }

        std::cout << "Merged " << corresp_clusters.size() << " clusters into " << new_transforms.size() << " clusters. Total correspondences: " << oh.model_scene_corresp_.size () << " " << it->first << std::endl;

        //        oh.visualize(*scene_);

        size_t existing_hypotheses = models_.size();
        models_.resize( existing_hypotheses + new_transforms.size(), oh.model_  );
        transforms_.insert(transforms_.end(), new_transforms.begin(), new_transforms.end());
    }
}
template<template<class > class Distance, typename PointT, typename FeatureT> bool
GlobalNNPipelineROS<Distance,PointT,FeatureT>::classifyROS (classifier_srv_definitions::classify::Request & req, classifier_srv_definitions::classify::Response & response)
    {
        typename pcl::PointCloud<PointT>::Ptr cloud (new pcl::PointCloud<PointT>());
        pcl::fromROSMsg(req.cloud, *cloud);
        this->input_ = cloud;

        pcl::PointCloud<pcl::PointXYZRGB>::Ptr pClusteredPCl (new pcl::PointCloud<pcl::PointXYZRGB>());
        pcl::copyPointCloud(*cloud, *pClusteredPCl);

        //clear all data from previous visualization steps and publish empty markers/point cloud
        for (size_t i=0; i < markerArray_.markers.size(); i++)
        {
            markerArray_.markers[i].action = visualization_msgs::Marker::DELETE;
        }
        vis_pub_.publish( markerArray_ );
        sensor_msgs::PointCloud2 scenePc2;
        vis_pc_pub_.publish(scenePc2);
        markerArray_.markers.clear();

        for(size_t cluster_id=0; cluster_id < req.clusters_indices.size(); cluster_id++)
        {
          std::vector<int> cluster_indices_int;
          Eigen::Vector4f centroid;
          Eigen::Matrix3f covariance_matrix;

          const float r = std::rand() % 255;
          const float g = std::rand() % 255;
          const float b = std::rand() % 255;

          this->indices_.resize(req.clusters_indices[cluster_id].data.size());
          for(size_t kk=0; kk < req.clusters_indices[cluster_id].data.size(); kk++)
          {
                this->indices_[kk] = static_cast<int>(req.clusters_indices[cluster_id].data[kk]);
                pClusteredPCl->at(req.clusters_indices[cluster_id].data[kk]).r = 0.8*r;
                pClusteredPCl->at(req.clusters_indices[cluster_id].data[kk]).g = 0.8*g;
                pClusteredPCl->at(req.clusters_indices[cluster_id].data[kk]).b = 0.8*b;
          }

          this->classify ();

          std::cout << "for cluster " << cluster_id << " with size " << cluster_indices_int.size() << ", I have following hypotheses: " << std::endl;

          object_perception_msgs::classification class_tmp;
          for(size_t kk=0; kk < this->categories_.size(); kk++)
          {
            std::cout << this->categories_[kk] << " with confidence " << this->confidences_[kk] << std::endl;
            std_msgs::String str_tmp;
            str_tmp.data = this->categories_[kk];
            class_tmp.class_type.push_back(str_tmp);
            class_tmp.confidence.push_back( this->confidences_[kk] );
          }
          response.class_results.push_back(class_tmp);

          typename pcl::PointCloud<PointT>::Ptr pClusterPCl_transformed (new pcl::PointCloud<PointT>());
          pcl::computeMeanAndCovarianceMatrix(*this->input_, cluster_indices_int, covariance_matrix, centroid);
          Eigen::Matrix3f eigvects;
          Eigen::Vector3f eigvals;
          pcl::eigen33(covariance_matrix, eigvects,  eigvals);

          Eigen::Vector3f centroid_transformed = eigvects.transpose() * centroid.topRows(3);

          Eigen::Matrix4f transformation_matrix = Eigen::Matrix4f::Zero(4,4);
          transformation_matrix.block<3,3>(0,0) = eigvects.transpose();
          transformation_matrix.block<3,1>(0,3) = -centroid_transformed;
          transformation_matrix(3,3) = 1;

          pcl::transformPointCloud(*this->input_, cluster_indices_int, *pClusterPCl_transformed, transformation_matrix);

          //pcl::transformPointCloud(*frame_, cluster_indices_int, *frame_eigencoordinates_, eigvects);
          PointT min_pt, max_pt;
          pcl::getMinMax3D(*pClusterPCl_transformed, min_pt, max_pt);
          std::cout << "Elongations along eigenvectors: " << max_pt.x - min_pt.x << ", " << max_pt.y - min_pt.y
                    << ", " << max_pt.z - min_pt.z << std::endl;
          geometry_msgs::Point32 centroid_ros;
          centroid_ros.x = centroid[0];
          centroid_ros.y = centroid[1];
          centroid_ros.z = centroid[2];
          response.centroid.push_back(centroid_ros);

          // calculating the bounding box of the cluster
          Eigen::Vector4f min;
          Eigen::Vector4f max;
          pcl::getMinMax3D (*this->input_, cluster_indices_int, min, max);

          object_perception_msgs::BBox bbox;
          geometry_msgs::Point32 pt;
          pt.x = min[0]; pt.y = min[1]; pt.z = min[2]; bbox.point.push_back(pt);
          pt.x = min[0]; pt.y = min[1]; pt.z = max[2]; bbox.point.push_back(pt);
          pt.x = min[0]; pt.y = max[1]; pt.z = min[2]; bbox.point.push_back(pt);
          pt.x = min[0]; pt.y = max[1]; pt.z = max[2]; bbox.point.push_back(pt);
          pt.x = max[0]; pt.y = min[1]; pt.z = min[2]; bbox.point.push_back(pt);
          pt.x = max[0]; pt.y = min[1]; pt.z = max[2]; bbox.point.push_back(pt);
          pt.x = max[0]; pt.y = max[1]; pt.z = min[2]; bbox.point.push_back(pt);
          pt.x = max[0]; pt.y = max[1]; pt.z = max[2]; bbox.point.push_back(pt);
          response.bbox.push_back(bbox);

          // getting the point cloud of the cluster
          typename pcl::PointCloud<PointT>::Ptr cluster (new pcl::PointCloud<PointT>);
          pcl::copyPointCloud(*this->input_, cluster_indices_int, *cluster);

          sensor_msgs::PointCloud2  pc2;
          pcl::toROSMsg (*cluster, pc2);
          response.cloud.push_back(pc2);

