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Spherical Joint

Joint allows 3-D rotations

  • Spherical Joint block

Libraries:
Simscape / Multibody / Joints

Description

The Spherical Joint block provides three degrees of freedom between two frames. The follower frame can have an arbitrary 3-D rotation with respect to the base frame. During a simulation, the origins of the base and follower frames remain coincident.

Joint Transformation Sequence of Spherical joint

Unlike a gimbal joint, the Spherical Joint does not have kinematic singularity because the rotation is encoded as a quaternion.

For information about how to specify joint blocks, see Modeling Joint Connections.

Ports

Frame

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Base frame of the joint block.

Follower frame of the joint block.

Input

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Physical signal input port that accepts the actuation torque for the spherical primitive. The signal has a scalar format that represents the torque about the x-axis of the resolution frame.

Dependencies

To enable this port, under Spherical Primitive (S) > Actuation, set Torque to Provided by Input and select Torque (X).

Physical signal input port that accepts the actuation torque for the spherical primitive. The signal has a scalar format that represents the torque about the y-axis of the resolution frame.

Dependencies

To enable this port, under Spherical Primitive (S) > Actuation, set Torque to Provided by Input and select Torque (Y)..

Physical signal input port that accepts the actuation torque for the spherical primitive. The signal has a scalar format that represents the torque about the z-axis of the resolution frame.

Dependencies

To enable this port, under Spherical Primitive (S) > Actuation, set Torque to Provided by Input and select Torque (Z)..

Physical signal input port that accepts the actuation torque for the spherical primitive. The vector represents the actuation torque to apply between the base and follower frame as expressed in resolution frame.

Dependencies

To enable this port, under Spherical Primitive (S) > Actuation, set Motion to Provided by Input and select Torque (XYZ)..

Mode Configuration

Input port that controls the mode of the joint. The signal is a unitless scalar. The joint operates in normal mode when the input signal is 0 and operates in disengaged mode when the input signal is -1. You can change between the two modes at any time during simulation.

Dependencies

To enable this port, under Mode Configuration, set Mode to Provided by Input.

Output

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Sensing

Orientation of the follower frame with respect to the base frame, returned as a unit quaternion. See Quaternion Measurements for more information.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Position.

X-coordinate of the relative angular velocity, returned as a scalar. The value is resolved in the resolution frame.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Velocity (X).

Y-coordinate of the relative angular velocity, returned as a scalar. The value is resolved in the resolution frame.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Velocity (Y).

Z-coordinate of the relative angular velocity, returned as a scalar. The value is resolved in the resolution frame.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Velocity (Z).

Relative angular velocity, returned as a 3-D vector resolved in the resolution frame.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Velocity.

X-coordinate of the relative angular acceleration, returned as a scalar. This quantity equals the time derivative of the signal exported from the port wx.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Acceleration (X).

Y-coordinate of the relative angular acceleration, returned as a scalar. This quantity equals the time derivative of the signal exported from the port wy.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Acceleration (Y).

Z-coordinate of the relative angular acceleration, returned as a scalar. This quantity equals the time derivative of the signal exported from the port wz.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Acceleration (Z).

Relative angular acceleration, returned as a 3-D vector resolved in the resolution frame. This quantity equals the time derivative of the signal exported from the port w.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Acceleration.

Physical signal port that outputs the magnitude of the lower-limit torque. The block applies the lower-limit torque when the angle between the z-axes of the two frames is less than the bound of the lower limit. The torque applies to both the base and follower frames of the spherical primitive to accelerate the relative position back to the free region.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Signed Lower-Limit Torque Magnitude.

Physical signal port that outputs the magnitude of the upper-limit torque. The block applies the upper-limit torque when the angle between the z-axes of the two frames exceeds the upper bound. The torque applies to both the base and follower frames of the spherical primitive to accelerate the relative position back to the free region.

