Universiti Teknologi Malaysia Institutional Repository

Hub angle control of flexible manipulator based on bacterial foraging optimization

Mohd. Salme, Muhammad Nazri and Hadi, Muhamad Sukri and Jamali, Annisa and Mohd. Yatim, Hanim and Ab. Talib, Mat Hussin and Mat Darus, Intan Zaurah (2022) Hub angle control of flexible manipulator based on bacterial foraging optimization. In: Enabling Industry 4.0 through Advances in Mechatronics Selected Articles from iM3F 2021, Malaysia. Lecture Notes in Electrical Engineering, 900 (NA). Springer Science and Business Media Deutschland GmbH, Singapore, pp. 181-192. ISBN 978-981192094-3

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Official URL: http://dx.doi.org/10.1007/978-981-19-2095-0_17

Abstract

Flexible manipulator offers industry with less material requirement, lighter in weight thus transportable, consuming less power, require smaller actuators, less control complexity while being able to operate in higher payload to weight. But, due to high flexibility of the flexible manipulator, excessive vibration can be found if the system is implemented. This study aims to simulate an accurate model system using system identification (SI) technique via Bacterial Foraging Optimization (BFO) for control of the hub angle of the flexible manipulator system in simulation environment. It is vital to model the system that represents actual characteristics of the flexible manipulator before precisely control the hub angle of the flexible manipulator’s movement. The experimental data obtained from the flexible manipulator system’s hub are utilised to construct a model of the system using an auto-regressive with exogenous (ARX) structure. Bacterial Foraging Optimization (BFO) is used to develop the modelling by SI technique to obtain the mathematical models. The generated model’s performance is assessed using three methods: minimum mean square error (MSE), correlation tests, and stability test in pole-zero diagram. The model of hub angle constructed using BFO has a minimum mean square error of 1.9694,10-5, a high degree of stability, and strong correlation tests. The model of hub angle constructed using BFO has a minimum mean square error of 1.9694,10-5, a high degree of stability, and strong correlation results. Following that, a PID controller is designed and heuristically tuned to provide accurate hub angle positioning with a short settling time using the BFO model. It is also worth noting that BFO’s model successfully regulated the hub angle’s positioning with a 0.8% overshoot and a 0.5242 s settling time in the presence of single disturbances.

Item Type:Book Section
Uncontrolled Keywords:bacterial foraging optimization, flexible manipulator, swarm intelligence algorithm, system identification
Subjects:T Technology > TJ Mechanical engineering and machinery
Divisions:Mechanical Engineering
ID Code:100656
Deposited By: Yanti Mohd Shah
Deposited On:30 Apr 2023 08:26
Last Modified:30 Apr 2023 08:26

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