          // visualize the result as ROS topic
            visualization_msgs::Marker marker;
            marker.header.frame_id = camera_frame_;
            marker.header.stamp = ros::Time::now();
            //marker.header.seq = ++marker_seq_;
            marker.ns = "object_classification";
            marker.id = cluster_id;
            marker.type = visualization_msgs::Marker::TEXT_VIEW_FACING;
            marker.action = visualization_msgs::Marker::ADD;
            marker.pose.position.x = centroid_ros.x;
            marker.pose.position.y = centroid_ros.y - 0.1;
            marker.pose.position.z = centroid_ros.z - 0.1;
            marker.pose.orientation.x = 0;
            marker.pose.orientation.y = 0;
            marker.pose.orientation.z = 0;
            marker.pose.orientation.w = 1.0;
            marker.scale.z = 0.1;
            marker.color.a = 1.0;
            marker.color.r = r/255.f;
            marker.color.g = g/255.f;
            marker.color.b = b/255.f;
            std::stringstream marker_text;
            marker_text.precision(2);
            marker_text << this->categories_[0] << this->confidences_[0];
            marker.text = marker_text.str();
            markerArray_.markers.push_back(marker);
        }

        pcl::toROSMsg (*pClusteredPCl, scenePc2);
        vis_pc_pub_.publish(scenePc2);
        vis_pub_.publish( markerArray_ );

        response.clusters_indices = req.clusters_indices;
        return true;
    }
Exemple #21
0
 )
{
  Approx approx = Approx::custom().epsilon( 0.00001 );
  
  OSinput oi = OSinput(pdg2014::Mb, 80.399, 91.1876, 125.6, 173.5);
    
  SECTION( "MS mass from OS one,\\mu=M" ) 
    {

      // We use b-quark due to nl=2*NL
      bb<OS> dMt(oi, oi.MMb());

      SECTION( "Three-loop zm3 = c0 + c1*nl + c2*nl^2" )
        {
          
          Eigen::Matrix3f mM3;
          Eigen::Vector3f x3NL;
          
          x3NL(0) = dMt.x03(0,1);
          x3NL(1) = dMt.x03(1,1);
          x3NL(2) = dMt.x03(2,1);
          
          // c0 + c1*nl + c2*nl^2
          mM3 <<
            1, 0, 0,
            1, 2, 4,
            1, 4, 16;
          
          Eigen::Vector3f ci3 = pow(4,-3)*mM3.colPivHouseholderQr().solve(x3NL);
          
          // NL^0
Exemple #22
0
template<typename PointInT, typename PointNT, typename PointOutT> bool
pcl::OURCVFHEstimation<PointInT, PointNT, PointOutT>::sgurf (Eigen::Vector3f & centroid, Eigen::Vector3f & normal_centroid,
                                                               PointInTPtr & processed, std::vector<Eigen::Matrix4f, Eigen::aligned_allocator<Eigen::Matrix4f> > & transformations,
                                                               PointInTPtr & grid, pcl::PointIndices & indices)
{

  Eigen::Vector3f plane_normal;
  plane_normal[0] = -centroid[0];
  plane_normal[1] = -centroid[1];
  plane_normal[2] = -centroid[2];
  Eigen::Vector3f z_vector = Eigen::Vector3f::UnitZ ();
  plane_normal.normalize ();
  Eigen::Vector3f axis = plane_normal.cross (z_vector);
  double rotation = -asin (axis.norm ());
  axis.normalize ();

  Eigen::Affine3f transformPC (Eigen::AngleAxisf (static_cast<float> (rotation), axis));

  grid->points.resize (processed->points.size ());
  for (size_t k = 0; k < processed->points.size (); k++)
    grid->points[k].getVector4fMap () = processed->points[k].getVector4fMap ();

  pcl::transformPointCloud (*grid, *grid, transformPC);

  Eigen::Vector4f centroid4f (centroid[0], centroid[1], centroid[2], 0);
  Eigen::Vector4f normal_centroid4f (normal_centroid[0], normal_centroid[1], normal_centroid[2], 0);

  centroid4f = transformPC * centroid4f;
  normal_centroid4f = transformPC * normal_centroid4f;

  Eigen::Vector3f centroid3f (centroid4f[0], centroid4f[1], centroid4f[2]);

  Eigen::Vector4f farthest_away;
  pcl::getMaxDistance (*grid, indices.indices, centroid4f, farthest_away);
  farthest_away[3] = 0;

  float max_dist = (farthest_away - centroid4f).norm ();

  pcl::demeanPointCloud (*grid, centroid4f, *grid);

  Eigen::Matrix4f center_mat;
  center_mat.setIdentity (4, 4);
  center_mat (0, 3) = -centroid4f[0];
  center_mat (1, 3) = -centroid4f[1];
  center_mat (2, 3) = -centroid4f[2];

  Eigen::Matrix3f scatter;
  scatter.setZero ();
  float sum_w = 0.f;

  //for (int k = 0; k < static_cast<intgrid->points[k].getVector3fMap ();> (grid->points.size ()); k++)
  for (int k = 0; k < static_cast<int> (indices.indices.size ()); k++)
  {
    Eigen::Vector3f pvector = grid->points[indices.indices[k]].getVector3fMap ();
    float d_k = (pvector).norm ();
    float w = (max_dist - d_k);
    Eigen::Vector3f diff = (pvector);
    Eigen::Matrix3f mat = diff * diff.transpose ();
    scatter = scatter + mat * w;
    sum_w += w;
  }

  scatter /= sum_w;

  Eigen::JacobiSVD <Eigen::MatrixXf> svd (scatter, Eigen::ComputeFullV);
  Eigen::Vector3f evx = svd.matrixV ().col (0);
  Eigen::Vector3f evy = svd.matrixV ().col (1);
  Eigen::Vector3f evz = svd.matrixV ().col (2);
  Eigen::Vector3f evxminus = evx * -1;
  Eigen::Vector3f evyminus = evy * -1;
  Eigen::Vector3f evzminus = evz * -1;

  float s_xplus, s_xminus, s_yplus, s_yminus;
  s_xplus = s_xminus = s_yplus = s_yminus = 0.f;

  //disambiguate rf using all points
  for (int k = 0; k < static_cast<int> (grid->points.size ()); k++)
  {
    Eigen::Vector3f pvector = grid->points[k].getVector3fMap ();
    float dist_x, dist_y;
    dist_x = std::abs (evx.dot (pvector));
    dist_y = std::abs (evy.dot (pvector));

    if ((pvector).dot (evx) >= 0)
      s_xplus += dist_x;
    else
      s_xminus += dist_x;

    if ((pvector).dot (evy) >= 0)
      s_yplus += dist_y;
    else
      s_yminus += dist_y;

  }

  if (s_xplus < s_xminus)
    evx = evxminus;

  if (s_yplus < s_yminus)
    evy = evyminus;

  //select the axis that could be disambiguated more easily
  float fx, fy;
  float max_x = static_cast<float> (std::max (s_xplus, s_xminus));
  float min_x = static_cast<float> (std::min (s_xplus, s_xminus));
  float max_y = static_cast<float> (std::max (s_yplus, s_yminus));
  float min_y = static_cast<float> (std::min (s_yplus, s_yminus));

  fx = (min_x / max_x);
  fy = (min_y / max_y);

