drake::multibody Namespace Reference

Namespaces
	benchmarks
	collision
	constraint
	examples
	hydroelastics
	internal
	joints
	math
	multibody_plant
	parsers
	test
	test_utilities

Classes
struct	AddMultibodyPlantSceneGraphResult
	Temporary result from AddMultibodyPlantSceneGraph. More...
class	AngleBetweenVectorsConstraint
	Constrains that the angle between a vector a and another vector b is between [θ_lower, θ_upper]. More...
class	ArticulatedBodyInertia
	Articulated Body Inertia is the inertia that a body appears to have when it is the base (or root) of a rigid-body system, also referred to as Articulated Body in the context of articulated body algorithms. More...
class	Body
	Body provides the general abstraction of a body with an API that makes no assumption about whether a body is rigid or deformable and neither does it make any assumptions about the underlying physical model or approximation. More...
class	BodyFrame
	A BodyFrame is a material Frame that serves as the unique reference frame for a Body. More...
class	BoxSphereTest
class	ContactResults
	A container class storing the contact results information for each contact pair for a given state of the simulation. More...
class	ContactResultsToLcmSystem
	A System that encodes ContactResults into a lcmt_contact_results_for_viz message. More...
struct	ContactWrench
	Stores the contact wrench (spatial force) from Body A to Body B applied at point Cb. More...
class	ContactWrenchEvaluator
class	ContactWrenchFromForceInWorldFrameEvaluator
	The contact wrench is τ_AB_W = 0, f_AB_W = λ Namely we assume that λ is the contact force from A to B, applied directly at B's witness point. More...
class	CoulombFriction
	Parameters for Coulomb's Law of Friction, namely: More...
class	DistanceConstraint
	Constrains the distance between a pair of geometries to be within a range [distance_lower, distance_upper]. More...
struct	ExternallyAppliedSpatialForce
class	FixedOffsetFrame
	FixedOffsetFrame represents a material frame F whose pose is fixed with respect to a parent material frame P. More...
class	ForceElement
	A ForceElement allows modeling state and time dependent forces in a MultibodyTree model. More...
class	Frame
	Frame is an abstract class representing a material frame (also called a physical frame), meaning that it is associated with a material point of a Body. More...
class	FrameBase
	FrameBase is an abstract representation of the concept of a frame in multibody dynamics. More...
class	GaussianTriangleQuadratureRule
class	GazeTargetConstraint
	Constrains a target point T to be within a cone K. More...
class	GlobalInverseKinematics
	Solves the inverse kinematics problem as a mixed integer convex optimization problem. More...
class	HydroelasticContactInfo
	A class containing information regarding contact and contact response between two geometries attached to a pair of bodies. More...
class	IiwaKinematicConstraintTest
class	ImplicitStribeckSolver
struct	ImplicitStribeckSolverIterationStats
	Struct used to store information about the iteration process performed by ImplicitStribeckSolver. More...
struct	ImplicitStribeckSolverParameters
	These are the parameters controlling the iteration process of the ImplicitStribeckSolver solver. More...
class	InverseKinematics
	Solves an inverse kinematics (IK) problem on a MultibodyPlant, to find the postures of the robot satisfying certain constraints. More...
class	Joint
	A Joint models the kinematical relationship which characterizes the possible relative motion between two bodies. More...
class	JointActuator
	The JointActuator class is mostly a simple bookkeeping structure to represent an actuator acting on a given Joint. More...
class	LinearSpringDamper
	This ForceElement models a spring-damper attached between two points on two different bodies. More...
class	ManipulatorEquationConstraint
	A Constraint to impose the manipulator equation: 0 = (Buₙ₊₁ + ∑ᵢ (Jᵢ_WBᵀ(qₙ₊₁)ᵀ * Fᵢ_AB_W(λᵢ,ₙ₊₁)) More...
class	MinimumDistanceConstraint
	Constrain the signed distance between all candidate pairs of geometries (according to the logic of SceneGraphInspector::GetCollisionCandidates()) to be no smaller than a specified minimum distance. More...
class	MultibodyForces
	A class to hold a set of forces applied to a MultibodyTree system. More...
class	MultibodyPlant
	MultibodyPlant is a Drake system framework representation (see systems::System) for the model of a physical system consisting of a collection of interconnected bodies. More...
class	MultibodyPlantTester
class	MultibodyTreeElement< ElementType< T >, ElementIndexType >
	A class representing an element or component of a MultibodyTree. More...
class	OrientationConstraint
	Constrains that the angle difference θ between the orientation of frame A and the orientation of frame B to satisfy θ ≤ θ_bound. More...
class	PackageMap
	Maps ROS package names to their full path on the local file system. More...
class	Parser
	Parses SDF and URDF input files into a MultibodyPlant and (optionally) a SceneGraph. More...
class	PointPairContactInfo
	A class containing information regarding contact response between two bodies including: More...
class	PositionConstraint
	Constrains the position of a point Q, rigidly attached to a frame B, to be within a bounding box measured and expressed in frame A. More...
class	PrismaticJoint
	This Joint allows two bodies to translate relative to one another along a common axis. More...
class	RevoluteJoint
	This Joint allows two bodies to rotate relatively to one another around a common axis. More...
class	RevoluteSpring
	This ForceElement models a torsional spring attached to a RevoluteJoint and applies a torque to that joint. More...
class	RigidBody
	The term rigid body implies that the deformations of the body under consideration are so small that they have no significant effect on the overall motions of the body and therefore deformations can be neglected. More...
class	RotationalInertia
	This class describes the mass distribution (inertia properties) of a body or composite body about a particular point. More...
class	SpatialAcceleration
	This class is used to represent a spatial acceleration that combines rotational (angular acceleration) and translational (linear acceleration) components. More...
class	SpatialForce
	This class is used to represent a spatial force (also called a wrench) that combines both rotational (torque) and translational force components. More...
class	SpatialInertia
	This class represents the physical concept of a Spatial Inertia. More...
class	SpatialMomentum
	This class is used to represent the spatial momentum of a particle, system of particles or body (whether rigid or soft.) The linear momentum l_NS of a system of particles S in a reference frame N is defined by: More...
class	SpatialVector
	This class is used to represent physical quantities that correspond to spatial vectors such as spatial velocities, spatial accelerations and spatial forces. More...
class	SpatialVelocity
	This class is used to represent a spatial velocity (also called a twist) that combines rotational (angular) and translational (linear) velocity components. More...
class	StaticEquilibriumConstraint
	Impose the static equilibrium constraint 0 = τ_g + Bu + ∑J_WBᵀ(q) * Fapp_B_W. More...
class	StaticEquilibriumProblem
	Finds the static equilibrium pose of a multibody system through optimization. More...
class	StaticFrictionConeConstraint
	Formulates the nonlinear friction cone constraint |fₜ| ≤ μ*fₙ, where fₜ is the tangential contact force, fₙ is the normal contact force, and μ is the friction coefficient. More...
class	TriangleQuadrature
	A class for integrating a function using numerical quadrature over triangular domains. More...
class	TriangleQuadratureRule
	A "rule" (weights and quadrature points) for computing quadrature over triangular domains. More...
class	TwoFreeBodiesConstraintTest
class	TwoFreeSpheresTest
class	UniformGravityFieldElement
	This ForceElement allows modeling the effect of a uniform gravity field as felt by bodies on the surface of the Earth. More...
class	UnitInertia
	This class is used to represent rotational inertias for unit mass bodies. More...
class	WeldJoint
	This Joint fixes the relative pose between two frames as if "welding" them together. More...