Dependencies

To enable this port, under Spherical Primitive (S) > Sensing, select Upper-Limit Torque.

Composite Force/Torque Sensing

Physical signal port that outputs the constraint forces that act across the joint. The force maintains the translational constraints of the joint. For more information, see Measure Joint Constraint Forces.

Dependencies

To enable this port, under Composite Force/Torque Sensing, select Constraint Force.

Physical signal port that outputs the constraint torques that act across the joint. The torque maintains the rotational constraints of the joint. For more information, see Force and Torque Sensing.

Dependencies

To enable this port, under Composite Force/Torque Sensing, select Constraint Torque.

Physical signal port that outputs the total force that acts across the joint. The total force is the sum of the forces transmitted from one frame to the other through the joint. The force includes the actuation, internal, limit, and constraint forces. See Force and Torque Sensing for more information.

Dependencies

To enable this port, under Composite Force/Torque Sensing, select Total Force.

Physical signal port that outputs the total torque that acts across the joint. The total torque is the sum of the torques transmitted from one frame to the other through the joint. The torque includes the actuation, internal, limit, and constraint torques. For more information, see Force and Torque Sensing.

Dependencies

To enable this port, under Composite Force/Torque Sensing, select Total Torque.

Parameters

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Spherical Primitive (S)

State Targets

Select this parameter to specify the target of the relative orientation between the base and follower frames.

Priority level of the relative orientation target, specified as High (desired) or Low (approximate). See Guiding Assembly for more information.

Dependencies

To enable this parameter, select Specify Position Target.

Method to use to specify the relative orientation target between the base and follower frames. When specifying the parameter to None, the follower and base frames have the same orientation at the beginning of the simulation.

Dependencies

To enable this parameter, select Specify Position Target.

Follower frame axis used to align with the base frame axis set by the Pair 1: Base parameter, specified as an orthogonal axis of the follower frame. The follower frame rotates with respect to the base frame to enable the alignment between the selected axes of the base and follower frames.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Aligned Axis.

Base frame axis to align with the follower frame specified by the Pair 1: Follower, specified as an orthogonal axis of the base frame.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Aligned Axis.

Base frame axis to align with the follower frame specified by the Pair 2: Follower, specified as an orthogonal axis of the follower frame. The follower frame rotates with respect to the base frame to enable the alignment between the selected axes of the base and follower frames.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Aligned Axis.

Base frame axis used to let the follower frame axis set in the Pair2: Follower parameter to align with, specified as an orthogonal axis of the base frame. The axis choices for Pair 2 depend on the Pair 1 axis selections.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Aligned Axis.

Axis of the relative rotation, specified as an orthogonal axis of the base frame.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Standard Axis.

Angle of the relative rotation, specified as a scalar. The angle indicates the rotation of the follower frame with respect to the base frame about the specified axis.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Standard Axis.

Axis of the relative rotation, specified as a 3-by-1 unit vector. The vector is dimensionless and indicates the rotational axis resolved in the base frame.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Arbitrary Axis.

Angle of the relative rotation, specified as a scalar. The angle indicates the rotation of the follower frame with respect to the base frame about the axis specified by the Axis parameter.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Arbitrary Axis.

Frame whose axes to rotate the follower frame about, specified as Follower Axes or Base Axes. If you set the parameter to Follower Axes, the follower frame rotates about its own axes, and the follower frame changes the orientation with each successive rotation. If you set the parameter to Base Axes, the follower frame rotates about the fixed base frame axes. See Rotational Measurements for more information.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Rotation Sequence.

Sequence of the rotation axis for three successive elementary rotations. See Rotation Sequence Measurements for more information.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Rotation Sequence.

Angles for the rotation sequence parameterization, specified as a 1-by-3 vector. See Rotation Sequence Measurements for more information.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Rotation Sequence.

Relative rotation, specified as a 3-by-3 matrix that maps vectors from the follower frame to the base frame. The matrix must be orthogonal and have determinant 1. See Rotational Measurements for more information.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Rotation Matrix.