  Eigen::Vector3f normal3f = Eigen::Vector3f (normal_centroid4f[0], normal_centroid4f[1], normal_centroid4f[2]);
  if (normal3f.dot (evz) < 0)
    evz = evzminus;

  //if fx/y close to 1, it was hard to disambiguate
  //what if both are equally easy or difficult to disambiguate, namely fy == fx or very close

  float max_axis = std::max (fx, fy);
  float min_axis = std::min (fx, fy);

  if ((min_axis / max_axis) > axis_ratio_)
  {
    PCL_WARN("Both axis are equally easy/difficult to disambiguate\n");

    Eigen::Vector3f evy_copy = evy;
    Eigen::Vector3f evxminus = evx * -1;
    Eigen::Vector3f evyminus = evy * -1;

    if (min_axis > min_axis_value_)
    {
      //combination of all possibilities
      evy = evx.cross (evz);
      Eigen::Matrix4f trans = createTransFromAxes (evx, evy, evz, transformPC, center_mat);
      transformations.push_back (trans);

      evx = evxminus;
      evy = evx.cross (evz);
      trans = createTransFromAxes (evx, evy, evz, transformPC, center_mat);
      transformations.push_back (trans);

      evx = evy_copy;
      evy = evx.cross (evz);
      trans = createTransFromAxes (evx, evy, evz, transformPC, center_mat);
      transformations.push_back (trans);

      evx = evyminus;
      evy = evx.cross (evz);
      trans = createTransFromAxes (evx, evy, evz, transformPC, center_mat);
      transformations.push_back (trans);

    }
    else
    {
      //1-st case (evx selected)
      evy = evx.cross (evz);
      Eigen::Matrix4f trans = createTransFromAxes (evx, evy, evz, transformPC, center_mat);
      transformations.push_back (trans);

      //2-nd case (evy selected)
      evx = evy_copy;
      evy = evx.cross (evz);
      trans = createTransFromAxes (evx, evy, evz, transformPC, center_mat);
      transformations.push_back (trans);
    }
  }
  else
  {
    if (fy < fx)
    {
      evx = evy;
      fx = fy;
    }

    evy = evx.cross (evz);
    Eigen::Matrix4f trans = createTransFromAxes (evx, evy, evz, transformPC, center_mat);
    transformations.push_back (trans);

  }

  return true;
}
// Eigen types to GLM types
glm::mat3 eigen_matrix3f_to_glm_mat3(const Eigen::Matrix3f &m)
{
    return glm::make_mat3x3((const float *)m.data());
}
void
NMBasedCloudIntegration<PointT>::collectInfo ()
{
  size_t total_point_count = 0;
  for(size_t i = 0; i < input_clouds_.size(); i++)
    total_point_count += (indices_.empty() || indices_[i].empty()) ? input_clouds_[i]->size() : indices_[i].size();
  VLOG(1) << "Allocating memory for point information of " << total_point_count << "points. ";
  big_cloud_info_.resize(total_point_count);


  std::vector<pcl::PointCloud<PointT> > input_clouds_aligned (input_clouds_.size());
  std::vector<pcl::PointCloud<pcl::Normal> > input_normals_aligned (input_clouds_.size());

#pragma omp parallel for schedule(dynamic)
  for(size_t i=0; i < input_clouds_.size(); i++)
  {
      pcl::transformPointCloud(*input_clouds_[i], input_clouds_aligned[i], transformations_to_global_[i]);
      transformNormals(*input_normals_[i], input_normals_aligned[i], transformations_to_global_[i]);
  }

  size_t point_count = 0;
  for(size_t i=0; i < input_clouds_.size(); i++)
  {
    const pcl::PointCloud<PointT> &cloud_aligned = input_clouds_aligned[i];
    const pcl::PointCloud<pcl::Normal> &normals_aligned = input_normals_aligned[i];

    size_t kept_new_pts = 0;
    if (indices_.empty() || indices_[i].empty())
    {
      for(size_t jj=0; jj<cloud_aligned.points.size(); jj++)
      {
        if ( !pcl::isFinite(cloud_aligned.points[jj]) || !pcl::isFinite(normals_aligned.points[jj]) )
          continue;

        PointInfo &pt = big_cloud_info_[point_count + kept_new_pts];
        pt.pt = cloud_aligned.points[jj];
        pt.normal = normals_aligned.points[jj];
        pt.sigma_lateral = pt_properties_[i][jj][0];
        pt.sigma_axial = pt_properties_[i][jj][1];
        pt.distance_to_depth_discontinuity = pt_properties_[i][jj][2];
        pt.pt_idx = jj;
        kept_new_pts++;
      }
    }
    else
    {
      for(int idx : indices_[i])
      {
        if ( !pcl::isFinite(cloud_aligned.points[idx]) || !pcl::isFinite(normals_aligned.points[idx]) )
           continue;

        PointInfo &pt = big_cloud_info_[point_count + kept_new_pts];
        pt.pt = cloud_aligned.points[idx];
        pt.normal = normals_aligned.points[ idx ];
        pt.sigma_lateral = pt_properties_[i][idx][0];
        pt.sigma_axial = pt_properties_[i][idx][1];
        pt.distance_to_depth_discontinuity = pt_properties_[i][idx][2];
        pt.pt_idx = idx;
        kept_new_pts++;
      }
    }

    // compute and store remaining information
#pragma omp parallel for schedule (dynamic) firstprivate(i, point_count, kept_new_pts)
    for(size_t jj=0; jj<kept_new_pts; jj++)
    {
      PointInfo &pt = big_cloud_info_ [point_count + jj];
      pt.origin = i;

      Eigen::Matrix3f sigma = Eigen::Matrix3f::Zero(), sigma_aligned = Eigen::Matrix3f::Zero();
      sigma(0,0) = pt.sigma_lateral;
      sigma(1,1) = pt.sigma_lateral;
      sigma(2,2) = pt.sigma_axial;

      const Eigen::Matrix4f &tf = transformations_to_global_[ i ];
      Eigen::Matrix3f rotation = tf.block<3,3>(0,0); // or inverse?
      sigma_aligned = rotation * sigma * rotation.transpose();
      double det = sigma_aligned.determinant();