Typedefs
using	MinimumDistancePenaltyFunction = solvers::MinimumValuePenaltyFunction
	Computes the penalty function φ(x) and its derivatives dφ(x)/dx. More...
using	FrameIndex = TypeSafeIndex< class FrameTag >
	Type used to identify frames by index in a multibody tree system. More...
using	BodyIndex = TypeSafeIndex< class BodyTag >
	Type used to identify bodies by index in a multibody tree system. More...
using	ForceElementIndex = TypeSafeIndex< class ForceElementTag >
	Type used to identify force elements by index within a multibody tree system. More...
using	JointIndex = TypeSafeIndex< class JointElementTag >
	Type used to identify joints by index within a multibody tree system. More...
using	JointActuatorIndex = TypeSafeIndex< class JointActuatorElementTag >
	Type used to identify actuators by index within a multibody tree system. More...
using	ModelInstanceIndex = TypeSafeIndex< class ModelInstanceTag >
	Type used to identify model instances by index within a multibody tree system. More...

Enumerations
enum	ImplicitStribeckSolverResult { kSuccess = 0, kMaxIterationsReached = 1, kLinearSolverFailed = 2 }
	The result from ImplicitStribeckSolver::SolveWithGuess() used to report the success or failure of the solver. More...
enum	JacobianWrtVariable { kQDot, kV }
	Enumeration that indicates whether the Jacobian is partial differentiation with respect to q̇ (time-derivatives of generalized positions) or with respect to v (generalized velocities). More...

