Lower Bound Tree Rapidly-exploring Random Trees. More...

#include <ompl/geometric/planners/rrt/LBTRRT.h>

Inheritance diagram for ompl::geometric::LBTRRT:

Classes

struct  IsLessThan
 comparator - metric is the cost to reach state via a specific state More...
 
struct  IsLessThanLB
 comparator - metric is the lower bound cost More...
 
class  Motion
 Representation of a motion. More...
 

Public Member Functions

 LBTRRT (const base::SpaceInformationPtr &si)
 Constructor.
 
void getPlannerData (base::PlannerData &data) const override
 Get information about the current run of the motion planner. Repeated calls to this function will update data (only additions are made). This is useful to see what changed in the exploration datastructure, between calls to solve(), for example (without calling clear() in between).

 
base::PlannerStatus solve (const base::PlannerTerminationCondition &ptc) override
 Function that can solve the motion planning problem. This function can be called multiple times on the same problem, without calling clear() in between. This allows the planner to continue work for more time on an unsolved problem, for example. If this option is used, it is assumed the problem definition is not changed (unpredictable results otherwise). The only change in the problem definition that is accounted for is the addition of starting or goal states (but not changing previously added start/goal states). If clearQuery() is called, the planner may retain prior datastructures generated from a previous query on a new problem definition. The function terminates if the call to ptc returns true.
 
void clear () override
 Clear all internal datastructures. Planner settings are not affected. Subsequent calls to solve() will ignore all previous work.
 
void setGoalBias (double goalBias)
 Set the goal bias. More...
 
double getGoalBias () const
 Get the goal bias the planner is using.
 
void setRange (double distance)
 Set the range the planner is supposed to use. More...
 
double getRange () const
 Get the range the planner is using.
 
template<template< typename T > class NN>
void setNearestNeighbors ()
 Set a different nearest neighbors datastructure.
 
void setup () override
 Perform extra configuration steps, if needed. This call will also issue a call to ompl::base::SpaceInformation::setup() if needed. This must be called before solving.
 
void setApproximationFactor (double epsilon)
 Set the apprimation factor.
 
double getApproximationFactor () const
 Get the apprimation factor.
 
std::string getIterationCount () const
 
std::string getBestCost () const
 
- Public Member Functions inherited from ompl::base::Planner
 Planner (const Planner &)=delete
 
Planneroperator= (const Planner &)=delete
 
 Planner (SpaceInformationPtr si, std::string name)
 Constructor.
 
virtual ~Planner ()=default
 Destructor.
 
template<class T >
T * as ()
 Cast this instance to a desired type. More...
 
template<class T >
const T * as () const
 Cast this instance to a desired type. More...
 
const SpaceInformationPtrgetSpaceInformation () const
 Get the space information this planner is using.
 
const ProblemDefinitionPtrgetProblemDefinition () const
 Get the problem definition the planner is trying to solve.
 
ProblemDefinitionPtrgetProblemDefinition ()
 Get the problem definition the planner is trying to solve.
 
const PlannerInputStatesgetPlannerInputStates () const
 Get the planner input states.
 
virtual void setProblemDefinition (const ProblemDefinitionPtr &pdef)
 Set the problem definition for the planner. The problem needs to be set before calling solve(). Note: If this problem definition replaces a previous one, it may also be necessary to call clear() or clearQuery().
 
PlannerStatus solve (const PlannerTerminationConditionFn &ptc, double checkInterval)
 Same as above except the termination condition is only evaluated at a specified interval.
 
PlannerStatus solve (double solveTime)
 Same as above except the termination condition is solely a time limit: the number of seconds the algorithm is allowed to spend planning.
 
virtual void clearQuery ()
 Clears internal datastructures of any query-specific information from the previous query. Planner settings are not affected. The planner, if able, should retain all datastructures generated from previous queries that can be used to help solve the next query. Note that clear() should also clear all query-specific information along with all other datastructures in the planner. By default clearQuery() calls clear().
 
const std::string & getName () const
 Get the name of the planner.
 
void setName (const std::string &name)
 Set the name of the planner.
 
const PlannerSpecsgetSpecs () const
 Return the specifications (capabilities of this planner)
 
virtual void checkValidity ()
 Check to see if the planner is in a working state (setup has been called, a goal was set, the input states seem to be in order). In case of error, this function throws an exception.
 
bool isSetup () const
 Check if setup() was called for this planner.
 
ParamSetparams ()
 Get the parameters for this planner.
 
const ParamSetparams () const
 Get the parameters for this planner.
 
const PlannerProgressPropertiesgetPlannerProgressProperties () const
 Retrieve a planner's planner progress property map.
 
virtual void printProperties (std::ostream &out) const
 Print properties of the motion planner.
 
virtual void printSettings (std::ostream &out) const
 Print information about the motion planner's settings.
 

