A critical review of modelling methods for flexible and rigid link manipulators

Lee, Tian Soon; Alandoli, Esmail Ali

doi:10.1007/s40430-020-02602-0

Cited by 33 publications

(15 citation statements)

References 143 publications

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“…In many mechanical engineering applications in the feld of robotics, haptics, industrial machining, instrumentation, and the optical industry, vibration-sensitive equipment might be mounted on one or more fexible co-operative arms carried by the moving support [1][2][3][4][5]. Generally, ignoring mechanical phenomena, such as deformation and vibration, causes poor performance or even the controller instability, when using fexible components in mechanical systems such as robotic arms [6][7][8]. In order to control the vibrations of fexible systems, from the point of view of installation (mounting) techniques of sensors and actuators, the command control input can be applied into the system as a distributed input or as a concentrated (point) input.…”

Section: Introductionmentioning

confidence: 99%

“…On the other hand, in the approach of the concentrated command control input, sensors and actuators are usually installed at a limited number of points within the boundaries of the fexible system, and it is possible that stabilization and tracking control can be performed successfully by controlling the boundaries. Among the most important methods of mathematical modeling and control of fexible systems, modal methods, the method of assume modes, the linear or nonlinear fnite elements method, the method of lines, and variable separation methods, can be mentioned [7,8]. Another technique of mechanical systems' control with fexible arms is the boundary control method, in which the dynamic equations of the system that are in the form of PDE are used directly by methods such as functional analysis, operators' techniques, and the semigroup theory, and the diferential geometry calculus is included in the design of the control system [9,10].…”

Section: Introductionmentioning

confidence: 99%

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Nonlinear Tracking Control Algorithm for Dynamical Output Systems Manipulated by the Hardly Constrained Oscillatory Actuator

Homaeinezhad

Mostaghim

2023

Structural Control and Health Monitoring

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In this article, a nonlinear control algorithm has been presented, in order to reduce vibrational movements of a flexible beam cantilevered in a cart supported by nonlinear stiffness, actuated by a hardly constrained second-order dynamic system. In the presented control algorithm, the interactive model of the solid body and a flexible beam has been extracted and utilized to design an algorithm, based on which the nonlinear vibrations of the tip point of the beam whose function is smooth and nonoscillatory tracking of the predefined desired trajectory are diminished. To design a nonlinear vibration control system of the beam, it has been assumed that the feedback system includes three modules: a vibrational beam cantilevered on a base, a base affected by nonlinear stiffness and actuator’s control force, and a force imposing system with constraints of bandwidth frequency limitation and actuation saturation boundary. In order to design this control system, the generalized tracking error function has been defined to nonlinearly amplify the vibrationally induced error and its rate, which by properly adjusting them, a new quantity can be extracted that satisfies the control system design constraints. To design a tracking control system for a nonlinear vibrating beam for the aforementioned three-modulus system, first, the generalized tracking error for the three modules is separately defined and parametrized, and then, by simultaneously adjusting all the defined parameters systematically, the predominant system presence in Lyapunov stability conditions is guaranteed. To illustrate the multimodule imitative (MMI) controller design algorithm, a moving support connected to a nonlinear spring and damper is considered, which carries a flexible cantilevered beam. The applied actuation system has second-order linear dynamics with the presence of command control saturation boundaries. For each of the abovementioned modules, a generalized tracking error is defined, and then, it is explained to how simultaneously adjust the parameters based on the stability and actuation constraints. The MMI controller is applied to the mentioned mechanical system modeled in the ANSYS® Mechanical APDL environment, and then, the necessary conclusions are discussed about the performance of the control system in eliminating the vibrations of the flexible arm, considering the actuation constraints while possessing the dominant Lyapunov stability.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nonlinear Tracking Control Algorithm for Dynamical Output Systems Manipulated by the Hardly Constrained Oscillatory Actuator