//      if( std::isfinite(det) && det>0)
//          pt.probability = 1 / sqrt(2 * M_PI * det);
//      else
//          pt.probability = std::numeric_limits<float>::min();

      if( std::isfinite(det) && det>0)
          pt.weight = det;
      else
          pt.weight = std::numeric_limits<float>::max();
    }

    point_count += kept_new_pts;
  }

  big_cloud_info_.resize(point_count);
}
void
v4r::MultiPlaneSegmentation<PointT>::segment(bool force_unorganized)
{
  models_.clear();

  if(input_->isOrganized() && !force_unorganized)
  {
    pcl::PointCloud<pcl::Normal>::Ptr normal_cloud (new pcl::PointCloud<pcl::Normal>);
    if(!normals_set_)
    {
        pcl::IntegralImageNormalEstimation<PointT, pcl::Normal> ne;
        ne.setNormalEstimationMethod (ne.COVARIANCE_MATRIX);
        ne.setMaxDepthChangeFactor (0.02f);
        ne.setNormalSmoothingSize (20.0f);
        ne.setBorderPolicy (pcl::IntegralImageNormalEstimation<PointT, pcl::Normal>::BORDER_POLICY_IGNORE);
        ne.setInputCloud (input_);
        ne.compute (*normal_cloud);
    }
    else
    {
        normal_cloud = normal_cloud_;
    }

    pcl::OrganizedMultiPlaneSegmentation<PointT, pcl::Normal, pcl::Label> mps;
    mps.setMinInliers (min_plane_inliers_);
    mps.setAngularThreshold (0.017453 * 2.f); // 2 degrees
    mps.setDistanceThreshold (0.01); // 1cm
    mps.setMaximumCurvature(0.002);
    mps.setInputNormals (normal_cloud);
    mps.setInputCloud (input_);

    std::vector<pcl::PlanarRegion<PointT>, Eigen::aligned_allocator<pcl::PlanarRegion<PointT> > > regions;
    std::vector<pcl::ModelCoefficients> model_coefficients;
    std::vector<pcl::PointIndices> inlier_indices;
    pcl::PointCloud<pcl::Label>::Ptr labels (new pcl::PointCloud<pcl::Label>);
    std::vector<pcl::PointIndices> label_indices;
    std::vector<pcl::PointIndices> boundary_indices;

    typename pcl::PlaneRefinementComparator<PointT, pcl::Normal, pcl::Label>::Ptr ref_comp (
                                                                                             new pcl::PlaneRefinementComparator<PointT,
                                                                                                 pcl::Normal, pcl::Label> ());
    ref_comp->setDistanceThreshold (0.01f, false);
    ref_comp->setAngularThreshold (0.017453 * 2.f);
    mps.setRefinementComparator (ref_comp);
    mps.segmentAndRefine (regions, model_coefficients, inlier_indices, labels, label_indices, boundary_indices);
    //mps.segment (model_coefficients, inlier_indices);

    //std::cout << model_coefficients.size() << std::endl;

    if(merge_planes_)
    {
      //sort planes by size
      //check if the first plane can be merged against the others, if yes, define a new plane combining both and add it to the cue

      typedef boost::adjacency_matrix<boost::undirectedS, int> GraphPlane;
      GraphPlane mergeable_planes (model_coefficients.size ());
      for(size_t i=0; i < model_coefficients.size(); i++)
      {

        Eigen::Vector3f plane_i = Eigen::Vector3f (model_coefficients[i].values[0], model_coefficients[i].values[1],
                                                   model_coefficients[i].values[2]);

        plane_i.normalize();
        for(size_t j=(i+1); j < model_coefficients.size(); j++)
        {
          Eigen::Vector3f plane_j = Eigen::Vector3f (model_coefficients[j].values[0], model_coefficients[j].values[1],
                                                     model_coefficients[j].values[2]);

          plane_j.normalize();

          //std::cout << "dot product:" << plane_i.dot(plane_j) << " diff:" << std::abs(model_coefficients[i].values[3] - model_coefficients[j].values[3]) << std::endl;
          if(plane_i.dot(plane_j) > 0.95)
          {
            if(std::abs(model_coefficients[i].values[3] - model_coefficients[j].values[3]) < 0.015)
            {
              boost::add_edge (static_cast<int>(i), static_cast<int>(j), mergeable_planes);
            }
          }
        }
      }

      boost::vector_property_map<int> components (boost::num_vertices (mergeable_planes));
      int n_cc = static_cast<int> (boost::connected_components (mergeable_planes, &components[0]));

      std::vector<int> cc_sizes;
      std::vector< std::vector<int> > cc_to_model_coeff;
      cc_sizes.resize (n_cc, 0);
      cc_to_model_coeff.resize(n_cc);

      for (size_t i = 0; i < model_coefficients.size (); i++)
      {
        cc_sizes[components[i]]++;
        cc_to_model_coeff[components[i]].push_back(i);
      }

      std::vector<pcl::ModelCoefficients> new_model_coefficients;
      std::vector<pcl::PointIndices> new_inlier_indices;

      for(size_t i=0; i < cc_sizes.size(); i++)
      {
        if(cc_sizes[i] < 2)
        {
          new_model_coefficients.push_back(model_coefficients[cc_to_model_coeff[i][0]]);
          new_inlier_indices.push_back(inlier_indices[cc_to_model_coeff[i][0]]);
          continue;
        }

        //std::cout << "going to merge CC:" << cc_sizes[i] << std::endl;
        pcl::ModelCoefficients model_coeff;
        model_coeff.values.resize(4);

        for(size_t k=0; k < 4; k++)
          model_coeff.values[k] = 0.f;

        pcl::PointIndices merged_indices;
        for(size_t j=0; j < cc_to_model_coeff[i].size(); j++)
        {
          for(size_t k=0; k < 4; k++)
            model_coeff.values[k] += model_coefficients[cc_to_model_coeff[i][j]].values[k];

          merged_indices.indices.insert(merged_indices.indices.end(), inlier_indices[cc_to_model_coeff[i][j]].indices.begin(),
                                                                      inlier_indices[cc_to_model_coeff[i][j]].indices.end());
        }

        for(size_t k=0; k < 4; k++)
          model_coeff.values[k] /= static_cast<float>(cc_to_model_coeff[i].size());

        new_model_coefficients.push_back(model_coeff);
        new_inlier_indices.push_back(merged_indices);
      }

      model_coefficients = new_model_coefficients;
      inlier_indices = new_inlier_indices;
    }

    for(size_t i=0; i < model_coefficients.size(); i++)
    {
      PlaneModel<PointT> pm;
      pm.coefficients_ = model_coefficients[i];
      pm.cloud_ = input_;
      pm.inliers_ = inlier_indices[i];

      //recompute coefficients based on distance to camera and normal?
      Eigen::Vector4f centroid;
      pcl::compute3DCentroid(*pm.cloud_, pm.inliers_, centroid);
      Eigen::Vector3f c(centroid[0],centroid[1],centroid[2]);

      Eigen::MatrixXf M_w(inlier_indices[i].indices.size(), 3);

      float sum_w = 0.f;
      for(size_t k=0; k < inlier_indices[i].indices.size(); k++)
      {
          const int &idx = inlier_indices[i].indices[k];
          float d_c = (pm.cloud_->points[idx].getVector3fMap()).norm();
          float w_k = std::max(1.f - std::abs(1.f - d_c), 0.f);
          //w_k = 1.f;
          M_w.row(k) = w_k * (pm.cloud_->points[idx].getVector3fMap() - c);
          sum_w += w_k;
      }