Protected Member Functions

void considerEdge (Motion *parent, Motion *child, double c)
 consider an edge for addition to the roadmap
 
double lazilyUpdateApxParent (Motion *child, Motion *parent)
 lazily update the parent in the approximation tree without updating costs to cildren
 
void updateChildCostsApx (Motion *m, double delta)
 update the child cost of the approximation tree
 
void removeFromParentApx (Motion *m)
 remove motion from its parent in the approximation tree
 
void freeMemory ()
 Free the memory allocated by this planner.
 
double distanceFunction (const Motion *a, const Motion *b) const
 Compute distance between motions (actually distance between contained states)
 
bool checkMotion (const Motion *a, const Motion *b)
 local planner
 
bool checkMotion (const base::State *a, const base::State *b)
 local planner
 
MotiongetMotion (std::size_t i)
 get motion from id
 
- Protected Member Functions inherited from ompl::base::Planner
template<typename T , typename PlannerType , typename SetterType , typename GetterType >
void declareParam (const std::string &name, const PlannerType &planner, const SetterType &setter, const GetterType &getter, const std::string &rangeSuggestion="")
 This function declares a parameter for this planner instance, and specifies the setter and getter functions.
 
template<typename T , typename PlannerType , typename SetterType >
void declareParam (const std::string &name, const PlannerType &planner, const SetterType &setter, const std::string &rangeSuggestion="")
 This function declares a parameter for this planner instance, and specifies the setter function.
 
void addPlannerProgressProperty (const std::string &progressPropertyName, const PlannerProgressProperty &prop)
 Add a planner progress property called progressPropertyName with a property querying function prop to this planner's progress property map.
 

Protected Attributes

base::StateSamplerPtr sampler_
 State sampler.
 
std::shared_ptr< NearestNeighbors< Motion * > > nn_
 A nearest-neighbors datastructure containing the tree of motions.
 
DynamicSSSP lowerBoundGraph_
 A graph of motions Glb.
 
std::vector< Motion * > idToMotionMap_
 mapping between a motion id and the motion
 
double goalBias_ {.05}
 The fraction of time the goal is picked as the state to expand towards (if such a state is available)
 
double maxDistance_ {0.}
 The maximum length of a motion to be added to a tree.
 
double epsilon_ {.4}
 approximation factor
 
RNG rng_
 The random number generator.
 
MotionlastGoalMotion_ {nullptr}
 The most recent goal motion. Used for PlannerData computation.
 
unsigned int iterations_ {0u}
 Number of iterations the algorithm performed.
 
double bestCost_
 Best cost found so far by algorithm.
 
- Protected Attributes inherited from ompl::base::Planner
SpaceInformationPtr si_
 The space information for which planning is done.
 
ProblemDefinitionPtr pdef_
 The user set problem definition.
 
PlannerInputStates pis_
 Utility class to extract valid input states

 
std::string name_
 The name of this planner.
 
PlannerSpecs specs_
 The specifications of the planner (its capabilities)
 
ParamSet params_
 A map from parameter names to parameter instances for this planner. This field is populated by the declareParam() function.
 
PlannerProgressProperties plannerProgressProperties_
 A mapping between this planner's progress property names and the functions used for querying those progress properties.
 
bool setup_
 Flag indicating whether setup() has been called.
 

Additional Inherited Members

- Public Types inherited from ompl::base::Planner
using PlannerProgressProperty = std::function< std::string()>
 Definition of a function which returns a property about the planner's progress that can be queried by a benchmarking routine.
 
using PlannerProgressProperties = std::map< std::string, PlannerProgressProperty >
 A dictionary which maps the name of a progress property to the function to be used for querying that property.
 

Detailed Description

Lower Bound Tree Rapidly-exploring Random Trees.

Short description
LBTRRT (Lower Bound Tree RRT) is a near asymptotically-optimal incremental sampling-based motion planning algorithm. LBTRRT algorithm is guaranteed to converge to a solution that is within a constant factor of the optimal solution. The notion of optimality is with respect to the distance function defined on the state space we are operating on.
External documentation
O. Salzman and D. Halperin, Sampling-based Asymptotically near-optimal RRT for fast, high-quality, motion planning, 2013. [PDF]

Definition at line 132 of file LBTRRT.h.

Member Function Documentation

◆ setGoalBias()

void ompl::geometric::LBTRRT::setGoalBias ( double  goalBias)
inline

Set the goal bias.

In the process of randomly selecting states in the state space to attempt to go towards, the algorithm may in fact choose the actual goal state, if it knows it, with some probability. This probability is a real number between 0.0 and 1.0; its value should usually be around 0.05 and should not be too large. It is probably a good idea to use the default value.

Definition at line 187 of file LBTRRT.h.

◆ setRange()

void ompl::geometric::LBTRRT::setRange ( double  distance)
inline

Set the range the planner is supposed to use.

This parameter greatly influences the runtime of the algorithm. It represents the maximum length of a motion to be added in the tree of motions.

Definition at line 203 of file LBTRRT.h.


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