Relative rotation, specified as a unit quaternion vector. See Rotational Measurements for more information about the quaternion.

Dependencies

To enable this parameter, under Specify Position Target > Value, set Method parameter to Quaternion.

Select this parameter to specify the angular velocity target for the spherical primitive.

Priority level of the angular velocity target, specified as High (desired) or Low (approximate). See Guiding Assembly for more information.

Dependencies

To enable this parameter, select Specify Velocity Target.

Angular velocity target for the spherical primitive, specified as a 1-by-3 vector resoved in resolution frame.

Dependencies

To enable this parameter, select Specify Velocity Target.

Frame used to resolve the specified angular velocity target, specified as one of these:

  • Base — The joint block resolves the angular velocity target in the coordinates of the base frame.

  • Follower — The joint block resolves the angular velocity target in the coordinates of the follower frame.

Internal Mechanics

Method to use to specify the equilibrium frame with respect to the base frame. The equilibrium frame is fixed during the simulation. If the z-axes of the follower and equilibrium frames are aligned, the spring torque of the spherical primitive is zero.

Set the Equilibrium Position > Method parameter to None to let the equilibrium and base frames be coincident.

Equilibrium frame axis used to align with the base frame axis set by the Pair 1: Base parameter, specified as an orthogonal axis of the equilibrium frame. The equilibrium frame rotates with respect to the base frame to enable the alignment between the selected axes of the base and equilibrium frames.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Aligned Axis.

Base frame axis to align with the equilibrium frame specified by the Pair 1: Follower, specified as an orthogonal axis of the base frame.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Aligned Axis.

Base frame axis to align with the equilibrium frame specified by the Pair 2: Follower, specified as an orthogonal axis of the equilibrium frame. The equilibrium frame rotates with respect to the base frame to enable the alignment between the selected axes of the base and equilibrium frames.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Aligned Axis.

Base frame axis used to let the equilibrium frame axis set in the Pair2: Follower parameter to align with, specified as an orthogonal axis of the base frame. The axis choices for Pair 2 depend on the Pair 1 axis selections.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Aligned Axis.

Axis of the relative rotation, specified as an orthogonal axis of the base frame.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Standard Axis.

Angle of the relative rotation, specified as a scalar. The angle indicates the rotation of the equilibrium frame with respect to the base frame about the specified axis.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Standard Axis.

Axis of the relative rotation, specified as a 3-by-1 unit vector. The vector is dimensionless and indicates the rotational axis resolved in the base frame.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Arbitrary Axis.

Angle of the relative rotation, specified as a scalar. The angle indicates the rotation of the equilibrium frame with respect to the base frame about the axis specified by the Axis parameter.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Arbitrary Axis.

Frame whose axes to rotate the equilibrium frame about, specified as Follower Axes or Base Axes. If you set the parameter to Follower Axes, the equilibrium frame rotates about its own axes, and the equilibrium frame changes the orientation with each successive rotation. If you set the parameter to Base Axes, the equilibrium frame rotates about the fixed base frame axes. See Rotational Measurements for more information.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Rotation Sequence.

Sequence of the rotation axis for three successive elementary rotations. See Rotation Sequence Measurements for more information.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Rotation Sequence.

Angles for elementary rotations, specified as a 1-by-3 vector. See Rotation Sequence Measurements for more information.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Rotation Sequence.

Relative rotation, specified as a 3-by-3 matrix. The matrix must be orthogonal and have determinant 1. See Rotational Measurements for more information.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Rotation Matrix.

Relative rotation, specified as a unit quaternion vector. See Rotational Measurements for more information about the quaternion.

Dependencies

To enable this parameter, under Equilibrium Position, set Method parameter to Quaternion.

Stiffness of the internal spring-damper force law for the spherical primitive, specified as a scalar with a unit of rotational stiffness.