      Eigen::Matrix3f scatter;
      scatter.setZero ();
      scatter = M_w.transpose() * M_w;

      Eigen::JacobiSVD<Eigen::MatrixXf> svd(scatter, Eigen::ComputeFullV);
      //std::cout << svd.matrixV() << std::endl;

      Eigen::Vector3f n = svd.matrixV().col(2);
      //flip normal if required
      if(n.dot(c*-1) < 0)
          n = n * -1.f;

      float d = n.dot(c) * -1.f;
      //std::cout << "normal:" << n << std::endl;
      //std::cout << "d:" << d << std::endl;

      pm.coefficients_.values[0] = n[0];
      pm.coefficients_.values[1] = n[1];
      pm.coefficients_.values[2] = n[2];
      pm.coefficients_.values[3] = d;

      pcl::PointIndices clean_inlier_indices;
      float dist_threshold_ = 0.01f;

      for(size_t k=0; k < inlier_indices[i].indices.size(); k++)
      {
          const int &idx = inlier_indices[i].indices[k];
          Eigen::Vector3f p = pm.cloud_->points[idx].getVector3fMap();
          float val = n.dot(p) + d;

          if(std::abs(val) <= dist_threshold_)
              clean_inlier_indices.indices.push_back( idx );
      }

      pm.inliers_ = clean_inlier_indices;
      models_.push_back(pm);
    }
  }
  else
  {
    // Create the filtering object: downsample the dataset using a leaf size of 1cm
    pcl::VoxelGrid<PointT> vg;
    PointTCloudPtr cloud_filtered (new PointTCloud);
    vg.setInputCloud (input_);
    float leaf_size_ = 0.005f;
    float dist_threshold_ = 0.01f;
    vg.setLeafSize (leaf_size_, leaf_size_, leaf_size_);
    vg.filter (*cloud_filtered);

    std::vector<bool> pixel_has_not_been_labelled( cloud_filtered->points.size(), true );

    // Create the segmentation object for the planar model and set all the parameters
    pcl::SACSegmentation<PointT> seg;
    pcl::ModelCoefficients coefficients;
    seg.setOptimizeCoefficients (true);
    seg.setModelType (pcl::SACMODEL_PLANE);
    seg.setMethodType (pcl::SAC_RANSAC);
    seg.setMaxIterations (1000);
    seg.setDistanceThreshold (dist_threshold_);

    PointTCloudPtr cloud_filtered_leftover (new PointTCloud (*cloud_filtered));

    while (1)
    {
      // Segment the largest planar component from the remaining cloud
      seg.setInputCloud (cloud_filtered_leftover);
      pcl::PointIndices inliers_in_leftover;
      seg.segment (inliers_in_leftover, coefficients);

      std::cout << "inliers in left over: " << inliers_in_leftover.indices.size() << " of " << cloud_filtered_leftover->points.size() << std::endl;

      if ( (int)inliers_in_leftover.indices.size () < min_plane_inliers_) // Could not estimate a(nother) planar model big enough for the given cloud.
        break;


      // make indices correspond to complete downsampled cloud
      pcl::PointIndices indices_in_original_cloud;
      size_t current_index_in_leftover = 0;
      size_t px=0;
      indices_in_original_cloud.indices.resize(inliers_in_leftover.indices.size());
      for(size_t inl_id=0; inl_id < inliers_in_leftover.indices.size(); inl_id++) {    // assumes indices are sorted in ascending order
          bool found = false;
          do {
              if( pixel_has_not_been_labelled[px] ) {
                  if( current_index_in_leftover == inliers_in_leftover.indices [inl_id] ) {
                      indices_in_original_cloud.indices[ inl_id ] = px;
                      found = true;
                  }
                  current_index_in_leftover++;
              }
              px++;
          } while( !found );
      }

      for(size_t i=0; i<indices_in_original_cloud.indices.size(); i++)
          pixel_has_not_been_labelled[ indices_in_original_cloud.indices[i] ] = false;


      //save coefficients
        PlaneModel<PointT> pm;
        pm.coefficients_ = coefficients;
        pm.cloud_ = cloud_filtered;
        pm.inliers_ = indices_in_original_cloud;
        models_.push_back(pm);

        pcl::copyPointCloud(*cloud_filtered, pixel_has_not_been_labelled, *cloud_filtered_leftover);
    }

    std::cout << "Number of planes found:" << models_.size() << "organized:" << static_cast<int>(input_->isOrganized() && !force_unorganized) << std::endl;
  }
}
Exemple #26
0
  void PwnTracker::processFrame(const DepthImage& depthImage_, 
				const Eigen::Isometry3f& sensorOffset_, 
				const Eigen::Matrix3f& cameraMatrix_,
				const Eigen::Isometry3f& initialGuess){
    int r,c;
    Eigen::Matrix3f scaledCameraMatrix = cameraMatrix_;
    _currentCloudOffset = sensorOffset_;
    _currentCameraMatrix = cameraMatrix_;
    _currentDepthImage = depthImage_;
    _currentCloud = makeCloud(r,c,scaledCameraMatrix,_currentCloudOffset,_currentDepthImage);
    
    bool newFrame = false;
    bool newRelation = false;
    PwnTrackerFrame* currentTrackerFrame=0;
    Eigen::Isometry3d relationMean;
    if (_previousCloud){
      _aligner->setCurrentSensorOffset(_currentCloudOffset);
      _aligner->setCurrentFrame(_currentCloud);
      _aligner->setReferenceSensorOffset(_previousCloudOffset);
      _aligner->setReferenceFrame(_previousCloud);

      _aligner->correspondenceFinder()->setImageSize(r,c);
      PinholePointProjector* alprojector=dynamic_cast<PinholePointProjector*>(_aligner->projector());
      alprojector->setCameraMatrix(scaledCameraMatrix);
      alprojector->setImageSize(r,c);

      Eigen::Isometry3f guess=_previousCloudTransform.inverse()*_globalT*initialGuess;
      _aligner->setInitialGuess(guess);
      double t0, t1;
      t0 = g2o::get_time();
      _aligner->align();

      t1 = g2o::get_time();
      std::cout << "Time: " << t1 - t0 << " seconds " << std::endl;
 
      cerr << "inliers: " << _aligner->inliers() << endl;
      // cerr << "chi2: " << _aligner->error() << endl;
      // cerr << "chi2/inliers: " << _aligner->error()/_aligner->inliers() << endl;
      // cerr << "initialGuess: " << t2v(guess).transpose() << endl;
      // cerr << "transform   : " << t2v(_aligner->T()).transpose() << endl;
      if (_aligner->inliers()>0){
    	_globalT = _previousCloudTransform*_aligner->T();
    	//cerr << "TRANSFORM FOUND" <<  endl;
      } else {
    	//cerr << "FAILURE" <<  endl;
    	_globalT = _globalT*guess;
      }
      convertScalar(relationMean, _aligner->T());
      if (! (_counter%50) ) {
    	Eigen::Matrix3f R = _globalT.linear();
    	Eigen::Matrix3f E = R.transpose() * R;
    	E.diagonal().array() -= 1;
    	_globalT.linear() -= 0.5 * R * E;
      }
      _globalT.matrix().row(3) << 0,0,0,1;
 
      newAlignmentCallbacks(_globalT, _aligner->T(), _aligner->inliers(), _aligner->error());
			   
      int maxInliers = r*c;
      float inliersFraction = (float) _aligner->inliers()/(float) maxInliers;
      cerr << "inliers/maxinliers/fraction: " << _aligner->inliers() << "/" << maxInliers << "/" << inliersFraction << endl;
      if (inliersFraction<_newFrameInliersFraction){
	newFrame = true;
	newRelation = true;

