drake::multibody Namespace Reference

Namespaces
	benchmarks
	contact_solvers
	fem
	hydroelastics
	meshcat
	mpm
	parsing
	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	AngleBetweenVectorsCost
	Implements a cost of the form c*(1-cosθ), where θ is the angle between two vectors a and b. 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	BallRpyJoint
	This Joint allows two bodies to rotate freely relative to one another. More...
struct	CalcGridPointsOptions
class	CentroidalMomentumConstraint
	Impose the constraint CentroidalMomentum(q, v) - h_WC = 0 with decision variables [q;v;h_WC] or CentroidalAngularMomentum(q, v) - k_WC = 0 with decision variables [q; v; k_WC] h_WC is the 6D spatial momentum (linear and angular momentum about the center of mass C) expressed in the world frame (W). More...
class	CollisionFilterGroups
	This is storage for parsed collision filter groups and group pairs. More...
class	ComInPolyhedronConstraint
	Constrains the center of mass to lie within a polyhedron lb <= A * p_EC <= ub where p_EC is the position of the center-of-mass (C) expressed in a frame E. More...
class	ComPositionConstraint
	Impose the constraint p_EScm(q) - p_EC = 0, where p_EScm(q) is a function that computes the center-of-mass (COM) position from robot generalized position q, expressed in a frame E. More...
class	ConstraintRelaxingIk
	A wrapper class around the IK planner. More...
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	DeformableContactInfo
	A class containing information regarding contact and contact response between two geometries belonging to a pair of bodies with at least one of them being a deformable body. More...
class	DeformableModel
	DeformableModel implements the interface in PhysicalModel and provides the functionalities to specify deformable bodies. More...
class	DifferentialInverseKinematicsIntegrator
	A LeafSystem that integrates successive calls to DoDifferentialInverseKinematics (which produces joint velocity commands) to produce joint position commands. More...
class	DifferentialInverseKinematicsParameters
	Contains parameters for differential inverse kinematics. More...
struct	DifferentialInverseKinematicsResult
class	DistanceConstraint
	Constrains the distance between a pair of geometries to be within a range [distance_lower, distance_upper]. More...
class	DoorHinge
	This ForceElement models a revolute DoorHinge joint that could exhibit different force/torque characteristics at different states due to the existence of different type of torques on the joint. More...
struct	DoorHingeConfig
	Configuration structure for the DoorHinge. More...
struct	ExternallyAppliedSpatialForce
class	ExternallyAppliedSpatialForceMultiplexer
	Concatenates multiple std::vector<>'s of ExternallyAppliedSpatialForce<T>. More...
class	FixedOffsetFrame
	FixedOffsetFrame represents a material frame F whose pose is fixed with respect to a parent material frame P. More...
class	ForceDensityField
	The ForceDensityField class is an abstract base class that represents a force density field affecting deformable bodies in a MultibodyPlant. 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) of its underlying RigidBody. More...
class	FrameBase
	FrameBase is deprecated and will be removed on or after 2025-01-01. More...
class	GaussianTriangleQuadratureRule
class	GazeTargetConstraint
	Constrains a target point T to be within a cone K. More...
struct	GeometryPairContactWrenchEvaluatorBinding
class	GlobalInverseKinematics
	Solves the inverse kinematics problem as a mixed integer convex optimization problem. More...
class	GravityForceField
	A uniform gravitational force density field for a uniform density object. More...
class	HydroelasticContactInfo
	A class containing information regarding contact and contact response between two geometries attached to a pair of bodies. More...
class	HydroelasticContactInfo< symbolic::Expression >
	Full specialization of HydroelasticContactInfo for T = Expression, with no member data. 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	LinearBushingRollPitchYaw
	This ForceElement models a massless flexible bushing that connects a frame A of a link (body) L0 to a frame C of a link (body) L1. 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	MinimumDistanceLowerBoundConstraint
	Constrain min(d) >= lb, namely 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 lb. More...
class	MinimumDistanceUpperBoundConstraint
	Constrain min(d) <= ub, namely at least one signed distance between a candidate pairs of geometries (according to the logic of SceneGraphInspector::GetCollisionCandidates()) to be no larger than a specified ub. More...
class	MultibodyElement
	A class representing an element (subcomponent) of a MultibodyPlant or (internally) a MultibodyTree. 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...
struct	MultibodyPlantConfig
	The set of configurable properties on a MultibodyPlant. More...
class	MultibodyPlantRemodeling
class	MultibodyPlantTester
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	OrientationCost
	Implements a cost of the form c * (1 - cos(θ)), where θ is the angle between the orientation of frame A and the orientation of frame B, and c is a cost scaling. More...
class	PackageMap
	Maps ROS package names to their full path on the local file system. More...
class	Parser
	Parses model description input into a MultibodyPlant and (optionally) a SceneGraph. More...
struct	PdControllerGains
	PD controller gains. More...
class	PhysicalModel
	(Internal) PhysicalModel provides the functionalities to extend the type of physical model of MultibodyPlant. More...
class	PlanarJoint