Functions
void	ApproximateBoundedNormByLinearConstraints (const Eigen::Ref< const Vector3< symbolic::Expression >> &x, double c, solvers::MathematicalProgram *prog)
template<typename T >
lcmt_viewer_load_robot	CreateLoadRobotMessage (const RigidBodyTree< double > &tree)
	Creates and returns an lcmt_viewer_load_robot message containing the visual geometries from the provided RigidBodyTree. More...
template lcmt_viewer_load_robot	CreateLoadRobotMessage< double > (const RigidBodyTree< double > &tree)
void	AddFlatTerrainToWorld (RigidBodyTreed *tree, double box_size=1000, double box_depth=10)
	Adds a box-shaped terrain to tree. More...
	TEST_F (RigidBodyTreeKinematicsTests, TestDoKinematicWithValidCache)
	TEST_F (RigidBodyTreeKinematicsTests, TestDoKinematicWithBadCache1)
	TEST_F (RigidBodyTreeKinematicsTests, TestDoKinematicWithBadCache2)
	TEST_F (AcrobotTests, PoseTests)
	TEST_F (AcrobotTests, SpatialVelocityTests)
	TEST_F (RBTDifferentialKinematicsHelperTest, RPYPoseTest)
	TEST_F (RBTDifferentialKinematicsHelperTest, RPYTwistInWorldAlignedBodyTest)
	TEST_F (RBTDifferentialKinematicsHelperTest, RPYJacobianTest)
	TEST_F (RBTDifferentialKinematicsHelperTest, RPYJacobianDotTimeVTest)
	TEST_F (RBTDifferentialKinematicsHelperTest, QuatPoseTest)
	TEST_F (RBTDifferentialKinematicsHelperTest, QuatTwistInWorldAlignedBodyTest)
	TEST_F (RBTDifferentialKinematicsHelperTest, QuatJacobianTest)
	TEST_F (RBTDifferentialKinematicsHelperTest, QuatJacobianDotTimeVTest)
template<typename T >
void	EvalConstraintGradient (const systems::Context< T > &, const MultibodyPlant< T > &, const Frame< T > &, const Frame< T > &, const Eigen::Vector3d &, const Eigen::Vector3d &, const math::RotationMatrix< T > &, const Eigen::Ref< const VectorX< T >> &, VectorX< T > *)
void	EvalConstraintGradient (const systems::Context< double > &context, const MultibodyPlant< double > &plant, const Frame< double > &frameA, const Frame< double > &frameB, const Eigen::Vector3d &a_unit_A, const Eigen::Vector3d &b_unit_B, const math::RotationMatrix< double > &R_AB, const Eigen::Ref< const AutoDiffVecXd > &x, AutoDiffVecXd *y)
template<typename T , typename S >
void	DoEvalGeneric (const MultibodyPlant< T > &plant, systems::Context< T > *context, const FrameIndex frameA_index, const FrameIndex frameB_index, const Eigen::Vector3d &a_unit_A, const Eigen::Vector3d &b_unit_B, const Eigen::Ref< const VectorX< S >> &x, VectorX< S > *y)
template<typename T , typename S >
void	EvalDistance (const MultibodyPlant< T > &plant, const SortedPair< geometry::GeometryId > &geometry_pair, systems::Context< T > *context, const Eigen::Ref< const VectorX< S >> &x, VectorX< S > *y)
template<typename T >
void	EvalConstraintGradient (const systems::Context< T > &, const MultibodyPlant< T > &, const Frame< T > &, const Frame< T > &, const Eigen::Vector3d &, const Eigen::Vector3d &, const Vector3< T > &, const T &, const Vector2< T > &g, const Eigen::Ref< const VectorX< T >> &, VectorX< T > *y)
void	EvalConstraintGradient (const systems::Context< double > &context, const MultibodyPlant< double > &plant, const Frame< double > &frameA, const Frame< double > &frameB, const Eigen::Vector3d &p_BT, const Eigen::Vector3d &n_A, const Eigen::Vector3d &cos_cone_half_angle_squared_times_p, const double &p_dot_n, const Eigen::Vector2d &g, const Eigen::Ref< const AutoDiffVecXd > &x, AutoDiffVecXd *y)
template<typename T , typename S >
void	DoEvalGeneric (const MultibodyPlant< T > &plant, systems::Context< T > *context, const FrameIndex frameA_index, const FrameIndex frameB_index, const Eigen::Vector3d &p_AS, const Eigen::Vector3d &n_A, const Eigen::Vector3d p_BT, double cos_cone_half_angle, const Eigen::Ref< const VectorX< S >> &x, VectorX< S > *y)
template<typename T , typename S >
VectorX< S >	Distances (const MultibodyPlant< T > &plant, systems::Context< T > *context, const Eigen::Ref< const VectorX< S >> &q, double influence_distance)
template<typename T >
void	EvalConstraintGradient (const systems::Context< T > &, const MultibodyPlant< T > &, const Frame< T > &, const Frame< T > &, const math::RotationMatrix< double > &, const math::RotationMatrix< T > &R_AB, const Vector3< T > &, const Eigen::Ref< const VectorX< T >> &, VectorX< T > *y)
void	EvalConstraintGradient (const systems::Context< double > &context, const MultibodyPlant< double > &plant, const Frame< double > &frameAbar, const Frame< double > &frameBbar, const math::RotationMatrix< double > &R_AbarA, const math::RotationMatrix< double > &R_AB, const Vector3< double > &r_AB, const Eigen::Ref< const AutoDiffVecXd > &x, AutoDiffVecXd *y)
template<typename T , typename S >
void	DoEvalGeneric (const MultibodyPlant< T > &plant, systems::Context< T > *context, FrameIndex frameAbar_index, FrameIndex frameBbar_index, const math::RotationMatrix< double > &R_AbarA, const math::RotationMatrix< double > &R_BbarB, const Eigen::Ref< const VectorX< S >> &x, VectorX< S > *y)
template<typename T >
void	EvalConstraintGradient (const systems::Context< T > &, const MultibodyPlant< T > &, const Frame< T > &, const Frame< T > &, const Vector3< T > &p_AQ, const Eigen::Vector3d &, const Eigen::Ref< const VectorX< T >> &, VectorX< T > *y)
void	EvalConstraintGradient (const systems::Context< double > &context, const MultibodyPlant< double > &plant, const Frame< double > &frameA, const Frame< double > &frameB, const Eigen::Vector3d &p_AQ, const Eigen::Vector3d &p_BQ, const Eigen::Ref< const AutoDiffVecXd > &x, AutoDiffVecXd *y)
template<typename T , typename S >
void	DoEvalGeneric (const MultibodyPlant< T > &plant, systems::Context< T > *context, const FrameIndex frameA_index, const FrameIndex frameB_index, const Eigen::Vector3d &p_BQ, const Eigen::Ref< const VectorX< S >> &x, VectorX< S > *y)
	TEST_F (TwoFreeSpheresTest, Constructor)
	TEST_F (TwoFreeSpheresTest, TestEval)
Eigen::Quaterniond	Vector4ToQuaternion (const Eigen::Ref< const Eigen::Vector4d > &q)
	GTEST_TEST (InverseKinematicsTest, ConstructorWithJointLimits)
	TEST_F (TwoFreeBodiesTest, PositionConstraint)
	TEST_F (TwoFreeBodiesTest, OrientationConstraint)
	TEST_F (TwoFreeBodiesTest, GazeTargetConstraint)
	TEST_F (TwoFreeBodiesTest, AngleBetweenVectorsConstraint)
	TEST_F (TwoFreeSpheresTest, MinimumDistanceConstraintTest)
template<typename T >
void	AddTwoFreeBodiesToPlant (MultibodyPlant< T > *model)
	Adds two free bodies to a MultibodyPlant. More...
template<typename T >
std::unique_ptr< MultibodyPlant< T > >	ConstructTwoFreeBodiesPlant ()
	Constructs a MultibodyPlant consisting of two free bodies. More...
std::unique_ptr< MultibodyPlant< double > >	ConstructIiwaPlant (const std::string &file_path, double time_step)
	Constructs a MultibodyPlant consisting of an Iiwa robot. More...
Eigen::Vector4d	QuaternionToVectorWxyz (const Eigen::Quaterniond &q)
	Convert an Eigen::Quaternion to a vector 4d in the order (w, x, y, z). More...
template<typename T >
std::unique_ptr< systems::Diagram< T > >	ConstructBoxSphereDiagram (const Eigen::Vector3d &box_size, double radius, MultibodyPlant< T > **plant, geometry::SceneGraph< T > **scene_graph)
template<typename T >
T	BoxSphereSignedDistance (const Eigen::Ref< const Eigen::Vector3d > &box_size, double radius, const math::RigidTransform< T > &X_WB, const math::RigidTransform< T > &X_WS)
	Compute the signed distance between a box and a sphere. More...
template std::unique_ptr< MultibodyPlant< double > >	ConstructTwoFreeBodiesPlant< double > ()
template std::unique_ptr< MultibodyPlant< AutoDiffXd > >	ConstructTwoFreeBodiesPlant< AutoDiffXd > ()
template double	BoxSphereSignedDistance< double > (const Eigen::Ref< const Eigen::Vector3d > &box_size, double radius, const math::RigidTransform< double > &X_WB, const math::RigidTransform< double > &X_WS)
template AutoDiffXd	BoxSphereSignedDistance< AutoDiffXd > (const Eigen::Ref< const Eigen::Vector3d > &box_size, double radius, const math::RigidTransform< AutoDiffXd > &X_WB, const math::RigidTransform< AutoDiffXd > &X_WS)
template<typename DerivedA , typename DerivedB >
std::enable_if< std::is_same< typename DerivedA::Scalar, typename DerivedB::Scalar >::value &&std::is_same< typename DerivedA::Scalar, AutoDiffXd >::value >::type	CompareAutoDiffVectors (const Eigen::MatrixBase< DerivedA > &a, const Eigen::MatrixBase< DerivedB > &b, double tol)
	Compares if two eigen matrices of AutoDiff have the same values and gradients. More...
template<typename ConstraintType >
void	TestKinematicConstraintEval (const ConstraintType &constraint_from_double, const ConstraintType &constraint_from_autodiff, const Eigen::Ref< const Eigen::VectorXd > &x_double, const Eigen::Ref< const Eigen::MatrixXd > &dx, double gradient_tol)
	Since we can construct the kinematic constraint using both MultibodyPlant<double> (as constraint_from_double) and MultibodyPlant<AutoDiffXd> (as constraint_from_autodiff), and evaluate the constraint with both VectorX<double> and VectorX<AutoDiffXd>, we check if the following evaluation results match: More...
template<typename T >
Vector3< T >	ComputeCollisionSphereCenterPosition (const Vector3< T > &p_WB, const Quaternion< T > &quat_WB, const math::RigidTransformd &X_BS)
	TEST_F (TwoFreeSpheresMinimumDistanceTest, ExponentialPenalty)
	TEST_F (TwoFreeSpheresMinimumDistanceTest, QuadraticallySmoothedHingePenalty)
	GTEST_TEST (MinimumDistanceConstraintTest, MultibodyPlantWithouthGeometrySource)
	GTEST_TEST (MinimumDistanceConstraintTest, MultibodyPlantWithoutCollisionPairs)
	TEST_F (TwoFreeSpheresTest, NonpositiveInfluenceDistanceOffset)
	TEST_F (TwoFreeSpheresTest, NonfiniteInfluenceDistanceOffset)
template<typename T >
T	BoxSphereSignedDistance (const Eigen::Vector3d &box_size, double radius, const VectorX< T > &x)
	TEST_F (BoxSphereTest, Test)
template<typename T >
SpatialForce< T >	operator+ (const SpatialForce< T > &F1_Sp_E, const SpatialForce< T > &F2_Sp_E)
	Computes the resultant spatial force as the addition of two spatial forces F1_Sp_E and F2_Sp_E on a same system or body S, at the same point P and expressed in the same frame E. More...
template<typename T >
SpatialMomentum< T >	operator+ (const SpatialMomentum< T > &L1_NSp_E, const SpatialMomentum< T > &L2_NSp_E)
	Computes the resultant spatial momentum as the addition of two spatial momenta L1_NSp_E and L2_NSp_E on a same system S, about the same point P and expressed in the same frame E. More...
template<typename T >
SpatialVelocity< T >	operator+ (const SpatialVelocity< T > &V_MAb_E, const SpatialVelocity< T > &V_AB_E)
	Performs the addition of two spatial velocities. More...
template<typename T >
SpatialVelocity< T >	operator- (const SpatialVelocity< T > &V_MB_E, const SpatialVelocity< T > &V_MAb_E)
	The addition of two spatial velocities relates to the composition of the spatial velocities for two frames given we know the relative spatial velocity between them, see operator+(const SpatialVelocity<T>&, const SpatialVelocity<T>&) for further details. More...
std::pair< solvers::Binding< internal::SlidingFrictionComplementarityNonlinearConstraint >, solvers::Binding< StaticFrictionConeConstraint > >	AddSlidingFrictionComplementarityExplicitContactConstraint (const ContactWrenchEvaluator *contact_wrench_evaluator, double complementarity_tolerance, const Eigen::Ref< const VectorX< symbolic::Variable >> &q_vars, const Eigen::Ref< const VectorX< symbolic::Variable >> &v_vars, const Eigen::Ref< const VectorX< symbolic::Variable >> &lambda_vars, solvers::MathematicalProgram *prog)
	For a pair of geometries in explicit contact, adds the sliding friction complementarity constraint explained in sliding_friction_complementarity_constraint to an optimization program. More...
std::pair< solvers::Binding< internal::SlidingFrictionComplementarityNonlinearConstraint >, solvers::Binding< internal::StaticFrictionConeComplementarityNonlinearConstraint > >	AddSlidingFrictionComplementarityImplicitContactConstraint (const ContactWrenchEvaluator *contact_wrench_evaluator, double complementarity_tolerance, const Eigen::Ref< const VectorX< symbolic::Variable >> &q_vars, const Eigen::Ref< const VectorX< symbolic::Variable >> &v_vars, const Eigen::Ref< const VectorX< symbolic::Variable >> &lambda_vars, solvers::MathematicalProgram *prog)
	For a pair of geometries in implicit contact (they may or may not be in contact, adds the sliding friction complementarity constraint explained in sliding_friction_complementarity_constraint. More...
solvers::Binding< internal::StaticFrictionConeComplementarityNonlinearConstraint >	AddStaticFrictionConeComplementarityConstraint (const ContactWrenchEvaluator *contact_wrench_evaluator, double complementarity_tolerance, const Eigen::Ref< const VectorX< symbolic::Variable >> &q_vars, const Eigen::Ref< const VectorX< symbolic::Variable >> &lambda_vars, solvers::MathematicalProgram *prog)
	Adds the complementarity constraint on the static friction force between a pair of contacts |ft_W| <= μ * n_Wᵀ * f_W (static friction force in the friction cone). More...
	GTEST_TEST (StaticEquilibriumProblemTest, SphereOnGroundTest)
	GTEST_TEST (TestStaticEquilibriumProblem, TwoSpheresWithinBin)
	GTEST_TEST (StaticFrictionConeComplementarityNonlinearConstraint, TestEval)
	GTEST_TEST (StaticFrictionConeConstraint, TestEval)
std::ostream &	operator<< (std::ostream &out, const PackageMap &package_map)
systems::lcm::LcmPublisherSystem *	ConnectContactResultsToDrakeVisualizer (systems::DiagramBuilder< double > *builder, const MultibodyPlant< double > &multibody_plant, lcm::DrakeLcmInterface *lcm=nullptr)
	Extends a Diagram with the required components to publish contact results to drake_visualizer. More...
systems::lcm::LcmPublisherSystem *	ConnectContactResultsToDrakeVisualizer (systems::DiagramBuilder< double > *builder, const MultibodyPlant< double > &multibody_plant, const systems::OutputPort< double > &contact_results_port, lcm::DrakeLcmInterface *lcm=nullptr)
	Implements ConnectContactResultsToDrakeVisualizer, but using contact_results_port to explicitly specify the output port used to get contact results for multibody_plant. More...
template<typename T >
CoulombFriction< T >	CalcContactFrictionFromSurfaceProperties (const CoulombFriction< T > &surface_properties1, const CoulombFriction< T > &surface_properties2)
	Given the surface properties of two different surfaces, this method computes the Coulomb's law coefficients of friction characterizing the interaction by friction of the given surface pair. More...
template<typename T >
AddMultibodyPlantSceneGraphResult< T >	AddMultibodyPlantSceneGraph (systems::DiagramBuilder< T > *builder, std::unique_ptr< MultibodyPlant< T >> plant=nullptr, std::unique_ptr< geometry::SceneGraph< T >> scene_graph=nullptr)
	Adds a MultibodyPlant and a SceneGraph instance to a diagram builder, connecting the geometry ports. More...
template AddMultibodyPlantSceneGraphResult< double >	AddMultibodyPlantSceneGraph (systems::DiagramBuilder< double > *builder, std::unique_ptr< MultibodyPlant< double >> plant, std::unique_ptr< geometry::SceneGraph< double >> scene_graph)
template AddMultibodyPlantSceneGraphResult< AutoDiffXd >	AddMultibodyPlantSceneGraph (systems::DiagramBuilder< AutoDiffXd > *builder, std::unique_ptr< MultibodyPlant< AutoDiffXd >> plant, std::unique_ptr< geometry::SceneGraph< AutoDiffXd >> scene_graph)
BodyIndex	world_index ()
	For every MultibodyTree the world body always has this unique index and it is always zero. More...
ModelInstanceIndex	world_model_instance ()
	Returns the model instance containing the world body. More...
ModelInstanceIndex	default_model_instance ()
	Returns the model instance which contains all tree elements with no explicit model instance specified. More...
Drake joint comparison methods.
These methods compare joint original with joint clone. Since these methods are intended to compare a clone, an exact match is performed. This method will only return true if the provided clone joint is exactly the same as the provided original joint.
bool	CompareDrakeJointToClone (const DrakeJoint &original, const DrakeJoint &clone)
bool	CompareFixedJointToClone (const FixedJoint &original, const FixedJoint &other)
bool	CompareHelicalJointToClone (const HelicalJoint &original, const HelicalJoint &clone)
bool	ComparePrismaticJointToClone (const PrismaticJoint &original, const PrismaticJoint &clone)
bool	CompareQuaternionBallJointToClone (const QuaternionBallJoint &original, const QuaternionBallJoint &clone)
bool	CompareQuaternionFloatingJointToClone (const QuaternionFloatingJoint &original, const QuaternionFloatingJoint &clone)
bool	CompareRevoluteJointToClone (const RevoluteJoint &original, const RevoluteJoint &clone)
bool	CompareRollPitchYawFloatingJointToClone (const RollPitchYawFloatingJoint &original, const RollPitchYawFloatingJoint &clone)
template<typename Derived >
bool	CompareFixedAxisOneDofJointToClone (const FixedAxisOneDoFJoint< Derived > &original, const FixedAxisOneDoFJoint< Derived > &clone)