	// char filename[1024];
	// sprintf (filename, "frame-%05d.pwn", _numKeyframes);
	// frame->save(filename,1,true,_globalT);

	_numKeyframes ++;
	if (!_cache) 
	  delete _previousCloud;
	else{
	  _previousCloudHandle.release();
	}
	//_cache->unlock(_previousTrackerFrame);
	// _aligner->setReferenceSensorOffset(_currentCloudOffset);
	// _aligner->setReferenceFrame(_currentCloud);
	_previousCloud = _currentCloud;
	_previousCloudTransform = _globalT;
	// cerr << "new frame added (" << _numKeyframes <<  ")" << endl;
	// cerr << "inliers: " << _aligner->inliers() << endl;
	// cerr << "maxInliers: " << maxInliers << endl;
	// cerr << "chi2: " << _aligner->error() << endl;
	// cerr << "chi2/inliers: " << _aligner->error()/_aligner->inliers() << endl;
	// cerr << "initialGuess: " << t2v(guess).transpose() << endl;
	// cerr << "transform   : " << t2v(_aligner->T()).transpose() << endl;
	// cerr << "globalTransform   : " << t2v(_globalT).transpose() << endl;
      } else { // previous frame but offset is small
	delete _currentCloud;
	_currentCloud = 0;
      }
    } else { // first frame
      //ser.writeObject(*manager);
      newFrame = true;
      // _aligner->setReferenceSensorOffset(_currentCloudOffset);
      // _aligner->setReferenceFrame(_currentCloud);
      _previousCloud = _currentCloud;
      _previousCloudTransform = _globalT;
      _previousCloudOffset = _currentCloudOffset;
      _numKeyframes ++;
      /*Eigen::Isometry3f t = _globalT;
	geometry_msgs::Point p;
	p.x = t.translation().x();
	p.y = t.translation().y();
	p.z = t.translation().z();
	m_odometry.points.push_back(p);
      */
    }
    _counter++;

    if (newFrame) {
      //cerr << "maing new frame, previous: " << _previousTrackerFrame << endl;
      currentTrackerFrame = new PwnTrackerFrame(_manager);
      //currentTrackerFrame->cloud.set(cloud);
      currentTrackerFrame->cloud=_currentCloud;
      currentTrackerFrame->sensorOffset = _currentCloudOffset;
      boss_map::ImageBLOB* depthBLOB=new boss_map::ImageBLOB();
      DepthImage_convert_32FC1_to_16UC1(depthBLOB->cvImage(),_currentDepthImage);
      //depthImage.toCvMat(depthBLOB->cvImage());
      depthBLOB->adjustFormat();
      currentTrackerFrame->depthImage.set(depthBLOB);
      
      boss_map::ImageBLOB* normalThumbnailBLOB=new boss_map::ImageBLOB();
      boss_map::ImageBLOB* depthThumbnailBLOB=new boss_map::ImageBLOB();
      makeThumbnails(depthThumbnailBLOB->cvImage(), normalThumbnailBLOB->cvImage(), _currentCloud, 
		    _currentDepthImage.rows, 
		    _currentDepthImage.cols,
		    _currentCloudOffset,
		    _currentCameraMatrix, 
		    0.1);
      normalThumbnailBLOB->adjustFormat();
      depthThumbnailBLOB->adjustFormat();
      
      currentTrackerFrame->depthThumbnail.set(depthThumbnailBLOB);
      currentTrackerFrame->normalThumbnail.set(normalThumbnailBLOB);
      currentTrackerFrame->cameraMatrix = _currentCameraMatrix;
      currentTrackerFrame->imageRows = _currentDepthImage.rows;
      currentTrackerFrame->imageCols = _currentDepthImage.cols;
      Eigen::Isometry3d _iso;
      convertScalar(_iso, _globalT);
      currentTrackerFrame->setTransform(_iso);
      convertScalar(currentTrackerFrame->sensorOffset, _currentCloudOffset);
      currentTrackerFrame->setSeq(_seq++);
      _manager->addNode(currentTrackerFrame);
      //cerr << "AAAA" << endl;

      if (_cache)
	_currentCloudHandle=_cache->get(currentTrackerFrame);
      //cerr << "BBBB" << endl;
      //_cache->lock(currentTrackerFrame);
      newFrameCallbacks(currentTrackerFrame);
      currentTrackerFrame->depthThumbnail.set(0);
      currentTrackerFrame->normalThumbnail.set(0);
      currentTrackerFrame->depthImage.set(0);
    }

    if (newRelation) {
      PwnTrackerRelation* rel = new PwnTrackerRelation(_manager);
      rel->setTransform(relationMean);
      Matrix6d omega;
      convertScalar(omega, _aligner->omega());
      omega.setIdentity();
      omega *= 100;
      rel->setInformationMatrix(omega);
      rel->setTo(currentTrackerFrame);
      rel->setFrom(_previousTrackerFrame);
      //cerr << "saved relation" << _previousTrackerFrame << " " << currentTrackerFrame << endl;
      _manager->addRelation(rel);
      newRelationCallbacks(rel);
      //ser.writeObject(*rel);
    }

    if (currentTrackerFrame) {
      _previousTrackerFrame = currentTrackerFrame;
    }
  }
Exemple #27
0
template <typename PointInT, typename PointOutT> void
pcl::ROPSEstimation <PointInT, PointOutT>::computeLRF (const PointInT& point, const std::set <unsigned int>& local_triangles, Eigen::Matrix3f& lrf_matrix) const
{
  const unsigned int number_of_triangles = static_cast <unsigned int> (local_triangles.size ());

  std::vector<Eigen::Matrix3f, Eigen::aligned_allocator<Eigen::Matrix3f> > scatter_matrices (number_of_triangles);
  std::vector <float> triangle_area (number_of_triangles);
  std::vector <float> distance_weight (number_of_triangles);

  float total_area = 0.0f;
  const float coeff = 1.0f / 12.0f;
  const float coeff_1_div_3 = 1.0f / 3.0f;