	This joint models a planar joint allowing two bodies to translate and rotate relative to one another in a plane with three degrees of freedom. More...
class	PointPairContactInfo
	A class containing information regarding contact response between two bodies including: More...
class	PointToLineDistanceConstraint
	Constrain that the distance between a point P on frame B1 and another line L on frame B2 is within a range [distance_lower, distance_upper]. More...
class	PointToPointDistanceConstraint
	Constrain that the distance between a point P1 on frame B1 and another point P2 on frame B2 is within a range [distance_lower, distance_upper]. More...
class	PolyhedronConstraint
	Constrain the position of points P1, P2, ..., Pn to satisfy the constraint A. 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	PositionCost
	Implements a cost of the form (p_AP - p_AQ)ᵀ C (p_AP - p_AQ), where point P is specified relative to frame A and point Q is specified relative to frame B, and the cost is evaluated in frame A. More...
class	PrismaticJoint
	This Joint allows two bodies to translate relative to one another along a common axis. More...
class	PrismaticSpring
	This ForceElement models a linear spring attached to a PrismaticJoint and applies a force to that joint according to. More...
class	Propeller
	A System that connects to the MultibodyPlant in order to model the effects of one or more controlled propellers acting on a Body. More...
struct	PropellerInfo
	Parameters that describe the kinematic frame and force-production properties of a single propeller. More...
class	QuaternionEulerIntegrationConstraint
	If we have a body with orientation quaternion z₁ at time t₁, and a quaternion z₂ at time t₂ = t₁ + h, with the angular velocity ω (expressed in the world frame), we impose the constraint that the body rotates at a constant velocity ω from quaternion z₁ to quaternion z₂ within time interval h. More...
class	QuaternionFloatingJoint
	This Joint allows two bodies to move freely relatively to one another. More...
class	RationalForwardKinematics
	For certain robots (whose joint transforms are algebraic functions of joint variables, for example revolute/prismatic/floating-base joints), we can represent the pose (position, orientation) of each body, as rational functions, namely n(s) / d(s) where both the numerator n(s) and denominator d(s) are polynomials of s, and s is some variable related to the generalized position. 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	RigidBodyFrame
	A RigidBodyFrame is a material Frame that serves as the unique reference frame for a RigidBody. More...
class	RotationalInertia
	This class describes the mass distribution (inertia properties) of a body or composite body about a particular point. More...
class	RpyFloatingJoint
	This Joint allows a rigid body to move freely with respect to its parent rigid body. More...
class	ScopedName
	A delimited string name for a multibody element, e.g., "robot1::torso". More...
class	ScrewJoint
	This joint models a screw joint allowing two bodies to rotate about one axis while translating along that same axis with one degree of freedom. More...
struct	SignedDistanceWithTimeDerivative
	The struct containing the signed distance and its time derivative between a pair of geometries. More...
class	SpatialAcceleration
	This class represents a spatial acceleration A and has 6 elements with an angular (rotational) acceleration α (3-element vector) on top of a translational (linear) acceleration 𝐚 (3-element vector). More...
class	SpatialForce
	This class represents a spatial force F (also called a wrench) and has 6 elements with a torque 𝛕 (3-element vector) on top of a force 𝐟 (3-element vector). More...
class	SpatialInertia
	This class represents the physical concept of a Spatial Inertia. More...
class	SpatialMomentum
	This class represents a spatial momentum L and has 6 elements with an angular (rotational) momentum 𝐡 (3-element vector) on top of a translational (linear) momentum 𝐥 (3-element vector). More...
class	SpatialVector
	This class represents a spatial vector and has 6 elements, with a 3-element rotational vector on top of a 3-element translational vector. More...
class	SpatialVelocity
	This class represents a spatial velocity V (also called a twist) and has 6 elements with an angular (rotational) velocity ω (3-element vector) on top of a translational (linear) velocity v (3-element vector). More...
class	SpatialVelocityConstraint
	Constrains the spatial velocity of a frame C, rigidly attached to a frame B, measured and expressed in frame A. 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	TamsiSolver
struct	TamsiSolverIterationStats
	Struct used to store information about the iteration process performed by TamsiSolver. More...
struct	TamsiSolverParameters
	These are the parameters controlling the iteration process of the TamsiSolver solver. More...
class	Toppra
	Solves a Time Optimal Path Parameterization based on Reachability Analysis (TOPPRA) to find the fastest traversal of a given path, satisfying the given constraints. 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	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	UnitQuaternionConstraint
	Constrains the quaternion to have a unit length. More...
class	UniversalJoint
	This joint models a universal joint allowing two bodies to rotate relative to one another with two degrees of freedom. More...
class	WeldJoint
	This Joint fixes the relative pose between two frames as if "welding" them together. More...
class	Wing
	A System that connects to the MultibodyPlant in order to model the simplified dynamics of an airfoil (or hydrofoil). More...