Variables
constexpr int	kNumPositionsForTwoFreeBodies {14}
const double	kInf = std::numeric_limits<double>::infinity()

Typedef Documentation

BodyIndex

using BodyIndex = TypeSafeIndex<class BodyTag>

Type used to identify bodies by index in a multibody tree system.

ForceElementIndex

using ForceElementIndex = TypeSafeIndex<class ForceElementTag>

Type used to identify force elements by index within a multibody tree system.

FrameIndex

using FrameIndex = TypeSafeIndex<class FrameTag>

Type used to identify frames by index in a multibody tree system.

JointActuatorIndex

using JointActuatorIndex = TypeSafeIndex<class JointActuatorElementTag>

Type used to identify actuators by index within a multibody tree system.

JointIndex

using JointIndex = TypeSafeIndex<class JointElementTag>

Type used to identify joints by index within a multibody tree system.

MinimumDistancePenaltyFunction

using MinimumDistancePenaltyFunction = solvers::MinimumValuePenaltyFunction

Computes the penalty function φ(x) and its derivatives dφ(x)/dx.

Valid penalty functions must meet the following criteria:

1. φ(x) ≥ 0 ∀ x ∈ ℝ.
2. dφ(x)/dx ≤ 0 ∀ x ∈ ℝ.
3. φ(x) = 0 ∀ x ≥ 0.
4. dφ(x)/dx < 0 ∀ x < 0.

ModelInstanceIndex

using ModelInstanceIndex = TypeSafeIndex<class ModelInstanceTag>

Type used to identify model instances by index within a multibody tree system.

Enumeration Type Documentation

ImplicitStribeckSolverResult

enum ImplicitStribeckSolverResult

strong

The result from ImplicitStribeckSolver::SolveWithGuess() used to report the success or failure of the solver.

Enumerator
kSuccess	Successful computation.
kMaxIterationsReached	The maximum number of iterations was reached.
kLinearSolverFailed	The linear solver used within the Newton-Raphson loop failed. This might be caused by a divergent iteration that led to an invalid Jacobian matrix.

JacobianWrtVariable

enum JacobianWrtVariable

strong

Enumeration that indicates whether the Jacobian is partial differentiation with respect to q̇ (time-derivatives of generalized positions) or with respect to v (generalized velocities).

Enumerator
kQDot	J = ∂V/∂q̇
kV	J = ∂V/∂v.

Function Documentation

AddFlatTerrainToWorld()

void AddFlatTerrainToWorld	(	RigidBodyTreed *	tree,
		double	box_size = 1000,
		double	box_depth = 10
	)

Adds a box-shaped terrain to tree.

This directly modifies the existing world rigid body within tree and thus does not need to return a model_instance_id value.

Two opposite corners of the resulting axis-aligned box are: (box_size / 2, box_size / 2, 0) and (-box_size / 2, -box_size / 2, -box_depth).

Parameters

[in]	tree	The RigidBodyTreed to which to add the terrain.
[in]	box_size	The length and width of the terrain aligned with the world's X and Y axes.
[in]	box_depth	The depth of the terrain aligned with the world's Z axis. Note that regardless of how deep the terrain is, the top surface of the terrain will be at Z = 0.

AddMultibodyPlantSceneGraph() [1/3]

AddMultibodyPlantSceneGraphResult< T > AddMultibodyPlantSceneGraph	(	systems::DiagramBuilder< T > *	builder,
		std::unique_ptr< MultibodyPlant< T >>	plant = nullptr,
		std::unique_ptr< geometry::SceneGraph< T >>	scene_graph = nullptr
	)

Adds a MultibodyPlant and a SceneGraph instance to a diagram builder, connecting the geometry ports.

