Abstract
Kinematic analysis of under-constrained cable-driven parallel robots (CDPR) has been a topic of interest because of the inherent coupling between the loop-closure and static equilibrium equations. The non-linearity of the problem is magnified with the addition of the coupling between the cable lengths and their tensions based on the elastic cable model. The paper proposes an unsupervised neural network algorithm to perform real-time forward geometrico-static analysis of such robots in a suspended configuration under the action of gravity. The formulation determines a non-linear function approximation to model the problem and proves to be efficient in solving consecutive and close waypoints in a path. The methodology is applied on a six-degree-of-freedom spatial under-constrained suspended CDPR. Specific comparison results in simulation and hardware to show the effectiveness of the proposed method in tracking a given path are illustrated. Finally, the degree of constraint satisfaction is presented against the results obtained from non-linear least-square optimization.
Issue Section:
Special Issue: Selected Papers from IDETC-CIE 2021
References
1.
Barnett
, E.
, and Gosselin
, C.
, 2015
, “Large-Scale 3d Printing With a Cable-Suspended Robot
,” Addit. Manuf.
, 7
, pp. 27
–44
.2.
Merlet
, J.-P.
, and Daney
, D.
, 2010
, “A Portable, Modular Parallel Wire Crane for Rescue Operations
,” 2010 IEEE International Conference on Robotics and Automation
, Anchorage, AL
, May 3–8
, pp. 2834
–2839
.3.
Su
, Y. X.
, Duan
, B. Y.
, Nan
, R. D.
, and Peng
, B.
, 2001
, “Development of a Large Parallel-Cable Manipulator for the Feed-Supporting System of a Next-Generation Large Radio Telescope
,” J. Rob. Syst.
, 18
(11
), pp. 633
–643
. 4.
Homma
, K.
, Fukuda
, O.
, Sugawara
, J.
, Nagata
, Y.
, and Usuba
, M.
, 2003
, “A Wire-Driven Leg Rehabilitation System: Development of a 4-DOF Experimental System
,” Proceedings 2003 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM 2003)
, Kobe, Japan
, July 20–24
, Vol. 2
, pp. 908
–913
.5.
Merlet
, J.-P.
, 2010
, “Marionet, a Family of Modular Wire-Driven Parallel Robots,” Advances in Robot Kinematics: Motion in Man and Machine
, Lenarcic
, J.
, and Stanisic
, M.
, eds., Springer Netherlands
, Dordrecht, The Netherlands
, pp. 53
–61
.6.
Garant
, X.
, Campeau-Lecours
, A.
, Cardou
, P.
, and Gosselin
, C.
, 2018
, “Improving the Forward Kinematics of Cable-Driven Parallel Robots Through Cable Angle Sensors,” Cable-Driven Parallel Robots
, Gosselin
, C.
, Cardou
, P.
, Bruckmann
, T.
, and Pott
, A.
, eds., Springer International Publishing
, Cham, Switzerland
, pp. 167
–179
.7.
Dallej
, T.
, Gouttefarde
, M.
, Andreff
, N.
, Hervé
, P.-E.
, and Martinet
, P.
, 2019
, “Modeling and Vision-Based Control of Large-Dimension Cable-Driven Parallel Robots Using a Multiple-Camera Setup
,” Mechatronics
, 61
, pp. 20
–36
. 8.
Chawla
, I.
, Pathak
, P.
, Notash
, L.
, Samantaray
, A.
, Li
, Q.
, and Sharma
, U.
, 2021
, “Effect of Selection Criterion on the Kineto-Static Solution of a Redundant Cable-Driven Parallel Robot Considering Cable Mass and Elasticity
,” Mech. Mach. Theory
, 156
, p. 104175
. 9.
Behzadipour
, S.
, and Khajepour
, A.
, 2005
, “A New Cable-Based Parallel Robot with Three Degrees of Freedom
,” Multibody Syst. Dyn.
, 13
(4
), pp. 371
–383
. 10.
Carricato
, M.
, and Merlet
, J.-P.
, 2013
, “Stability Analysis of Underconstrained Cable-Driven Parallel Robots
,” IEEE Trans. Rob.
, 29
(1
), pp. 288
–296
. 11.
Carricato
, M.
, 2013
, “Direct Geometrico-Static Problem of Underconstrained Cable-Driven Parallel Robots With Three Cables
,” ASME J. Mech. Rob.
, 5
(3
), p. 031008
. 12.
Berti
, A.
, Merlet
, J.-P.
, and Carricato
, M.
, 2016
, “Solving the Direct Geometrico-Static Problem of Underconstrained Cable-Driven Parallel Robots by Interval Analysis
,” Int. J. Rob. Res.
, 35
(6
), pp. 723
–739
. 13.
Merlet
, J. P.
, 2004
, “Solving the Forward Kinematics of a Gough-Type Parallel Manipulator With Interval Analysis
,” Int. J. Rob. Res.