Typedefs
using	DeformableBodyId = Identifier< class DeformableBodyTag >
	Uniquely identifies a deformable body. More...
using	DeformableBodyIndex = TypeSafeIndex< class DeformableBodyTag >
	(Internal use only) Indexes deformable bodies, only used after Finalize(). More...
template<typename T >
using	PhysicalModelPointerVariant = std::variant< const DeformableModel< T > *, std::monostate >
using	FrameIndex = TypeSafeIndex< class FrameTag >
	Type used to identify frames by index in a multibody plant. More...
using	BodyIndex = TypeSafeIndex< class RigidBodyTag >
	Type used to identify RigidBodies (a.k.a. More...
using	ForceElementIndex = TypeSafeIndex< class ForceElementTag >
	Type used to identify force elements by index within a multibody plant. More...
using	JointIndex = TypeSafeIndex< class JointElementTag >
	Type used to identify joints by index within a multibody plant. More...
using	JointActuatorIndex = TypeSafeIndex< class JointActuatorElementTag >
	Type used to identify actuators by index within a multibody plant. More...
using	MultibodyConstraintId = Identifier< class ConstraintTag >
	Type used to identify constraint by id within a multibody plant. More...
using	ModelInstanceIndex = TypeSafeIndex< class ModelInstanceTag >
	Type used to identify model instances by index within a multibody plant. More...
template<typename T >
using	Body = RigidBody< T >
	(Compatibility) Prefer RigidBody to Body, however this dispreferred alias is available to permit older code to continue working. More...