Parameters

[in,out]	builder	Builder to add to.
[in]	plant	(optional) Constructed plant (e.g. for using a discrete plant). By default, a continuous plant is used.
[in]	scene_graph	(optional) Constructed scene graph. If none is provided, one will be created and used.

Returns

Pair of the registered plant and scene graph.

Precondition

builder must be non-null.

Recommended usages:

Assign to a MultibodyPlant reference (ignoring the SceneGraph):

MultibodyPlant<double>& plant = AddMultibodyPlantSceneGraph(&builder);
plant.DoFoo(...);

This flavor is the simplest, when the SceneGraph is not explicitly needed. (It can always be retrieved later via GetSubsystemByName("scene_graph").)

Assign to auto, and use the named public fields:

auto items = AddMultibodyPlantSceneGraph(&builder);
items.plant.DoFoo(...);
items.scene_graph.DoBar(...);

or

auto items = AddMultibodyPlantSceneGraph(&builder);
MultibodyPlant<double>& plant = items.plant;
SceneGraph<double>& scene_graph = items.scene_graph;
...
plant.DoFoo(...);
scene_graph.DoBar(...);

This is the easiest way to use both the plant and scene_graph.

Assign to already-declared pointer variables:

MultibodyPlant<double>* plant{};
SceneGraph<double>* scene_graph{};
std::tie(plant, scene_graph) = AddMultibodyPlantSceneGraph(&builder);
plant->DoFoo(...);
scene_graph->DoBar(...);

This flavor is most useful when the pointers are class member fields (and so perhaps cannot be references).

AddMultibodyPlantSceneGraph() [2/3]

template AddMultibodyPlantSceneGraphResult<double> drake::multibody::AddMultibodyPlantSceneGraph	(	systems::DiagramBuilder< double > *	builder,
		std::unique_ptr< MultibodyPlant< double >>	plant,
		std::unique_ptr< geometry::SceneGraph< double >>	scene_graph
	)

AddMultibodyPlantSceneGraph() [3/3]

template AddMultibodyPlantSceneGraphResult<AutoDiffXd> drake::multibody::AddMultibodyPlantSceneGraph	(	systems::DiagramBuilder< AutoDiffXd > *	builder,
		std::unique_ptr< MultibodyPlant< AutoDiffXd >>	plant,
		std::unique_ptr< geometry::SceneGraph< AutoDiffXd >>	scene_graph
	)

AddSlidingFrictionComplementarityExplicitContactConstraint()

std::pair< solvers::Binding< internal::SlidingFrictionComplementarityNonlinearConstraint >, solvers::Binding< StaticFrictionConeConstraint > > AddSlidingFrictionComplementarityExplicitContactConstraint	(	const ContactWrenchEvaluator *	contact_wrench_evaluator,
		double	complementarity_tolerance,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	q_vars,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	v_vars,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	lambda_vars,
		solvers::MathematicalProgram *	prog
	)

For a pair of geometries in explicit contact, adds the sliding friction complementarity constraint explained in sliding_friction_complementarity_constraint to an optimization program.

This function adds the slack variables (f_static, f_sliding, c), and impose all the constraints in sliding_friction_complementarity_constraint.

Parameters

contact_wrench_evaluator	Evaluates the contact wrench between a pair of geometries.
complementarity_tolerance	The tolerance on the complementarity constraint.
q_vars	The variable for the generalized position q in prog.
v_vars	The variable for the generalized velocity v in prog.
lambda_vars	The varaibles to parameterize the contact wrench between this pair of geometry.
prog	The optimization program to which the sliding friction complementarity constraint is imposed.

Returns

(sliding_friction_complementarity_constraint, static_friction_cone_constraint), the pair of constraint that imposes (1)-(4) and (6) in sliding_friction_complementarity_constraint.

AddSlidingFrictionComplementarityImplicitContactConstraint()

std::pair< solvers::Binding< internal::SlidingFrictionComplementarityNonlinearConstraint >, solvers::Binding< internal::StaticFrictionConeComplementarityNonlinearConstraint > > AddSlidingFrictionComplementarityImplicitContactConstraint	(	const ContactWrenchEvaluator *	contact_wrench_evaluator,
		double	complementarity_tolerance,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	q_vars,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	v_vars,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	lambda_vars,
		solvers::MathematicalProgram *	prog
	)

For a pair of geometries in implicit contact (they may or may not be in contact, adds the sliding friction complementarity constraint explained in sliding_friction_complementarity_constraint.

The input arguments are the same as those in AddSlidingFrictionComplementarityExplicitContactConstraint(). The difference is that the returned argument includes the nonlinear complementarity binding 0 ≤ φ(q) ⊥ fₙ≥ 0, which imposes the constraint for implicit contact.

AddStaticFrictionConeComplementarityConstraint()

solvers::Binding< internal::StaticFrictionConeComplementarityNonlinearConstraint > AddStaticFrictionConeComplementarityConstraint	(	const ContactWrenchEvaluator *	contact_wrench_evaluator,
		double	complementarity_tolerance,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	q_vars,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	lambda_vars,
		solvers::MathematicalProgram *	prog
	)

Adds the complementarity constraint on the static friction force between a pair of contacts |ft_W| <= μ * n_Wᵀ * f_W (static friction force in the friction cone).

fn_W * sdf = 0 (complementarity condition) sdf >= 0 (no penetration) where sdf stands for signed distance function, ft_W stands for the tangential friction force expressed in the world frame.

Mathematically, we add the following constraints to the optimization program

f_Wᵀ * ((μ² + 1)* n_W * n_Wᵀ - I) * f_W ≥ 0                    (1)
n_Wᵀ * f_W = α                                                 (2)
sdf(q) = β                                                     (3)
0 ≤ α * β ≤ ε                                                  (4)
α ≥ 0                                                          (5)
β ≥ 0                                                          (6)

the slack variables α and β are added to the optimization program as well.

Parameters

	contact_wrench_evaluator	The evaluator to compute the contact wrench expressed in the world frame.
	complementarity_tolerance	ε in the documentation above.
	q_vars	The decision variable for the generalized configuration q.
	lambda_vars	The decision variable to parameterize the contact wrench.
[in,out]	prog	The optimization program to which the constraint is added.

Returns

binding The binding containing the nonlinear constraints (1)-(4).

Precondition

Both q_vars and lambda_vars have been added to prog before calling this function.

AddTwoFreeBodiesToPlant()

void AddTwoFreeBodiesToPlant

(

MultibodyPlant< T > *

model

)

Adds two free bodies to a MultibodyPlant.

ApproximateBoundedNormByLinearConstraints()

void drake::multibody::ApproximateBoundedNormByLinearConstraints	(	const Eigen::Ref< const Vector3< symbolic::Expression >> &	x,
		double	c,
		solvers::MathematicalProgram *	prog
	)

BoxSphereSignedDistance() [1/2]

T BoxSphereSignedDistance	(	const Eigen::Ref< const Eigen::Vector3d > &	box_size,
		double	radius,
		const math::RigidTransform< T > &	X_WB,
		const math::RigidTransform< T > &	X_WS
	)

Compute the signed distance between a box and a sphere.

Parameters

box_size	The size of the box.
radius	The radius of the sphere.
X_WB	the pose of the box (B) in the world frame (W).
X_WS	the pose of the sphere (S) in the world frame (W).