The spring attempts to pull the follower frame so that the follower frame is aligned with the specified equilibrium fame.

Damping coefficient of the internal spring-damper force law for the spherical primitive, specified as a scalar with a unit of rotational damping coefficient.

Limits

Select this parameter to specify the lower limit of the spherical primitive. Joint limits use spring-dampers to resist travel past the bounds of the range.

Lower bound for the free region of the spherical primitive, specified as a scalar with a unit of angle.

Dependencies

To enable this parameter, select Specify Lower Limit.

Stiffness of the spring at lower bound, specified as a scalar with a unit of rotational stiffness.

Dependencies

To enable this parameter, select Specify Lower Limit.

Damping coefficient at lower bound, specified as a scalar with a unit of rotational damping coefficient.

Dependencies

To enable this parameter, select Specify Lower Limit.

Region to smooth the spring and damper torques, specified as a scalar with a unit of angle.

The block applies the full value of the lower-limit torque when the penetration reaches the width of the transition region. The smaller the region, the sharper the onset of torques and the smaller the time-step required of the solver. In the trade-off between simulation accuracy and simulation speed, reducing the transition region improves accuracy while expanding it improves speed.

Dependencies

To enable this parameter, select Specify Lower Limit.

Select this parameter to specify the upper limit of the spherical primitive. Joint limits use spring-dampers to resist travel past the bounds of the range.

Upper bound for the free region of the spherical primitive, specified as a scalar with a unit of angle.

Dependencies

To enable this parameter, select Specify Upper Limit.

Stiffness of the spring at upper bound, specified as a scalar with a unit of stiffness.

Dependencies

To enable this parameter, select Specify Upper Limit.

Damping coefficient at upper bound, specified as a scalar with a unit of damping coefficient.

Dependencies

To enable this parameter, select Specify Upper Limit.

Region to smooth the spring and damper torques, specified as a scalar with a unit of angle.

The block applies the full value of the upper-limit torque when the penetration reaches the width of the transition region. The smaller the region, the sharper the onset of torques and the smaller the time-step required of the solver. In the trade-off between simulation accuracy and simulation speed, reducing the transition region improves accuracy while expanding it improves speed.

Dependencies

To enable this parameter, select Specify Upper Limit.

Actuation

Option to provide the actuation torque for the spherical primitive, specified as one of these values.

Actuation Torque SettingDescription
NoneApply no actuation torque.
Provided by InputApply actuation torques based on physical signals. The signal specifies the torque acting on the follower frame with respect to the base frame. The signal provides the value of the torque applied equally and oppositely to the base and follower frames. Selecting this option exposes additional parameters that you can use to enable input ports See the Input section for details.

Frame used to resolve the input actuation torques, specified as Base or Follower.

Sensing

Frame used to resolve the sensing output signals, specified as Base or Follower. For more information about the output signals, see the Output section.

Mode Configuration

Joint mode for the simulation, specified as one of these values:

MethodDescription
NormalThe joint behaves normally throughout the simulation.
DisengagedThe joint is disengaged throughout the simulation.
Provided by InputThe port mode specifies whether the joint behaves normally or is disengaged.

Composite Force/Torque Sensing

Measurement direction, specified as one of these values:

  • Follower on Base — The block senses the force and torque that the follower frame exerts on the base frame.

  • Base on Follower — The block senses the force and torque that the base frame exerts on the follower frame.

This parameter only affects the output signals under the Composite Force/Torque Sensing section. Reversing the direction changes the sign of the measurements. For more information see Force and Torque Measurement Direction.

Frame used to resolve the measurements, specified as one of these values:

  • Base — The block resolves the measurements in the coordinates of the base frame.

  • Follower — The block resolves the measurements in the coordinates of the follower frame.

This parameter only affects the output signals under the Composite Force/Torque Sensing section.

Extended Capabilities

C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.

Version History

Introduced in R2012a