#include <factor1Pose1Landmark3d.hpp>

Inheritance diagram for mrob::Factor1Pose1Landmark3d:

Collaboration diagram for mrob::Factor1Pose1Landmark3d:

Public Member Functions
	Factor1Pose1Landmark3d (const Mat31 &observation, std::shared_ptr< Node > &nodePose, std::shared_ptr< Node > &nodeLandmark, const Mat3 &obsInf, bool initializeLandmark=false, Factor::robustFactorType robust_type=Factor::robustFactorType::QUADRATIC)

void	evaluate_residuals () override

void	evaluate_jacobians () override

void	evaluate_chi2 () override

void	print () const

MatRefConst	get_obs () const

VectRefConst	get_residual () const

MatRefConst	get_information_matrix () const

MatRefConst	get_jacobian ([[maybe_unused]] mrob::factor_id_t id=0) const

Public Member Functions inherited from mrob::Factor
	Factor (uint_t dim, uint_t allNodesDim, robustFactorType factor_type=QUADRATIC, uint_t potNumberNodes=5)

matData_t	get_chi2 () const

factor_id_t	get_id () const

void	set_id (factor_id_t id)

uint_t	get_dim_obs () const

void	set_dim_obs (uint_t dim)

uint_t	get_all_nodes_dim () const

void	set_all_nodes_dim (uint_t dim)

const std::vector< std::shared_ptr< Node > > *	get_neighbour_nodes (void) const

matData_t	evaluate_robust_weight (matData_t u, matData_t params=0.0)

Protected Attributes
Mat31	obs_

Mat31	r_

Mat31	landmark_

SE3	Tinv_

Mat3	W_

Mat< 3, 9 >	J_

bool	reversedNodeOrder_

Protected Attributes inherited from mrob::Factor
factor_id_t	id_

std::vector< std::shared_ptr< Node > >	neighbourNodes_

uint_t	dim_

uint_t	allNodesDim_

matData_t	chi2_

robustFactorType	robust_type_

matData_t	robust_weight_

Additional Inherited Members
Public Types inherited from mrob::Factor
enum	robustFactorType { QUADRATIC = 0, HUBER, CAUCHY, MCCLURE, RANSAC }

Detailed Description

The factor1Pose1Landmark3d is a vertex representing the distribution between a Rigid Body Transformation encoding a 3D pose and a Landmark, a 3D point

The observation is a 3D point, in the local frame of the current 3D pose. The two Nodes that the factor is connecting, which are provided by their shared_ptr's, are:

1 Pose3d
1 Landmark3d We provide the node's Id to get the correspondent Jacobian

In particular, the relation between the transformation of poses is: z = T^{-1}*l

z is a 3d point with the observations in the local frame T T is the transformation encoded by the 3D pose, the local frame. l is a 3d point encoding the landmark position

and the residual is thus: r = T^{-1}l - z

Constructor functions will be overloaded to include the pointers of the nodes, The convention is 3d pose, we observe node destination, such that: Factor1Pose1Landmark3d(nodePose, nodeLandmark, ...

The observations relate a pair of nodes. The order matters, since this will affect the order on the Jacobian block matrix

Member Function Documentation

◆ evaluate_chi2()

void Factor1Pose1Landmark3d::evaluate_chi2 ( )

overridevirtual

Evaluates chi2 of the current problem, with the given residuals. It may be required to evaluate_residuals() to obtain the new chi2 values This function MOST likely needs to evaluate residuals first, but evaluate_residuals does not necessarily requires to calculate chi2, that is why there are 2 functions.

Implements mrob::Factor.

◆ evaluate_jacobians()

void Factor1Pose1Landmark3d::evaluate_jacobians ( )

overridevirtual

Evaluates residuals and Jacobians

Implements mrob::Factor.

◆ evaluate_residuals()

void Factor1Pose1Landmark3d::evaluate_residuals ( )

overridevirtual

Jacobians are not evaluated, just the residuals

Implements mrob::Factor.

◆ get_jacobian()

MatRefConst mrob::Factor1Pose1Landmark3d::get_jacobian ( [[maybe_unused] ] mrob::factor_id_t id = 0 ) const

inlinevirtual

get_jacobian returns a block matrices stacking all the Jacobians on the factor. The convention is that Jacobians corresponding to.

The input value is in case that Jacobian supports accessing a particular Jacobian of a node. For most factors (include 1-2 nodes) this option is not available Mostly only for EigenFactors whose number of connected nodes is unbounded

Implements mrob::Factor.

◆ get_obs()

MatRefConst mrob::Factor1Pose1Landmark3d::get_obs ( ) const

inlinevirtual

Return a Ref to a dynamic matrix, while the child matrix should declare all these variables as fixed size matrices, and ref takes care of doing the conversion with minimal temporary artifacts Observation can be a 3d point, a 3d pose (transformation 4x4), etc.

Implements mrob::Factor.

◆ get_residual()

VectRefConst mrob::Factor1Pose1Landmark3d::get_residual ( ) const

inlinevirtual

Residual will always be a block vector

Implements mrob::Factor.

◆ print()

void Factor1Pose1Landmark3d::print ( ) const

virtual

The print utility could be re-implemented on child classes if there are special needs

Reimplemented from mrob::Factor.

The documentation for this class was generated from the following files:

src/FGraph/mrob/factors/factor1Pose1Landmark3d.hpp
src/FGraph/factors/factor1Pose1Landmark3d.cpp

Public Member Functions

Protected Attributes

Additional Inherited Members

Detailed Description

Member Function Documentation

◆ evaluate_chi2()

◆ evaluate_jacobians()

◆ evaluate_residuals()

◆ get_jacobian()

◆ get_obs()

◆ get_residual()

◆ print()