BoxSphereSignedDistance() [2/2]

T drake::multibody::BoxSphereSignedDistance	(	const Eigen::Vector3d &	box_size,
		double	radius,
		const VectorX< T > &	x
	)

BoxSphereSignedDistance< AutoDiffXd >()

template AutoDiffXd drake::multibody::BoxSphereSignedDistance< AutoDiffXd >	(	const Eigen::Ref< const Eigen::Vector3d > &	box_size,
		double	radius,
		const math::RigidTransform< AutoDiffXd > &	X_WB,
		const math::RigidTransform< AutoDiffXd > &	X_WS
	)

BoxSphereSignedDistance< double >()

template double drake::multibody::BoxSphereSignedDistance< double >	(	const Eigen::Ref< const Eigen::Vector3d > &	box_size,
		double	radius,
		const math::RigidTransform< double > &	X_WB,
		const math::RigidTransform< double > &	X_WS
	)

CalcContactFrictionFromSurfaceProperties()

CoulombFriction<T> drake::multibody::CalcContactFrictionFromSurfaceProperties	(	const CoulombFriction< T > &	surface_properties1,
		const CoulombFriction< T > &	surface_properties2
	)

Given the surface properties of two different surfaces, this method computes the Coulomb's law coefficients of friction characterizing the interaction by friction of the given surface pair.

The surface properties are specified by individual Coulomb's law coefficients of friction. As outlined in the class's documentation for CoulombFriction, friction coefficients characterize a surface pair and not individual surfaces. However, we find it useful in practice to associate the abstract idea of friction coefficients to a single surface. Please refer to the documentation for CoulombFriction for details on this topic.

More specifically, this method computes the contact coefficients for the given surface pair as:

  μ = 2μₘμₙ/(μₘ + μₙ)

where the operation above is performed separately on the static and dynamic friction coefficients.

Parameters

[in]	surface_properties1	Surface properties for surface 1. Specified as an individual set of Coulomb's law coefficients of friction.
[in]	surface_properties2	Surface properties for surface 2. Specified as an individual set of Coulomb's law coefficients of friction.

Returns

the combined friction coefficients for the interacting surfaces.

CompareAutoDiffVectors()

std::enable_if< std::is_same<typename DerivedA::Scalar, typename DerivedB::Scalar>::value && std::is_same<typename DerivedA::Scalar, AutoDiffXd>::value>::type drake::multibody::CompareAutoDiffVectors	(	const Eigen::MatrixBase< DerivedA > &	a,
		const Eigen::MatrixBase< DerivedB > &	b,
		double	tol
	)

Compares if two eigen matrices of AutoDiff have the same values and gradients.

CompareDrakeJointToClone()

bool CompareDrakeJointToClone	(	const DrakeJoint &	original,
		const DrakeJoint &	clone
	)

CompareFixedAxisOneDofJointToClone()

bool drake::multibody::CompareFixedAxisOneDofJointToClone	(	const FixedAxisOneDoFJoint< Derived > &	original,
		const FixedAxisOneDoFJoint< Derived > &	clone
	)

CompareFixedJointToClone()

bool CompareFixedJointToClone	(	const FixedJoint &	original,
		const FixedJoint &	other
	)

CompareHelicalJointToClone()

bool CompareHelicalJointToClone	(	const HelicalJoint &	original,
		const HelicalJoint &	clone
	)

ComparePrismaticJointToClone()

bool ComparePrismaticJointToClone	(	const PrismaticJoint &	original,
		const PrismaticJoint &	clone
	)

CompareQuaternionBallJointToClone()

bool CompareQuaternionBallJointToClone	(	const QuaternionBallJoint &	original,
		const QuaternionBallJoint &	clone
	)

CompareQuaternionFloatingJointToClone()

bool CompareQuaternionFloatingJointToClone	(	const QuaternionFloatingJoint &	original,
		const QuaternionFloatingJoint &	clone
	)

CompareRevoluteJointToClone()

bool CompareRevoluteJointToClone	(	const RevoluteJoint &	original,
		const RevoluteJoint &	clone
	)

CompareRollPitchYawFloatingJointToClone()

bool CompareRollPitchYawFloatingJointToClone	(	const RollPitchYawFloatingJoint &	original,
		const RollPitchYawFloatingJoint &	clone
	)

ComputeCollisionSphereCenterPosition()

Vector3<T> drake::multibody::ComputeCollisionSphereCenterPosition	(	const Vector3< T > &	p_WB,
		const Quaternion< T > &	quat_WB,
		const math::RigidTransformd &	X_BS
	)

ConstructBoxSphereDiagram()

std::unique_ptr<systems::Diagram<T> > drake::multibody::ConstructBoxSphereDiagram	(	const Eigen::Vector3d &	box_size,
		double	radius,
		MultibodyPlant< T > **	plant,
		geometry::SceneGraph< T > **	scene_graph
	)

ConstructIiwaPlant()

std::unique_ptr< MultibodyPlant< double > > ConstructIiwaPlant	(	const std::string &	file_path,
		double	time_step
	)

Constructs a MultibodyPlant consisting of an Iiwa robot.

ConstructTwoFreeBodiesPlant()

std::unique_ptr< MultibodyPlant< T > > ConstructTwoFreeBodiesPlant

(

)

Constructs a MultibodyPlant consisting of two free bodies.

ConstructTwoFreeBodiesPlant< AutoDiffXd >()

template std::unique_ptr<MultibodyPlant<AutoDiffXd> > drake::multibody::ConstructTwoFreeBodiesPlant< AutoDiffXd >

(

)

ConstructTwoFreeBodiesPlant< double >()

template std::unique_ptr<MultibodyPlant<double> > drake::multibody::ConstructTwoFreeBodiesPlant< double >

(

)

CreateLoadRobotMessage()

lcmt_viewer_load_robot CreateLoadRobotMessage

(

const RigidBodyTree< double > &

tree

)

Creates and returns an lcmt_viewer_load_robot message containing the visual geometries from the provided RigidBodyTree.

Note that this includes any visual geometries attached to the world body.

Instantiated templates for the following ScalarTypes are provided:

• double

They are already available to link against in the containing library.

CreateLoadRobotMessage< double >()

template lcmt_viewer_load_robot drake::multibody::CreateLoadRobotMessage< double >

(

const RigidBodyTree< double > &

tree

)

default_model_instance()

ModelInstanceIndex drake::multibody::default_model_instance

(

)

Returns the model instance which contains all tree elements with no explicit model instance specified.

Distances()

VectorX<S> drake::multibody::Distances	(	const MultibodyPlant< T > &	plant,
		systems::Context< T > *	context,
		const Eigen::Ref< const VectorX< S >> &	q,
		double	influence_distance
	)

DoEvalGeneric() [1/4]

void drake::multibody::DoEvalGeneric	(	const MultibodyPlant< T > &	plant,
		systems::Context< T > *	context,
		const FrameIndex	frameA_index,
		const FrameIndex	frameB_index,
		const Eigen::Vector3d &	p_BQ,
		const Eigen::Ref< const VectorX< S >> &	x,
		VectorX< S > *	y
	)

DoEvalGeneric() [2/4]

void drake::multibody::DoEvalGeneric	(	const MultibodyPlant< T > &	plant,
		systems::Context< T > *	context,
		const FrameIndex	frameA_index,
		const FrameIndex	frameB_index,
		const Eigen::Vector3d &	p_AS,
		const Eigen::Vector3d &	n_A,
		const Eigen::Vector3d	p_BT,
		double	cos_cone_half_angle,
		const Eigen::Ref< const VectorX< S >> &	x,
		VectorX< S > *	y
	)

DoEvalGeneric() [3/4]

void drake::multibody::DoEvalGeneric	(	const MultibodyPlant< T > &	plant,
		systems::Context< T > *	context,
		FrameIndex	frameAbar_index,
		FrameIndex	frameBbar_index,
		const math::RotationMatrix< double > &	R_AbarA,
		const math::RotationMatrix< double > &	R_BbarB,
		const Eigen::Ref< const VectorX< S >> &	x,
		VectorX< S > *	y
	)

DoEvalGeneric() [4/4]

void drake::multibody::DoEvalGeneric	(	const MultibodyPlant< T > &	plant,
		systems::Context< T > *	context,
		const FrameIndex	frameA_index,
		const FrameIndex	frameB_index,
		const Eigen::Vector3d &	a_unit_A,
		const Eigen::Vector3d &	b_unit_B,
		const Eigen::Ref< const VectorX< S >> &	x,
		VectorX< S > *	y
	)