Enumerations
enum	DifferentialInverseKinematicsStatus { kSolutionFound, kNoSolutionFound, kStuck }
enum	ToppraDiscretization { kCollocation, kInterpolation }
	Selects how linear constraints are enforced for TOPPRA's optimization. More...
enum	ForceDensityType { kPerCurrentVolume, kPerReferenceVolume }
	(Advanced) Enum for the type of force density in ForceDensityField. More...
enum	ContactModel {   kHydroelastic, kPoint, kHydroelasticWithFallback, kHydroelasticsOnly = kHydroelastic,   kPointContactOnly = kPoint }
	Enumeration for contact model options. More...
enum	DiscreteContactSolver { kTamsi, kSap }
	The type of the contact solver used for a discrete MultibodyPlant model. More...
enum	DiscreteContactApproximation { kTamsi, kSap, kSimilar, kLagged }
	The type of the contact approximation used for a discrete MultibodyPlant model. More...
enum	BaseBodyJointType { kQuaternionFloatingJoint, kRpyFloatingJoint, kWeldJoint }
	The kind of joint to be used to connect base bodies to world at Finalize(). More...
enum	TamsiSolverResult { kSuccess = 0, kMaxIterationsReached = 1, kLinearSolverFailed = 2, kAlphaSolverFailed = 3 }
	The result from TamsiSolver::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
std::vector< solvers::Binding< solvers::Constraint > >	AddMultibodyPlantConstraints (const MultibodyPlant< double > &plant, const solvers::VectorXDecisionVariable &q, solvers::MathematicalProgram *prog, systems::Context< double > *plant_context=nullptr)
	For unit quaternion and (holonomic) constraints registered with plant adds a corresponding solver::Constraint to prog, using decision variables q to represent the generalized positions of the plant. More...
std::ostream &	operator<< (std::ostream &os, const DifferentialInverseKinematicsStatus value)
Vector6< double >	ComputePoseDiffInCommonFrame (const math::RigidTransform< double > &X_C0, const math::RigidTransform< double > &X_C1)
	Computes the pose "difference" between X_C0 and X_C1 such that the linear part equals p_C1 - p_C0, and the angular part equals R_C1 * R_C0.inv(), where p and R stand for the position and rotation parts, and C is the common frame. More...
DifferentialInverseKinematicsResult	DoDifferentialInverseKinematics (const Eigen::Ref< const VectorX< double >> &q_current, const Eigen::Ref< const VectorX< double >> &v_current, const Eigen::Ref< const VectorX< double >> &V, const Eigen::Ref< const MatrixX< double >> &J, const DifferentialInverseKinematicsParameters &parameters, const std::optional< Eigen::Ref< const Eigen::SparseMatrix< double >>> &N=std::nullopt, const std::optional< Eigen::Ref< const Eigen::SparseMatrix< double >>> &Nplus=std::nullopt)
	Computes a generalized velocity v_next, via the following MathematicalProgram: More...
DifferentialInverseKinematicsResult	DoDifferentialInverseKinematics (const MultibodyPlant< double > &robot, const systems::Context< double > &context, const Vector6< double > &V_WE_desired, const Frame< double > &frame_E, const DifferentialInverseKinematicsParameters &parameters)
	A wrapper over DoDifferentialInverseKinematics(q_current, v_current, V, J, params) that tracks frame E's spatial velocity. More...
DifferentialInverseKinematicsResult	DoDifferentialInverseKinematics (const MultibodyPlant< double > &robot, const systems::Context< double > &context, const Vector6< double > &V_AE_desired, const Frame< double > &frame_A, const Frame< double > &frame_E, const DifferentialInverseKinematicsParameters &parameters)
	A wrapper over DoDifferentialInverseKinematics(q_current, v_current, V, J, params) that tracks frame E's spatial velocity in frame A. More...
DifferentialInverseKinematicsResult	DoDifferentialInverseKinematics (const MultibodyPlant< double > &robot, const systems::Context< double > &context, const math::RigidTransform< double > &X_WE_desired, const Frame< double > &frame_E, const DifferentialInverseKinematicsParameters &parameters)
	A wrapper over DoDifferentialInverseKinematics(robot, context, V_WE_desired, frame_E, params) that tracks frame E's pose in the world frame. More...
DifferentialInverseKinematicsResult	DoDifferentialInverseKinematics (const MultibodyPlant< double > &robot, const systems::Context< double > &context, const math::RigidTransform< double > &X_AE_desired, const Frame< double > &frame_A, const Frame< double > &frame_E, const DifferentialInverseKinematicsParameters &parameters)
	A wrapper over DoDifferentialInverseKinematics(robot, context, V_AE_desired, frame_A, frame_E, params) that tracks frame E's pose in frame A. More...
template<typename T >
std::vector< solvers::Binding< solvers::Constraint > >	AddUnitQuaternionConstraintOnPlant (const MultibodyPlant< T > &plant, const Eigen::Ref< const VectorX< symbolic::Variable >> &q_vars, solvers::MathematicalProgram *prog)
	Add unit length constraints to all the variables representing quaternion in q_vars. 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...
SignedDistanceWithTimeDerivative	CalcDistanceAndTimeDerivative (const multibody::MultibodyPlant< double > &plant, const SortedPair< geometry::GeometryId > &geometry_pair, const systems::Context< double > &context)
	Given a pair of geometries and the generalized position/velocity of the plant, compute the signed distance between the pair of geometries and the time derivative of the signed distance. 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...
AddMultibodyPlantSceneGraphResult< double >	AddMultibodyPlant (const MultibodyPlantConfig &config, systems::DiagramBuilder< double > *builder)
	Adds a new MultibodyPlant and SceneGraph to the given builder. More...
AddMultibodyPlantSceneGraphResult< double >	AddMultibodyPlant (const MultibodyPlantConfig &plant_config, const geometry::SceneGraphConfig &scene_graph_config, systems::DiagramBuilder< double > *builder)
	Adds a new MultibodyPlant and SceneGraph to the given builder. More...
void	ApplyMultibodyPlantConfig (const MultibodyPlantConfig &config, MultibodyPlant< double > *plant)
	Applies settings given in config to an existing plant. More...
SpatialInertia< double >	CalcSpatialInertia (const geometry::Shape &shape, double density)
	Computes the SpatialInertia of a body made up of a homogeneous material (of given density in kg/m³) uniformly distributed in the volume of the given shape. More...
SpatialInertia< double >	CalcSpatialInertia (const geometry::TriangleSurfaceMesh< double > &mesh, double density)
	Computes the SpatialInertia of a body made up of a homogeneous material (of given density in kg/m³) uniformly distributed in the volume of the given mesh. More...
BodyIndex	world_index ()
	For every MultibodyPlant the world body always has this unique index and it is always zero. More...
FrameIndex	world_frame_index ()
	For every MultibodyPlant the world frame 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...
Visualizing contact results
These functions extend a Diagram with the required components to publish contact results (as reported by MultibodyPlant) to a visualizer (Meldis). We recommend using these functions instead of assembling the requisite components by hand. These must be called during Diagram building. Each function makes modifications to the diagram being constructed by builder including the following changes: adds systems multibody::ContactResultsToLcmSystem and LcmPublisherSystem to the Diagram and connects the draw message output to the publisher input, connects a ContactResults<double>-valued output port to the ContactResultsToLcmSystem system, and sets the publishing rate based on publish_period. The two overloads differ in the following way: One overload takes an OutputPort and one doesn't. This determines what is connected to the ContactResultsToLcmSystem input port. The overload that specifies an OutputPort will attempt to connect that port. The one that doesn't will connect the given plant's contact results output port. The parameters have the following semantics: Parameters builder The diagram builder being used to construct the Diagram. Systems will be added to this builder. plant The System in builder containing the plant whose contact results are to be visualized. scene_graph The SceneGraph that will determine how the geometry names will appear in the lcm message. publish_period An optional period to pass along to the LcmPublisherSystem constructor; when null, a reasonable default period will be used. lcm An optional lcm interface through which lcm messages will be dispatched. Will be allocated internally if none is supplied. If one is given, it must remain alive at least as long as the diagram built from builder. contact_results_port The optional port that will be connected to the ContactResultsToLcmSystem (as documented above). Returns (for all overloads) the LcmPublisherSystem (in case callers, e.g., need to change the default publishing rate). Precondition plant is contained within the supplied builder. scene_graph is contained with the supplied builder. contact_results_port (if given) belongs to a system that is an immediate child of builder.
systems::lcm::LcmPublisherSystem *	ConnectContactResultsToDrakeVisualizer (systems::DiagramBuilder< double > *builder, const MultibodyPlant< double > &plant, const geometry::SceneGraph< double > &scene_graph, lcm::DrakeLcmInterface *lcm=nullptr, std::optional< double > publish_period=std::nullopt)
	MultibodyPlant-connecting overload. More...
systems::lcm::LcmPublisherSystem *	ConnectContactResultsToDrakeVisualizer (systems::DiagramBuilder< double > *builder, const MultibodyPlant< double > &plant, const geometry::SceneGraph< double > &scene_graph, const systems::OutputPort< double > &contact_results_port, lcm::DrakeLcmInterface *lcm=nullptr, std::optional< double > publish_period=std::nullopt)
	OutputPort-connecting overload. More...