  Eigen::Vector3f feature_point (point.x, point.y, point.z);

  std::set <unsigned int>::const_iterator it;
  unsigned int i_triangle = 0;
  for (it = local_triangles.begin (), i_triangle = 0; it != local_triangles.end (); it++, i_triangle++)
  {
    Eigen::Vector3f pt[3];
    for (unsigned int i_vertex = 0; i_vertex < 3; i_vertex++)
    {
      const unsigned int index = triangles_[*it].vertices[i_vertex];
      pt[i_vertex] (0) = surface_->points[index].x;
      pt[i_vertex] (1) = surface_->points[index].y;
      pt[i_vertex] (2) = surface_->points[index].z;
    }

    const float curr_area = ((pt[1] - pt[0]).cross (pt[2] - pt[0])).norm ();
    triangle_area[i_triangle] = curr_area;
    total_area += curr_area;

    distance_weight[i_triangle] = pow (support_radius_ - (feature_point - (pt[0] + pt[1] + pt[2]) * coeff_1_div_3).norm (), 2.0f);

    Eigen::Matrix3f curr_scatter_matrix;
    curr_scatter_matrix.setZero ();
    for (unsigned int i_pt = 0; i_pt < 3; i_pt++)
    {
      Eigen::Vector3f vec = pt[i_pt] - feature_point;
      curr_scatter_matrix += vec * (vec.transpose ());
      for (unsigned int j_pt = 0; j_pt < 3; j_pt++)
        curr_scatter_matrix += vec * ((pt[j_pt] - feature_point).transpose ());
    }
    scatter_matrices[i_triangle] = coeff * curr_scatter_matrix;
  }

  if (std::abs (total_area) < std::numeric_limits <float>::epsilon ())
    total_area = 1.0f / total_area;
  else
    total_area = 1.0f;

  Eigen::Matrix3f overall_scatter_matrix;
  overall_scatter_matrix.setZero ();
  std::vector<float> total_weight (number_of_triangles);
  const float denominator = 1.0f / 6.0f;
  for (unsigned int i_triangle = 0; i_triangle < number_of_triangles; i_triangle++)
  {
    float factor = distance_weight[i_triangle] * triangle_area[i_triangle] * total_area;
    overall_scatter_matrix += factor * scatter_matrices[i_triangle];
    total_weight[i_triangle] = factor * denominator;
  }

  Eigen::Vector3f v1, v2, v3;
  computeEigenVectors (overall_scatter_matrix, v1, v2, v3);

  float h1 = 0.0f;
  float h3 = 0.0f;
  for (it = local_triangles.begin (), i_triangle = 0; it != local_triangles.end (); it++, i_triangle++)
  {
    Eigen::Vector3f pt[3];
    for (unsigned int i_vertex = 0; i_vertex < 3; i_vertex++)
    {
      const unsigned int index = triangles_[*it].vertices[i_vertex];
      pt[i_vertex] (0) = surface_->points[index].x;
      pt[i_vertex] (1) = surface_->points[index].y;
      pt[i_vertex] (2) = surface_->points[index].z;
    }

    float factor1 = 0.0f;
    float factor3 = 0.0f;
    for (unsigned int i_pt = 0; i_pt < 3; i_pt++)
    {
      Eigen::Vector3f vec = pt[i_pt] - feature_point;
      factor1 += vec.dot (v1);
      factor3 += vec.dot (v3);
    }
    h1 += total_weight[i_triangle] * factor1;
    h3 += total_weight[i_triangle] * factor3;
  }

  if (h1 < 0.0f) v1 = -v1;
  if (h3 < 0.0f) v3 = -v3;

  v2 = v3.cross (v1);

  lrf_matrix.row (0) = v1;
  lrf_matrix.row (1) = v2;
  lrf_matrix.row (2) = v3;
}
void 
pcl::getCameraMatrixFromProjectionMatrix (
    const Eigen::Matrix<float, 3, 4, Eigen::RowMajor>& projection_matrix, 
    Eigen::Matrix3f& camera_matrix)
{
  Eigen::Matrix3f KR = projection_matrix.topLeftCorner <3, 3> ();

  Eigen::Matrix3f KR_KRT = KR * KR.transpose ();
  
  Eigen::Matrix3f cam = KR_KRT / KR_KRT.coeff (8);

  memset (&(camera_matrix.coeffRef (0)), 0, sizeof (Eigen::Matrix3f::Scalar) * 9);
  camera_matrix.coeffRef (8) = 1.0;
  
  if (camera_matrix.Flags & Eigen::RowMajorBit)
  {
    camera_matrix.coeffRef (2) = cam.coeff (2);
    camera_matrix.coeffRef (5) = cam.coeff (5);
    camera_matrix.coeffRef (4) = static_cast<float> (std::sqrt (cam.coeff (4) - cam.coeff (5) * cam.coeff (5)));
    camera_matrix.coeffRef (1) = (cam.coeff (1) - cam.coeff (2) * cam.coeff (5)) / camera_matrix.coeff (4);
    camera_matrix.coeffRef (0) = static_cast<float> (std::sqrt (cam.coeff (0) - camera_matrix.coeff (1) * camera_matrix.coeff (1) - cam.coeff (2) * cam.coeff (2)));
  }
  else
  {
    camera_matrix.coeffRef (6) = cam.coeff (2);
    camera_matrix.coeffRef (7) = cam.coeff (5);
    camera_matrix.coeffRef (4) = static_cast<float> (std::sqrt (cam.coeff (4) - cam.coeff (5) * cam.coeff (5)));
    camera_matrix.coeffRef (3) = (cam.coeff (1) - cam.coeff (2) * cam.coeff (5)) / camera_matrix.coeff (4);
    camera_matrix.coeffRef (0) = static_cast<float> (std::sqrt (cam.coeff (0) - camera_matrix.coeff (3) * camera_matrix.coeff (3) - cam.coeff (2) * cam.coeff (2)));
  }
}
bool checkCloud(const sensor_msgs::PointCloud2& cloud_msg,
                typename pcl::PointCloud<T>::Ptr hand_cloud,
                //typename pcl::PointCloud<T>::Ptr finger_cloud,
                const std::string& frame_id,
                tf::Vector3& hand_position,
                tf::Vector3& arm_position,
                tf::Vector3& arm_direction)
{  
  typename pcl::PointCloud<T>::Ptr cloud(new pcl::PointCloud<T>);
  pcl::fromROSMsg(cloud_msg, *cloud);

  if((cloud->points.size() < g_config.min_cluster_size) ||
     (cloud->points.size() > g_config.max_cluster_size))
    return false;

  pcl::PCA<T> pca;
  pca.setInputCloud(cloud);
  Eigen::Vector4f mean = pca.getMean();

  if((mean.coeff(0) < g_config.min_x) || (mean.coeff(0) > g_config.max_x)) return false;
  if((mean.coeff(1) < g_config.min_y) || (mean.coeff(1) > g_config.max_y)) return false;
  if((mean.coeff(2) < g_config.min_z) || (mean.coeff(2) > g_config.max_z)) return false;