EvalConstraintGradient() [1/8]

void drake::multibody::EvalConstraintGradient	(	const systems::Context< T > &	,
		const MultibodyPlant< T > &	,
		const Frame< T > &	,
		const Frame< T > &	,
		const Vector3< T > &	p_AQ,
		const Eigen::Vector3d &	,
		const Eigen::Ref< const VectorX< T >> &	,
		VectorX< T > *	y
	)

EvalConstraintGradient() [2/8]

void drake::multibody::EvalConstraintGradient	(	const systems::Context< T > &	,
		const MultibodyPlant< T > &	,
		const Frame< T > &	,
		const Frame< T > &	,
		const math::RotationMatrix< double > &	,
		const math::RotationMatrix< T > &	R_AB,
		const Vector3< T > &	,
		const Eigen::Ref< const VectorX< T >> &	,
		VectorX< T > *	y
	)

EvalConstraintGradient() [3/8]

void drake::multibody::EvalConstraintGradient	(	const systems::Context< double > &	context,
		const MultibodyPlant< double > &	plant,
		const Frame< double > &	frameA,
		const Frame< double > &	frameB,
		const Eigen::Vector3d &	p_AQ,
		const Eigen::Vector3d &	p_BQ,
		const Eigen::Ref< const AutoDiffVecXd > &	x,
		AutoDiffVecXd *	y
	)

EvalConstraintGradient() [4/8]

void drake::multibody::EvalConstraintGradient	(	const systems::Context< T > &	,
		const MultibodyPlant< T > &	,
		const Frame< T > &	,
		const Frame< T > &	,
		const Eigen::Vector3d &	,
		const Eigen::Vector3d &	,
		const math::RotationMatrix< T > &	,
		const Eigen::Ref< const VectorX< T >> &	,
		VectorX< T > *
	)

EvalConstraintGradient() [5/8]

void drake::multibody::EvalConstraintGradient	(	const systems::Context< double > &	context,
		const MultibodyPlant< double > &	plant,
		const Frame< double > &	frameAbar,
		const Frame< double > &	frameBbar,
		const math::RotationMatrix< double > &	R_AbarA,
		const math::RotationMatrix< double > &	R_AB,
		const Vector3< double > &	r_AB,
		const Eigen::Ref< const AutoDiffVecXd > &	x,
		AutoDiffVecXd *	y
	)

EvalConstraintGradient() [6/8]

void drake::multibody::EvalConstraintGradient	(	const systems::Context< T > &	,
		const MultibodyPlant< T > &	,
		const Frame< T > &	,
		const Frame< T > &	,
		const Eigen::Vector3d &	,
		const Eigen::Vector3d &	,
		const Vector3< T > &	,
		const T &	,
		const Vector2< T > &	g,
		const Eigen::Ref< const VectorX< T >> &	,
		VectorX< T > *	y
	)

EvalConstraintGradient() [7/8]

void drake::multibody::EvalConstraintGradient	(	const systems::Context< double > &	context,
		const MultibodyPlant< double > &	plant,
		const Frame< double > &	frameA,
		const Frame< double > &	frameB,
		const Eigen::Vector3d &	a_unit_A,
		const Eigen::Vector3d &	b_unit_B,
		const math::RotationMatrix< double > &	R_AB,
		const Eigen::Ref< const AutoDiffVecXd > &	x,
		AutoDiffVecXd *	y
	)

EvalConstraintGradient() [8/8]

void drake::multibody::EvalConstraintGradient	(	const systems::Context< double > &	context,
		const MultibodyPlant< double > &	plant,
		const Frame< double > &	frameA,
		const Frame< double > &	frameB,
		const Eigen::Vector3d &	p_BT,
		const Eigen::Vector3d &	n_A,
		const Eigen::Vector3d &	cos_cone_half_angle_squared_times_p,
		const double &	p_dot_n,
		const Eigen::Vector2d &	g,
		const Eigen::Ref< const AutoDiffVecXd > &	x,
		AutoDiffVecXd *	y
	)

EvalDistance()

void drake::multibody::EvalDistance	(	const MultibodyPlant< T > &	plant,
		const SortedPair< geometry::GeometryId > &	geometry_pair,
		systems::Context< T > *	context,
		const Eigen::Ref< const VectorX< S >> &	x,
		VectorX< S > *	y
	)

GTEST_TEST() [1/7]

drake::multibody::GTEST_TEST	(	StaticEquilibriumProblemTest	,
		SphereOnGroundTest
	)

GTEST_TEST() [2/7]

drake::multibody::GTEST_TEST	(	StaticFrictionConeConstraint	,
		TestEval
	)

GTEST_TEST() [3/7]

drake::multibody::GTEST_TEST	(	StaticFrictionConeComplementarityNonlinearConstraint	,
		TestEval
	)

GTEST_TEST() [4/7]

drake::multibody::GTEST_TEST	(	InverseKinematicsTest	,
		ConstructorWithJointLimits
	)

GTEST_TEST() [5/7]

drake::multibody::GTEST_TEST	(	TestStaticEquilibriumProblem	,
		TwoSpheresWithinBin
	)

GTEST_TEST() [6/7]

drake::multibody::GTEST_TEST	(	MinimumDistanceConstraintTest	,
		MultibodyPlantWithouthGeometrySource
	)

GTEST_TEST() [7/7]

drake::multibody::GTEST_TEST	(	MinimumDistanceConstraintTest	,
		MultibodyPlantWithoutCollisionPairs
	)

operator+() [1/3]

SpatialForce<T> drake::multibody::operator+	(	const SpatialForce< T > &	F1_Sp_E,
		const SpatialForce< T > &	F2_Sp_E
	)

Computes the resultant spatial force as the addition of two spatial forces F1_Sp_E and F2_Sp_E on a same system or body S, at the same point P and expressed in the same frame E.

Return values

Fr_Sp_E

The resultant spatial force on system or body S from combining F1_Sp_E and F2_Sp_E, applied at the same point P and in the same expressed-in frame E as the operand spatial forces.

operator+() [2/3]

SpatialMomentum<T> drake::multibody::operator+	(	const SpatialMomentum< T > &	L1_NSp_E,
		const SpatialMomentum< T > &	L2_NSp_E
	)

Computes the resultant spatial momentum as the addition of two spatial momenta L1_NSp_E and L2_NSp_E on a same system S, about the same point P and expressed in the same frame E.

Return values

Lc_NSp_E

The combined spatial momentum of system S from combining L1_NSp_E and L2_NSp_E, applied about the same point P, and in the same expressed-in frame E as the operand spatial momenta.

operator+() [3/3]

SpatialVelocity<T> drake::multibody::operator+	(	const SpatialVelocity< T > &	V_MAb_E,
		const SpatialVelocity< T > &	V_AB_E
	)

Performs the addition of two spatial velocities.

This operator returns the spatial velocity that results from adding the operands as if they were 6-dimensional vectors. In other words, the resulting spatial velocity contains a rotational component which is the 3-dimensional addition of the operand's rotational components and a translational component which is the 3-dimensional addition of the operand's translational components.