Typedef Documentation

Body

using Body = RigidBody<T>

(Compatibility) Prefer RigidBody to Body, however this dispreferred alias is available to permit older code to continue working.

BodyIndex

using BodyIndex = TypeSafeIndex<class RigidBodyTag>

Type used to identify RigidBodies (a.k.a.

Links) by index in a multibody plant. Interchangeable with LinkIndex.

DeformableBodyId

using DeformableBodyId = Identifier<class DeformableBodyTag>

Uniquely identifies a deformable body.

It is valid before and after Finalize().

DeformableBodyIndex

using DeformableBodyIndex = TypeSafeIndex<class DeformableBodyTag>

(Internal use only) Indexes deformable bodies, only used after Finalize().

ForceElementIndex

using ForceElementIndex = TypeSafeIndex<class ForceElementTag>

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

FrameIndex

using FrameIndex = TypeSafeIndex<class FrameTag>

Type used to identify frames by index in a multibody plant.

JointActuatorIndex

using JointActuatorIndex = TypeSafeIndex<class JointActuatorElementTag>

Type used to identify actuators by index within a multibody plant.

JointIndex

using JointIndex = TypeSafeIndex<class JointElementTag>

Type used to identify joints by index within a multibody plant.

ModelInstanceIndex

using ModelInstanceIndex = TypeSafeIndex<class ModelInstanceTag>

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

MultibodyConstraintId

using MultibodyConstraintId = Identifier<class ConstraintTag>

Type used to identify constraint by id within a multibody plant.

PhysicalModelPointerVariant

using PhysicalModelPointerVariant = std::variant<const DeformableModel<T>*, std::monostate>

Enumeration Type Documentation

BaseBodyJointType

enum BaseBodyJointType

strong

The kind of joint to be used to connect base bodies to world at Finalize().