Homaeinezhad

Mostaghim

2023

Structural Control and Health Monitoring

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“…In the second method, each PDE of the system is converted to a system of ODEs. In fact, the second method is a finite‐dimensional approximation of the real infinite‐dimensional system 16 . It can be performed using the methods of reduced order modeling (ROM) such as AMM, FEM and so forth.…”

Section: Introductionmentioning

confidence: 99%

Feedback control of actuation‐constrained moving structure carrying Timoshenko beam

Homaeinezhad

Gavari

2022

Intl J Robust & Nonlinear

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This article deals with tracking control and active vibration suppression of a hybrid rigid‐elastic vibrational mobile system with a nonlinear elastic foundation in the presence of actuator bandwidth limitation and control input saturation. The system consists of a rigid rectilinearly mobile frame on an elastic foundation, and a flexible Timoshenko beam clamped to it with a heavy attached concentrated mass. The hybrid partial differential equation (PDE)‐ordinary differential equation (ODE) system of the plant is obtained using Hamilton's principle and then is converted to a system of ODEs using the assumed mode method (AMM). Next, the model will be discretized in the time domain using the two‐step Adams‐Bashforth technique. Considering the first‐order dynamics to cover the bandwidth limitation of the actuator, a discrete‐time sliding mode controller (DSMC) is designed based on a positive definite Lyapunov functional. Following that, an innovative optimal predictive algorithm is proposed to compensate for the effects of input saturation. The proposed algorithm is based on a positive definite cost function and using an intelligent regime of optimizations and decisions, minimizes the cost function in a predefined prediction horizon. The vibratory behavior of the system also is included in the mentioned cost function. Consequently, the overall control scheme called optimal rigid‐elastic interaction control (OREIC) will be able to follow the desired tracking trajectory, suppress the beam vibrations, and compensate for the effect of bandwidth limitation as well as the effect of input saturation. The performance of the OREIC algorithm is compared with a saturated DSMC controller and the simulation results demonstrate the efficiency of the method in vibration control of mobile rigid‐elastic systems subjected to actuator bandwidth frequency and saturation limitations.

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“…Lou et al (2020) presented a general electricity-structure-fluid coupled model of a cantilever with partially distributed actuators by using the AMM. For a given flexible manipulator system, it is a difficult problem to select the appropriate modal eigen function (Lee and Alandoli, 2020). Therefore, the AMM is recommended for manipulators with uniform cross-sectional geometry and single-link flexible manipulators.…”

Section: Introductionmentioning

confidence: 99%

Vibration control of a translational coupled double flexible beam system using sliding mode neural network fuzzy control

Qiu

Chen

2022

Transactions of the Institute of Measurement and Control

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A sliding mode neural network fuzzy control (SMNNFC) method is investigated to suppress the vibration of a translational coupled double flexible beam system, equipped with an AC servomotor and several piezoelectric actuators. Adjacent beams and slider moving frame are connected at the tip by elastic springs. Based on the finite element method, the system model is established to recognize the vibration characteristics. Furthermore, two laser displacement sensors are used to decouple the first two bending modes of the double flexible beam system. In the applied SMNNFC strategy, a neural-fuzzy framework is designed to obtain robust control performance and alleviate the chattering phenomenon. Considering unknown and varying system uncertainty, a parameter updating algorithm is adopted. The stability of SMNNFC is analyzed. The experimental setup is constructed and experiments are conducted, including set-point vibration control and simultaneous translation and vibration control under trapezoidal and sinusoidal trajectories. The experimental results demonstrate that the SMNNFC scheme has advantages in suppressing both the large and low amplitude vibrations of the coupling double flexible beam system.

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A critical review of modelling methods for flexible and rigid link manipulators

Cited by 33 publications

References 143 publications

Nonlinear Tracking Control Algorithm for Dynamical Output Systems Manipulated by the Hardly Constrained Oscillatory Actuator

Nonlinear Tracking Control Algorithm for Dynamical Output Systems Manipulated by the Hardly Constrained Oscillatory Actuator

Feedback control of actuation‐constrained moving structure carrying Timoshenko beam

Vibration control of a translational coupled double flexible beam system using sliding mode neural network fuzzy control

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