2017
DOI: 10.1109/tsmc.2016.2562506
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Neural Network Control of a Flexible Robotic Manipulator Using the Lumped Spring-Mass Model

Abstract: Adaptive neural networks (NNs) are employed for control design to suppress vibrations of a flexible robotic manipulator. To improve the accuracy in describing the elastic deflection of the flexible manipulator, the system is modeled via the lumped spring-mass approach. Full-state feedback control as well as output feedback control are proposed separately. Aiming at achieving the control objective, uniform ultimate boundedness of the closed-loop system is ensured. Numerical simulations for the lumped model of t… Show more

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Cited by 286 publications
(114 citation statements)
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“…In [92], the NN was applied for the estimation of the unknown model parameters of a marine surface vessel and in [93] the full-state constraint of an n-link robotic manipulator was achieved by using the NN control. The NN controller was also constructed for flexible robotic manipulators to deal with the vibration suppression based on a lumped spring-mass model [94] while in [95], two RBFNNs were constructed for flexible robot manipulators to compensate for the unknown dynamics and the dead-zone effect, respectively.…”
Section: Nn Based Robot Control With Input Nonlinearitiesmentioning
confidence: 99%
“…In [92], the NN was applied for the estimation of the unknown model parameters of a marine surface vessel and in [93] the full-state constraint of an n-link robotic manipulator was achieved by using the NN control. The NN controller was also constructed for flexible robotic manipulators to deal with the vibration suppression based on a lumped spring-mass model [94] while in [95], two RBFNNs were constructed for flexible robot manipulators to compensate for the unknown dynamics and the dead-zone effect, respectively.…”
Section: Nn Based Robot Control With Input Nonlinearitiesmentioning
confidence: 99%
“…The boundary control is proposed based on smooth hyperbolic tangent function to stabilize the string system and saturate the control input, and the disturbance observer is exploited to track the external disturbance. In subsequent work, to achieve the transient performance regulation of the control systems based on neural networks approaches as presented in , we will devote to investigating the control design based on truncation model approach.…”
Section: Control Designmentioning
confidence: 99%
“…In modern industry field, significant research efforts have been made for the modeling and control of flexible manipulators due to their higher precision, faster operation, and lower energy consumption compared with typical rigid-link robotic arms. [1][2][3][4][5][6] However, such flexible structures may oscillate in the presence of exoteric factors and the elastic deformation caused by the motion of flexible arms will reduce the control performance. As a result, various methods on system modeling and control design, such as the singular perturbation method, model predictive control scheme, and backstepping control method, have been developed for flexible manipulators.…”
Section: Introductionmentioning
confidence: 99%