  Eigen::Vector3f eigen_value = pca.getEigenValues();
  double ratio = eigen_value.coeff(0) / eigen_value.coeff(1);

  if((ratio < g_config.min_eigen_value_ratio) || (ratio > g_config.max_eigen_value_ratio)) return false;

  T search_point;
  Eigen::Matrix3f ev = pca.getEigenVectors();
  Eigen::Vector3f main_axis(ev.coeff(0, 0), ev.coeff(1, 0), ev.coeff(2, 0));
  main_axis.normalize();
  arm_direction.setX(main_axis.coeff(0));
  arm_direction.setY(main_axis.coeff(1));
  arm_direction.setZ(main_axis.coeff(2));
  arm_position.setX(mean.coeff(0));
  arm_position.setY(mean.coeff(1));
  arm_position.setZ(mean.coeff(2));

  main_axis = (-main_axis * 0.3) + Eigen::Vector3f(mean.coeff(0), mean.coeff(1), mean.coeff(2));
  search_point.x = main_axis.coeff(0);
  search_point.y = main_axis.coeff(1);
  search_point.z = main_axis.coeff(2);



  //find hand
  pcl::KdTreeFLANN<T> kdtree;
  kdtree.setInputCloud(cloud);

  //find the closet point from the serach_point
  std::vector<int> point_indeices(1);
  std::vector<float> point_distances(1);
  if ( kdtree.nearestKSearch (search_point, 1, point_indeices, point_distances) > 0 )
  {
    //update search point
    search_point = cloud->points[point_indeices[0]];

    //show seach point
    if(g_marker_array_pub.getNumSubscribers() != 0)
    {
      pushSimpleMarker(search_point.x, search_point.y, search_point.z,
                       1.0, 0, 0,
                       0.02,
                       g_marker_id, g_marker_array, frame_id);
    }

    //hand
    point_indeices.clear();
    point_distances.clear();
    kdtree.radiusSearch(search_point, g_config.hand_lenght, point_indeices, point_distances);
    for (size_t i = 0; i < point_indeices.size (); ++i)
    {
      hand_cloud->points.push_back(cloud->points[point_indeices[i]]);
      hand_cloud->points.back().r = 255;
      hand_cloud->points.back().g = 0;
      hand_cloud->points.back().b = 0;
    }

    Eigen::Vector4f centroid;
    pcl::compute3DCentroid(*hand_cloud, centroid);

    if(g_marker_array_pub.getNumSubscribers() != 0)
    {
      pushSimpleMarker(centroid.coeff(0), centroid.coeff(1), centroid.coeff(2),
                       0.0, 1.0, 0,
                       0.02,
                       g_marker_id, g_marker_array, frame_id);
    }

    hand_position.setX(centroid.coeff(0));
    hand_position.setY(centroid.coeff(1));
    hand_position.setZ(centroid.coeff(2));

#if 0
    //fingers
    search_point.x = centroid.coeff(0);
    search_point.y = centroid.coeff(1);
    search_point.z = centroid.coeff(2);
    std::vector<int> point_indeices_inner;
    std::vector<float> point_distances_inner;
    kdtree.radiusSearch(search_point, 0.07, point_indeices_inner, point_distances_inner);

    std::vector<int> point_indeices_outter;
    std::vector<float> point_distances_outter;
    kdtree.radiusSearch(search_point, 0.1, point_indeices_outter, point_distances_outter);

    //ROS_INFO("before %d %d", point_indeices_inner.size(), point_indeices_outter.size());

    std::vector<int>::iterator it;
    for(size_t i = 0; i < point_indeices_inner.size(); i++)
    {

      it =  std::find(point_indeices_outter.begin(), point_indeices_outter.end(), point_indeices_inner[i]);
      if(it != point_indeices_outter.end())
      {
        point_indeices_outter.erase(it);
      }
    }

    //ROS_INFO("after %d %d", point_indeices_inner.size(), point_indeices_outter.size());

    //ROS_DEBUG_THROTTLE(1.0, "found %lu", point_indeices.size ());
    for (size_t i = 0; i < point_indeices_outter.size (); ++i)
    {
      finger_cloud->points.push_back(cloud->points[point_indeices_outter[i]]);
      finger_cloud->points.back().r = 255;
      finger_cloud->points.back().g = 0;
      finger_cloud->points.back().b = 0;
    }
#endif

  }
  else
  {    
    return false;
  }

  if(g_marker_array_pub.getNumSubscribers() != 0)
  {
    pushEigenMarker<T>(pca, g_marker_id, g_marker_array, 0.1, frame_id);
  }


  return true;
}
Exemple #30
0
  void ViewerState::load(const std::string& filename){
    clear();
    listWidget->clear();
    graph->clear();
    graph->load(filename.c_str());

    vector<int> vertexIds(graph->vertices().size());
    int k=0;
    for (OptimizableGraph::VertexIDMap::iterator it = graph->vertices().begin(); it != graph->vertices().end(); ++it) {
      vertexIds[k++] = (it->first);
    }

    sort(vertexIds.begin(), vertexIds.end());

    listAssociations.clear();
    size_t maxCount = 20000;
    for(size_t i = 0; i < vertexIds.size() &&  i< maxCount; ++i) {
      OptimizableGraph::Vertex* _v = graph->vertex(vertexIds[i]);
      g2o::VertexSE3* v = dynamic_cast<g2o::VertexSE3*>(_v);
      if (! v)
	continue;
      OptimizableGraph::Data* d = v->userData();
      while(d) {
	RGBDData* rgbdData = dynamic_cast<RGBDData*>(d);
	if (!rgbdData){
	  d=d->next();
	  continue;
	}
	// retrieve from the rgb data the index of the parameter
	int paramIndex = rgbdData->paramIndex();
	// retrieve from the graph the parameter given the index  
	g2o::Parameter* _cameraParam = graph->parameter(paramIndex);
	// attempt a cast to a parameter camera  
	ParameterCamera* cameraParam = dynamic_cast<ParameterCamera*>(_cameraParam);
	if (! cameraParam){
	  cerr << "shall thou be damned forever" << endl;
	  return;
	}
	// yayyy we got the parameter
	Eigen::Matrix3f cameraMatrix;
	Eigen::Isometry3f sensorOffset;
	cameraMatrix.setZero();
      
	int cmax = 4;
	int rmax = 3;
	for (int c=0; c<cmax; c++){
	  for (int r=0; r<rmax; r++){
	    sensorOffset.matrix()(r,c)= cameraParam->offset()(r, c);
	    if (c<3)
	      cameraMatrix(r,c) = cameraParam->Kcam()(r, c);
	  }
	}
	char buf[1024];
	sprintf(buf,"%d",v->id());
	QString listItem(buf);
	listAssociations.push_back(rgbdData);
	listWidget->addItem(listItem);
	d=d->next();
      }
    }

  }