See Working with free bodies for definitions and discussion.

See also

SetBaseBodyJointType() for details.

Enumerator
kQuaternionFloatingJoint	6 dofs, unrestricted orientation.
kRpyFloatingJoint	6 dofs using 3 angles; has singularity.
kWeldJoint	0 dofs, fixed to World.

ContactModel

enum ContactModel

strong

Enumeration for contact model options.

Enumerator
kHydroelastic	Contact forces are computed using the Hydroelastic model. Contact between unsupported geometries will cause a runtime exception.
kPoint	Contact forces are computed using a point contact model, see Compliant Point Contact.
kHydroelasticWithFallback	Contact forces are computed using the hydroelastic model, where possible. For most other unsupported colliding pairs, the point model from kPoint is used. See geometry::QueryObject::ComputeContactSurfacesWithFallback for more details.
kHydroelasticsOnly	Legacy alias. TODO(jwnimmer-tri) Deprecate this constant.
kPointContactOnly	Legacy alias. TODO(jwnimmer-tri) Deprecate this constant.

DifferentialInverseKinematicsStatus

enum DifferentialInverseKinematicsStatus

strong

Enumerator
kSolutionFound	Found the optimal solution.
kNoSolutionFound	Solver unable to find a solution.
kStuck	Unable to follow the desired velocity direction likely due to constraints.

DiscreteContactApproximation

enum DiscreteContactApproximation

strong

The type of the contact approximation used for a discrete MultibodyPlant model.

kTamsi, kSimilar and kLagged are all approximations to the same contact model – Compliant contact with regularized friction, refer to Contact Modeling for further details. The key difference however, is that the kSimilar and kLagged approximations are convex and therefore our contact solver has both theoretical and practical convergence guarantees — the solver will always succeed. Conversely, being non-convex, kTamsi can fail to find a solution.

kSap is also a convex model of compliant contact with regularized friction. There are a couple of key differences however:

• Dissipation is modeled using a linear Kelvin–Voigt model, parameterized by a relaxation time constant. See contact parameters.
• Unlike kTamsi, kSimilar and kLagged where regularization of friction is parameterized by a stiction tolerance (see set_stiction_tolerance()), SAP determines regularization automatically solely based on numerics. Users have no control on the amount of regularization.

How to choose an approximation

The Hunt & Crossley model is based on physics, it is continuous and has been experimentally validated. Therefore it is the preferred model to capture the physics of contact.

Being approximations, kSap and kSimilar introduce a spurious effect of "gliding" in sliding contact, see [Castro et al., 2023]. This artifact is 𝒪(δt) but can be significant at large time steps and/or large slip velocities. kLagged does not suffer from this, but introduces a "weak" coupling of friction that can introduce non-negligible effects in the dynamics during impacts or strong transients.

Summarizing, kLagged is the preferred approximation when strong transients are not expected or don't need to be accurately resolved. If strong transients do need to be accurately resolved (unusual for robotics applications), kSimilar is the preferred approximation.

References

• [Castro et al., 2019] Castro A., Qu A., Kuppuswamy N., Alspach A., Sherman M, 2019. A Transition-Aware Method for the Simulation of Compliant Contact with Regularized Friction. Available online at https://arxiv.org/abs/1909.05700.
• [Castro et al., 2022] Castro A., Permenter F. and Han X., 2022. An Unconstrained Convex Formulation of Compliant Contact. Available online at https://arxiv.org/abs/2110.10107.
• [Castro et al., 2023] Castro A., Han X., and Masterjohn J., 2023. A Theory of Irrotational Contact Fields. Available online at https://arxiv.org/abs/2312.03908

Enumerator
kTamsi	TAMSI solver approximation, see [Castro et al., 2019].
kSap	SAP solver model approximation, see [Castro et al., 2022].
kSimilar	Similarity approximation found in [Castro et al., 2023].
kLagged	Approximation in which the normal force is lagged in Coulomb's law, such that ‖γₜ‖ ≤ μ γₙ₀, [Castro et al., 2023].

DiscreteContactSolver

enum DiscreteContactSolver

strong

The type of the contact solver used for a discrete MultibodyPlant model.

Note: the SAP solver only fully supports scalar type double. For scalar type AutoDiffXd, the SAP solver throws if any constraint (including contact) is detected. As a consequence, one can only run dynamic simulations without any constraints under the combination of SAP and AutoDiffXd. The SAP solver does not support symbolic calculations.