The addition of two spatial velocities has a clear physical meaning but can only be performed if the operands meet strict conditions. In addition the the usual requirement of common expressed-in frames, both spatial velocities must be for frames with the same origin point. The general idea is that if frame A has a spatial velocity with respect to M, and frame B has a spatial velocity with respect to A, we want to "compose" them so that we get frame B's spatial velocity in M. But that can't be done directly since frames A and B don't have the same origin. So:

Given the velocity V_MA_E of a frame A in a measured-in frame M, and the velocity V_AB_E of a frame B measured in frame A (both expressed in a common frame E), we can calculate V_MB_E as their sum after shifting A's velocity to point Bo:

  V_MB_E = V_MA_E.Shift(p_AB_E) + V_AB_E

where p_AB_E is the position vector from A's origin to B's origin, expressed in E. This shift can also be thought of as yielding the spatial velocity of a new frame Ab, which is an offset frame rigidly aligned with A, but with its origin shifted to B's origin:

  V_MAb_E = V_MA_E.Shift(p_AB_E)
  V_MB_E = V_MAb_E + V_AB_E

The addition in the last expression is what is carried out by this operator; the caller must have already performed the necessary shift.

operator-()

SpatialVelocity<T> drake::multibody::operator-	(	const SpatialVelocity< T > &	V_MB_E,
		const SpatialVelocity< T > &	V_MAb_E
	)

The addition of two spatial velocities relates to the composition of the spatial velocities for two frames given we know the relative spatial velocity between them, see operator+(const SpatialVelocity<T>&, const SpatialVelocity<T>&) for further details.

Mathematically, operator-(v1, v2) is equivalent ot operator+(v1, -v2).

Physically, the subtraction operation allow us to compute the relative velocity between two frames. As an example, consider having the the spatial velocities V_MA and V_MB of two frames A and B respectively measured in the same frame M. The velocity of B in A can be obtained as:

  V_AB_E = V_MB_E - V_MAb_E = V_AB_E = V_MB_E - V_MA_E.Shift(p_AB_E)

where we have expressed all quantities in a common frame E. Notice that, as explained in the documentation for operator+(const SpatialVelocity<T>&, const SpatialVelocity<T>&) a shift operation with SpatialVelocity::Shift() operation is needed.

operator<<()

std::ostream& drake::multibody::operator<<	(	std::ostream &	out,
		const PackageMap &	package_map
	)

QuaternionToVectorWxyz()

Eigen::Vector4d QuaternionToVectorWxyz

(

const Eigen::Quaterniond &

q

)

Convert an Eigen::Quaternion to a vector 4d in the order (w, x, y, z).

TEST_F() [1/25]

drake::multibody::TEST_F	(	TwoFreeSpheresTest	,
		Constructor
	)

TEST_F() [2/25]

drake::multibody::TEST_F	(	TwoFreeSpheresTest	,
		TestEval
	)

TEST_F() [3/25]

drake::multibody::TEST_F	(	RigidBodyTreeKinematicsTests	,
		TestDoKinematicWithValidCache
	)

TEST_F() [4/25]

drake::multibody::TEST_F	(	RigidBodyTreeKinematicsTests	,
		TestDoKinematicWithBadCache1
	)

TEST_F() [5/25]

drake::multibody::TEST_F	(	RigidBodyTreeKinematicsTests	,
		TestDoKinematicWithBadCache2
	)

TEST_F() [6/25]

drake::multibody::TEST_F	(	TwoFreeBodiesTest	,
		PositionConstraint
	)

TEST_F() [7/25]

drake::multibody::TEST_F	(	TwoFreeBodiesTest	,
		OrientationConstraint
	)

TEST_F() [8/25]

drake::multibody::TEST_F	(	TwoFreeSpheresMinimumDistanceTest	,
		ExponentialPenalty
	)

TEST_F() [9/25]

drake::multibody::TEST_F	(	TwoFreeSpheresMinimumDistanceTest	,
		QuadraticallySmoothedHingePenalty
	)

TEST_F() [10/25]

drake::multibody::TEST_F	(	TwoFreeBodiesTest	,
		GazeTargetConstraint
	)

TEST_F() [11/25]

drake::multibody::TEST_F	(	TwoFreeBodiesTest	,
		AngleBetweenVectorsConstraint
	)

TEST_F() [12/25]

drake::multibody::TEST_F	(	AcrobotTests	,
		PoseTests
	)

TEST_F() [13/25]

drake::multibody::TEST_F	(	TwoFreeSpheresTest	,
		NonpositiveInfluenceDistanceOffset
	)

TEST_F() [14/25]

drake::multibody::TEST_F	(	AcrobotTests	,
		SpatialVelocityTests
	)

TEST_F() [15/25]

drake::multibody::TEST_F	(	TwoFreeSpheresTest	,
		NonfiniteInfluenceDistanceOffset
	)

TEST_F() [16/25]

drake::multibody::TEST_F	(	TwoFreeSpheresTest	,
		MinimumDistanceConstraintTest
	)

TEST_F() [17/25]

drake::multibody::TEST_F	(	BoxSphereTest	,
		Test
	)

TEST_F() [18/25]

drake::multibody::TEST_F	(	RBTDifferentialKinematicsHelperTest	,
		RPYPoseTest
	)

TEST_F() [19/25]

drake::multibody::TEST_F	(	RBTDifferentialKinematicsHelperTest	,
		RPYTwistInWorldAlignedBodyTest
	)

TEST_F() [20/25]

drake::multibody::TEST_F	(	RBTDifferentialKinematicsHelperTest	,
		RPYJacobianTest
	)

TEST_F() [21/25]

drake::multibody::TEST_F	(	RBTDifferentialKinematicsHelperTest	,
		RPYJacobianDotTimeVTest
	)

TEST_F() [22/25]

drake::multibody::TEST_F	(	RBTDifferentialKinematicsHelperTest	,
		QuatPoseTest
	)

TEST_F() [23/25]

drake::multibody::TEST_F	(	RBTDifferentialKinematicsHelperTest	,
		QuatTwistInWorldAlignedBodyTest
	)

TEST_F() [24/25]

drake::multibody::TEST_F	(	RBTDifferentialKinematicsHelperTest	,
		QuatJacobianTest
	)

TEST_F() [25/25]

drake::multibody::TEST_F	(	RBTDifferentialKinematicsHelperTest	,
		QuatJacobianDotTimeVTest
	)

TestKinematicConstraintEval()

void drake::multibody::TestKinematicConstraintEval	(	const ConstraintType &	constraint_from_double,
		const ConstraintType &	constraint_from_autodiff,
		const Eigen::Ref< const Eigen::VectorXd > &	x_double,
		const Eigen::Ref< const Eigen::MatrixXd > &	dx,
		double	gradient_tol
	)

Since we can construct the kinematic constraint using both MultibodyPlant<double> (as constraint_from_double) and MultibodyPlant<AutoDiffXd> (as constraint_from_autodiff), and evaluate the constraint with both VectorX<double> and VectorX<AutoDiffXd>, we check if the following evaluation results match:

1. constraint_from_double.Eval(x_double) = constraint_from_autodiff.Eval(x_double).
2. constraint_from_double.Eval(x_autodiff) = constraint_from_autodiff.Eval(x_autodiff).
3. constraint_from_double.Eval(x_double) = constraint_from_double.Eval(x_autodiff).value()
4. numerical_gradient(constraint_from_double.Eval(x_double)) ≈ constraint_from_double.Eval(x_autodiff).

   Parameters

   constraint_from_double	A kinematic constraint constructed from MultibodyPlant<double>
   constraint_from_autodiff	The same kinematic constraint, but constructed from MultibodyPlant<AutoDiffXd>.
   x_double	The value of x passed to the constraint Eval function.
   dx	The gradient of x_double. dx must have the same number of rows as x_double.
   gradient_tol	The tolerance for checking the 4th condition above, that the numerical gradient should be close to the analytical gradient.

Vector4ToQuaternion()

Eigen::Quaterniond drake::multibody::Vector4ToQuaternion

(

const Eigen::Ref< const Eigen::Vector4d > &

q

)

world_index()

BodyIndex drake::multibody::world_index

(

)

For every MultibodyTree the world body always has this unique index and it is always zero.

world_model_instance()

ModelInstanceIndex drake::multibody::world_model_instance

(

)

Returns the model instance containing the world body.

For every MultibodyTree the world body always has this unique model instance and it is always zero (as described in #3088).

Variable Documentation

kInf

const double kInf = std::numeric_limits<double>::infinity()

kNumPositionsForTwoFreeBodies

constexpr int kNumPositionsForTwoFreeBodies {14}