, 23
(3
), pp. 221
–235
. 14.
Pott
, A.
, and Schmidt
, V.
, 2015
, “On the Forward Kinematics of Cable-Driven Parallel Robots
,” 2015 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)
, Hamburg, Germany
, Sept. 28–Oct. 3
, pp. 3182
–3187
.15.
Collard
, J.-F.
, and Cardou
, P.
, 2013
, “Computing the Lowest Equilibrium Pose of a Cable-Suspended Rigid Body
,” Optim. Eng.
, 14
(3
), pp. 457
–476
. 16.
Miermeister
, P.
, Kraus
, W.
, and Pott
, A.
, 2013
, Differential Kinematics for Calibration, System Investigation, and Force Based Forward Kinematics of Cable-Driven Parallel Robots
, Springer
, Berlin
, pp. 319
–333
.17.
Pott
, A.
, 2012
, “Influence of Pulley Kinematics on Cable-Driven Parallel Robots,” Latest Advances in Robot Kinematics
, J.
Lenarcic
, and M.
Husty
, eds., Springer Netherlands
, Dordrecht, The Netherlands
, pp. 197
–204
.18.
Santos
, J. C.
, and Gouttefarde
, M.
, 2021
, “A Real-Time Capable Forward Kinematics Algorithm for Cable-Driven Parallel Robots Considering Pulley Kinematics,” Advances in Robot Kinematics 2020
, Lenarčič
, J.
, and Siciliano
, B.
, eds., Springer International Publishing
, Dordrecht, The Netherlands
, pp. 199
–208
.19.
Tang
, H.
, and Notash
, L.
, 2021
, “Neural Network-Based Transfer Learning of Manipulator Inverse Displacement Analysis
,” ASME J. Mech. Rob.
, 13
(3
), p. 035004
. 20.
Notash
, L.
, 2020
, “Artificial Neural Network Prediction of Deflection Maps for Cable-Driven Robots
,” Proceedings of the ASME 2020 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference (IDETC-CIE2020), Vol. 10: 44th Mechanisms and Robotics Conference (MR)
, Online, Virtual.21.
Mishra
, U. A.
, Chawla
, I.
, and Pathak
, P. M.
, 2020
, “On Determining Shortest Path in Joint Space of a Cable-Driven Parallel Robot for Point-to-Point Motion
,” 2020 28th Mediterranean Conference on Control and Automation (MED)
, Saint-Raphaël, France
, Sept. 16–18
, pp. 984
–989
.22.
Mishra
, U. A.
, and Caro
, S.
, 2021
, “Forward Kinematics for Suspended Under-Actuated Cable-Driven Parallel Robots: A Neural Network Approach
,” The ASME 2021 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference IDETC/CIE 2021, 45th Mechanisms and Robotics Conference (MR)
, Online, Virtual.23.
Mishra
, U. A.
, and Caro
, S.
, 2021
, “Unsupervised Neural Network Based Forward Kinematics for Cable-Driven Parallel Robots With Elastic Cables,” Cable-Driven Parallel Robots
, Gouttefarde
, M.
, Bruckmann
, T.
, and Pott
, A.
, eds., Springer International Publishing
, Cham, Switzerland
, pp. 63
–76
.24.
Métillon
, M.
, Cardou
, P.
, Subrin
, K.
, Charron
, C.
, and Caro
, S.
, 2021
, “A Cable-Driven Parallel Robot With Full-Circle End-Effector Rotations
,” ASME J. Mech. Rob.
, 13
(3
), p. 031017
. 25.
Baklouti
, S.
, Courteille
, E.
, Caro
, S.
, and Dkhil
, M.
, 2017
, “Dynamic and Oscillatory Motions of Cable-Driven Parallel Robots Based on a Nonlinear Cable Tension Model
,” ASME J. Mech. Rob.
, 9
(6
), p. 061014
. 26.
Ruiz
, A. L. C.
, Caro
, S.
, Cardou
, P.
, and Guay
, F.
, 2015
, “Arachnis: Analysis of Robots Actuated by Cables With Handy and Neat Interface Software,” Cable-Driven Parallel Robots
, Pott
, A.
, and Bruckmann
, T.
, eds., Springer International Publishing
, Cham, Switzerland
, pp. 293
–305
.27.
Rasheed
, T.
, Long
, P.
, and Caro
, S.
, 2020
, “Wrench-Feasible Workspace of Mobile Cable-Driven Parallel Robots
,” ASME J. Mech. Rob.
, 12
(3
), p. 031009
. 28.
Etienne
, L.
, Cardou
, P.
, Métillon
, M.
, and Caro
, S.
, 2021
, “Design of a Planar Cable-Driven Parallel Crane Without Parasitic Tilt
,” The ASME 2021 International Design Engineering Technical Conferences & Computers and Information in Engineering Conference IDETC/CIE 2021, 45th Mechanisms and Robotics Conference (MR)
, virtual online
, pp. 1
–10
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