References

• [Castro et al., 2019] Castro, A.M, Qu, A., Kuppuswamy, N., Alspach, A., Sherman, M.A., 2019. A Transition-Aware Method for the Simulation of Compliant Contact with Regularized Friction. Available online at https://arxiv.org/abs/1909.05700.
• [Castro et al., 2022] Castro A., Permenter F. and Han X., 2022. An Unconstrained Convex Formulation of Compliant Contact. Available online at https://arxiv.org/abs/2110.10107.

Enumerator
kTamsi	TAMSI solver, see [Castro et al., 2019].
kSap	SAP solver, see [Castro et al., 2022].

ForceDensityType

enum ForceDensityType

strong

(Advanced) Enum for the type of force density in ForceDensityField.

Enumerator
kPerCurrentVolume	ForceDensityField::EvaluateAt() returns the force per unit of current (deformed) configuration volume.
kPerReferenceVolume	ForceDensityField::EvaluateAt() returns the force per unit of reference configuration volume where the reference undeformed configuration is defined by the input mesh provided by the user.

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.

TamsiSolverResult

enum TamsiSolverResult

strong

The result from TamsiSolver::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.
kAlphaSolverFailed	Could not solve for the α coefficient for per-iteration angle change.

ToppraDiscretization

enum ToppraDiscretization

strong

Selects how linear constraints are enforced for TOPPRA's optimization.

kCollocation - enforces constraints only at each gridpoint. kInterpolation - enforces constraints at each gridpoint and at the following gridpoint using forward integration. Yields higher accuracy at minor computational cost.

Enumerator
kCollocation
kInterpolation

Function Documentation

AddMultibodyPlant() [1/2]

AddMultibodyPlantSceneGraphResult<double> drake::multibody::AddMultibodyPlant	(	const MultibodyPlantConfig &	config,
		systems::DiagramBuilder< double > *	builder
	)

Adds a new MultibodyPlant and SceneGraph to the given builder.

The plant's settings such as time_step are set using the given config.

AddMultibodyPlant() [2/2]

AddMultibodyPlantSceneGraphResult<double> drake::multibody::AddMultibodyPlant	(	const MultibodyPlantConfig &	plant_config,
		const geometry::SceneGraphConfig &	scene_graph_config,
		systems::DiagramBuilder< double > *	builder
	)

Adds a new MultibodyPlant and SceneGraph to the given builder.

The plant's settings such as time_step are set using the given plant_config. The scene graph's settings are set using the given scene_graph_config.

AddMultibodyPlantConstraints()

std::vector<solvers::Binding<solvers::Constraint> > drake::multibody::AddMultibodyPlantConstraints	(	const MultibodyPlant< double > &	plant,
		const solvers::VectorXDecisionVariable &	q,
		solvers::MathematicalProgram *	prog,
		systems::Context< double > *	plant_context = nullptr
	)

For unit quaternion and (holonomic) constraints registered with plant adds a corresponding solver::Constraint to prog, using decision variables q to represent the generalized positions of the plant.

Adds constraints for coupler, distance, ball, and weld constraints. The distance constraint is implemented here as a hard kinematic constraint (i.e., d(q) == d₀), instead of a soft "spring" force.

See also

AddUnitQuaternionConstraintOnPlant() for the unit quaternion constraints.

Precondition

plant.is_finalized() == true.

Exceptions

std::exception	if plant has constraints registered that are not yet supported by this method.
std::exception	if prog is nullptr.
std::exception	if plant_context is nullptr and one of the MultibodyPlant constraints requires it. (unit quaternion constraints and coupler constraints do not).

AddUnitQuaternionConstraintOnPlant()

std::vector<solvers::Binding<solvers::Constraint> > drake::multibody::AddUnitQuaternionConstraintOnPlant	(	const MultibodyPlant< T > &	plant,
		const Eigen::Ref< const VectorX< symbolic::Variable >> &	q_vars,
		solvers::MathematicalProgram *	prog
	)

Add unit length constraints to all the variables representing quaternion in q_vars.

Namely the quaternions for floating base joints in plant will be enforced to have a unit length.

Additionally, if the initial guess for the quaternion variables has not been set (it is nan), then this method calls MathematicalProgram::SetInitialGuess() with [1, 0, 0, 0], to help the solver avoid singularities.

Parameters

plant	The plant on which we impose the unit quaternion constraints.
q_vars	The decision variables for the generalized position of the plant.
prog	The unit quaternion constraints are added to this prog.

Template Parameters

T	The scalar type, which must be one of the default scalars.

