On hybrid intelligence-based control approach with its application to flexible robot system

Abstract A major hindrance to dynamics and control of flexible robot manipulators is the deficiency of its inherent damping. Damping enhancement, therefore, should result in lower vibration amplitudes, shorter settling times, and improvement of system stability. Since the bulk of robot vibrations is attributed to joint compliance, it is a prudent strategy to design joints with sufficient inherent damping. In this article, a method is proposed to estimate critical damping at each joint and identify the joint that should be targeted for design with sufficient built-in damping. The target joint identification process requires that a n-joint robot system is divided into n-subsystems. Subsystem i includes the compliance of joint i and the inertia of the succeeding links, joint mechanisms, and payload. An equivalent single degree of freedom torsional model is devised and the natural frequency and critical damping is evaluated for each subsystem. The estimated critical damping at the joints are used to determine the elastodynamic response of the entire robot system from a model that includes joint compliance, shear deformation, rotary inertia, and geometric stiffness. The response revealed the following conclusion: The joint of the manipulator that would result in lower amplitudes of vibrations and shorter settling times when designed with sufficient built-in damping is the one that renders a subsystem whose natural frequency is the lowest of all subsystems comprising the robot.

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Evolutionary computing approaches to optimum design of fuzzy logic controller for a flexible robot system

Archives of Control Sciences ◽

10.2478/acsc-2013-0024 ◽

2013 ◽

Vol 23 (4) ◽

pp. 395-412 ◽

Cited By ~ 1

Author(s):

Bidyadhar Subudhi ◽

Subhakanta Ranasingh

Keyword(s):

Fuzzy Logic ◽

Fuzzy Logic Controller ◽

Position Control ◽

Fitness Function ◽

Flexible Manipulator ◽

Position Tracking ◽

Flexible Robot ◽

Robot System ◽

Single Link ◽

Tip Position

Abstract This paper presents the design of a Fuzzy Logic Controller (FLC) whose parameters are optimized by using Genetic Algorithm (GA) and Bacteria Foraging Optimization (BFO) for tip position control of a single link flexible manipulator. The proposed FLC is designed by minimizing the fitness function, which is defined as a function of tip position error, through GA and BFO optimization algorithms achieving perfect tip position tracking of the single link flexible manipulator. Then the tip position responses obtained by using both the above controllers are compared to suggest the best controller for the tip position tracking.

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Dynamics and Control of a Helicopter Carrying a Payload Using a Cable-Suspended Robot

Volume 7: 29th Mechanisms and Robotics Conference, Parts A and B ◽

10.1115/detc2005-85131 ◽

2005 ◽

Cited By ~ 1

Author(s):

So-Ryeok Oh ◽

Ji-Chul Ryu ◽

Sunil K. Agrawal

Keyword(s):

Control Method ◽

Dual System ◽

Robust Controller ◽

Robot System ◽

Control Approach ◽

Cable Robot ◽

Dynamics And Control ◽

Position And Orientation ◽

And Control ◽

Scale Control

This paper presents a study of the dynamics and control of a helicopter carrying a payload through a cable-suspended robot. The helicopter can perform gross motion, while the cable suspended robot underneath the helicopter can modulate a platform in position and orientation. Due to the under-actuated nature of the helicopter, the operation of this dual system consisting of the helicopter and the cable robot is challenging. We propose here a two time scale control method, which makes it possible to control the helicopter and the cable robot independently. In addition, this method provides an effective estimation on the bound of the motion of the helicopter. Therefore, even in the case where the helicopter motion is unknown, the cable robot can be stabilized by implementing a robust controller. Simulation results of the dual system show that the proposed control approach is effective for such a helicopter-robot system.

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Evolutionary computation approaches to tip position controller design for a two-link flexible manipulator

Archives of Control Sciences ◽

10.2478/v10170-010-0043-2 ◽

2011 ◽

Vol 21 (3) ◽

pp. 269-285 ◽

Cited By ~ 6

Author(s):

Bidyadhar Subudhi ◽

Subhakanta Ranasingh ◽

Ajaha Swain

Keyword(s):

Evolutionary Computation ◽

Controller Design ◽

Flexible Manipulator ◽

Pd Controller ◽

Flexible Robot ◽

Robot System ◽

Global Parameter ◽

Position Controller ◽

Robot Performance ◽

Tip Position

Evolutionary computation approaches to tip position controller design for a two-link flexible manipulator Controlling multi-link flexible robots is very difficult compared rigid ones due to inter-link coupling, nonlinear dynamics, distributed link flexure and under-actuation. Hence, while designing controllers for such systems the controllers should be equipped with optimal gain parameters. Evolutionary Computing (EC) approaches such as Genetic Algorithm (GA), Bacteria Foraging Optimization (BFO) are popular in achieving global parameter optimizations. In this paper we exploit these EC techniques in achieving optimal PD controller for controlling the tip position of a two-link flexible robot. Performance analysis of the EC tuned PD controllers applied to a two-link flexible robot system has been discussed with number of simulation results.

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Genetic algorithm tuning of Lyapunov-based controllers: an application to a single-link flexible robot system

IEEE Transactions on Industrial Electronics ◽

10.1109/41.538614 ◽

1996 ◽

Vol 43 (5) ◽

pp. 567-574 ◽

Cited By ~ 45

Author(s):

S.S. Ge ◽

T.H. Lee ◽

G. Zhu

Keyword(s):

Genetic Algorithm ◽

Flexible Robot ◽

Robot System ◽

Single Link

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Self-excited Vibration Control of the Flexible Planar Parallel 3-RRR Robot

Journal of Vibration and Control ◽

10.1177/1077546318778630 ◽

2018 ◽

Vol 25 (2) ◽

pp. 351-361

Author(s):

Zhi-cheng Qiu ◽

Jie Yang ◽

Xian-min Zhang

Keyword(s):

High Speed ◽

Parallel Robot ◽

The Self ◽

Flexible Robot ◽

Nonlinear Controller ◽

Control Approach ◽

Excited Vibration ◽

Improve Accuracy ◽

The Stability ◽

Fuzzy Control Algorithm

A self-excited vibration active control approach for a 3-RRR flexible planar parallel robot is developed to improve accuracy and stability. The 3-RRR parallel flexible robot experimental setup is constructed. From the motion experiments, it is demonstrated that the residual vibration can be converted to self-excited vibration at a high-speed motion, which will affect the stability and positioning precision of the platform. To suppress the self-excited vibration owing to flexibility, friction, backlash, coupling, and other nonlinear factors, a nonlinear controller and a fuzzy control algorithm are designed to attenuate the self-excited vibration. Experiments are conducted in different positions of the 3-RRR flexible parallel robot. The experimental results demonstrate that the investigated control methods can suppress the self-excited vibration effectively.

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