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Inverse kinematics for a redundant robotic manipulator used for nuclear decommissioning

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Inverse kinematics for a redundant robotic manipulator used for nuclear decommissioning. / Besset, Pierre; Taylor, C. James.
10th UKACC International Control Conference. Loughborough, 2014.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

Harvard

Besset, P & Taylor, CJ 2014, Inverse kinematics for a redundant robotic manipulator used for nuclear decommissioning. in 10th UKACC International Control Conference. Loughborough.

APA

Besset, P., & Taylor, C. J. (2014). Inverse kinematics for a redundant robotic manipulator used for nuclear decommissioning. In 10th UKACC International Control Conference

Vancouver

Besset P, Taylor CJ. Inverse kinematics for a redundant robotic manipulator used for nuclear decommissioning. In 10th UKACC International Control Conference. Loughborough. 2014

Author

Besset, Pierre ; Taylor, C. James. / Inverse kinematics for a redundant robotic manipulator used for nuclear decommissioning. 10th UKACC International Control Conference. Loughborough, 2014.

Bibtex

@inproceedings{152a90ef026345d6b033976a56c24583,
title = "Inverse kinematics for a redundant robotic manipulator used for nuclear decommissioning",
abstract = "The article develops a generic framework for the control of a dual-manipulator mobile robotic system for nuclear decommissioning, with a particular focus on the inverse kinematics and trajectory planning. A six Degrees-Of-Freedom (DOF) kinematic model for each manipulator is described, including the rotation of the end-effector. On this basis, the forward kinematic equations are relatively straightforward to determine. However, the redundant nature of the manipulator and its particular geometry exclude the possibility of a closed-form analytic solution to the inverse kinematics. Hence, previous studies into advanced automatic control using the device have locked off selected control valves. For example, recent research into nonlinear, state-dependent control systems for the hydraulic actuators have been limited to just three DOF. By contrast, this new study considers all the joints of each manipulator, basing the resolution of the inverse kinematics on the iterative Jacobian transpose method. Preliminary experimental and simulation results highlight the potential utility of the system by performing standard tasks such as pick and place operations.",
keywords = "nuclear decommissioning, mobile robotics, inverse kinematics, hydraulic actuators, iterative Jacobian transpose, state-dependent control",
author = "Pierre Besset and Taylor, {C. James}",
year = "2014",
month = jul,
language = "English",
booktitle = "10th UKACC International Control Conference",

}

RIS

TY - GEN

T1 - Inverse kinematics for a redundant robotic manipulator used for nuclear decommissioning

AU - Besset, Pierre

AU - Taylor, C. James

PY - 2014/7

Y1 - 2014/7

N2 - The article develops a generic framework for the control of a dual-manipulator mobile robotic system for nuclear decommissioning, with a particular focus on the inverse kinematics and trajectory planning. A six Degrees-Of-Freedom (DOF) kinematic model for each manipulator is described, including the rotation of the end-effector. On this basis, the forward kinematic equations are relatively straightforward to determine. However, the redundant nature of the manipulator and its particular geometry exclude the possibility of a closed-form analytic solution to the inverse kinematics. Hence, previous studies into advanced automatic control using the device have locked off selected control valves. For example, recent research into nonlinear, state-dependent control systems for the hydraulic actuators have been limited to just three DOF. By contrast, this new study considers all the joints of each manipulator, basing the resolution of the inverse kinematics on the iterative Jacobian transpose method. Preliminary experimental and simulation results highlight the potential utility of the system by performing standard tasks such as pick and place operations.

AB - The article develops a generic framework for the control of a dual-manipulator mobile robotic system for nuclear decommissioning, with a particular focus on the inverse kinematics and trajectory planning. A six Degrees-Of-Freedom (DOF) kinematic model for each manipulator is described, including the rotation of the end-effector. On this basis, the forward kinematic equations are relatively straightforward to determine. However, the redundant nature of the manipulator and its particular geometry exclude the possibility of a closed-form analytic solution to the inverse kinematics. Hence, previous studies into advanced automatic control using the device have locked off selected control valves. For example, recent research into nonlinear, state-dependent control systems for the hydraulic actuators have been limited to just three DOF. By contrast, this new study considers all the joints of each manipulator, basing the resolution of the inverse kinematics on the iterative Jacobian transpose method. Preliminary experimental and simulation results highlight the potential utility of the system by performing standard tasks such as pick and place operations.

KW - nuclear decommissioning

KW - mobile robotics

KW - inverse kinematics

KW - hydraulic actuators

KW - iterative Jacobian transpose

KW - state-dependent control

M3 - Conference contribution/Paper

BT - 10th UKACC International Control Conference

CY - Loughborough

ER -