ApplyMultibodyPlantConfig()

void drake::multibody::ApplyMultibodyPlantConfig	(	const MultibodyPlantConfig &	config,
		MultibodyPlant< double > *	plant
	)

Applies settings given in config to an existing plant.

The time_step is the one value in config that cannot be updated – it can only be set in the MultibodyPlant constructor. Consider using AddMultibodyPlant() or manually passing config.time_step when you construct the MultibodyPlant.

This method must be called pre-Finalize.

Exceptions

std::exception

if plant is finalized or if time_step is changed.

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.

CalcDistanceAndTimeDerivative()

SignedDistanceWithTimeDerivative drake::multibody::CalcDistanceAndTimeDerivative	(	const multibody::MultibodyPlant< double > &	plant,
		const SortedPair< geometry::GeometryId > &	geometry_pair,
		const systems::Context< double > &	context
	)

Given a pair of geometries and the generalized position/velocity of the plant, compute the signed distance between the pair of geometries and the time derivative of the signed distance.

This function is similar to QueryObject::ComputeSignedDistancePairClosestPoints(), but it also provides the time derivative of the signed distance.

Parameters

	plant	The plant on which the geometries are attached. This plant must have been connected to a SceneGraph.
	geometry_pair	The pair of geometries whose distance and time derivative are computed.
	context	The context of the plant. This must store both q and v. This context must have been extracted from the diagram context which contains both MultibodyPlant and SceneGraph contexts.
[out]	distance	The signed distance between the pair of geometry.
[out]	distance_time_derivative	The time derivative of the signed distance.

CalcSpatialInertia() [1/2]

SpatialInertia<double> drake::multibody::CalcSpatialInertia	(	const geometry::Shape &	shape,
		double	density
	)

Computes the SpatialInertia of a body made up of a homogeneous material (of given density in kg/m³) uniformly distributed in the volume of the given shape.

The shape is defined in its canonical frame S and the body in frame B. The two frames are coincident and aligned (i.e., X_SB = I).

Most shapes are defined such that their center of mass is coincident with So (and, therefore, Bo). These are the shapes that have symmetry across So along each of the axes Sx, Sy, Sz (e.g., geometry::Box, geometry::Sphere, etc.) For meshes, it depends on how the mesh is defined. For more discussion on the nuances of geometry::Mesh and geometry::Convex calculations see below.

Return values

M_BBo_B

The spatial inertia of the hypothetical body implied by the given shape.

Exceptions

std::exception

if shape is an instance of geometry::HalfSpace or geometry::MeshcatCone.

CalcSpatialInertia() [2/2]

SpatialInertia<double> drake::multibody::CalcSpatialInertia	(	const geometry::TriangleSurfaceMesh< double > &	mesh,
		double	density
	)

Computes the SpatialInertia of a body made up of a homogeneous material (of given density in kg/m³) uniformly distributed in the volume of the given mesh.

The mesh is defined in its canonical frame M and the body in frame B. The two frames are coincident and aligned (i.e., X_MB = I).

For the resultant spatial inertia to be meaningful, the mesh must satisfy certain requirements:

• The mesh must fully enclose a volume (no cracks, no open manifolds, etc.).
• All triangles must be "wound" such that their normals point outward (according to the right-hand rule based on vertex winding).

Drake currently doesn't validate these requirements on the mesh. Instead, it does a best-faith effort to compute a spatial inertia. For some "bad" meshes, the SpatialInertia will be objectively physically invalid. For others, the SpatialInertia will appear physically valid, but be meaningless because it does not accurately represent the mesh.

Exceptions

std::exception

if the resulting spatial inertia is obviously physically invalid. See multibody::SpatialInertia::IsPhysicallyValid().

ComputePoseDiffInCommonFrame()

Vector6<double> drake::multibody::ComputePoseDiffInCommonFrame	(	const math::RigidTransform< double > &	X_C0,
		const math::RigidTransform< double > &	X_C1
	)

Computes the pose "difference" between X_C0 and X_C1 such that the linear part equals p_C1 - p_C0, and the angular part equals R_C1 * R_C0.inv(), where p and R stand for the position and rotation parts, and C is the common frame.

default_model_instance()

ModelInstanceIndex drake::multibody::default_model_instance

(

)

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

operator<<()

std::ostream& drake::multibody::operator<<	(	std::ostream &	os,
		const DifferentialInverseKinematicsStatus	value
	)

world_frame_index()

FrameIndex drake::multibody::world_frame_index

(

)

For every MultibodyPlant the world frame always has this unique index and it is always zero.

world_index()

BodyIndex drake::multibody::world_index

(

)

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