Control Design of Robotic Manipulator Based on Quantum Neural Network

Hayder Mahdi Abdulridha; Zainab Abdullah Hassoun

doi:10.1115/1.4038492

Journal of Dynamic Systems, Measurement, and Control | Volume 140 | Issue 6 | research-article

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Research Papers

Control Design of Robotic Manipulator Based on Quantum Neural Network

Hayder Mahdi Abdulridha and Zainab Abdullah Hassoun

[+] Author and Article Information

Hayder Mahdi Abdulridha

Department of Electrical Engineering,
University of Babylon,
P.O. Box No. 4,
Babylon, Iraq
e-mail: drenghaider@uobabylon.edu.iq

Zainab Abdullah Hassoun

Department of Electrical Engineering,
University of Babylon,
P.O. Box No. 4,
Babylon, Iraq
e-mail: Zainabeng43@gmail.com

Contributed by the Dynamic Systems Division of ASME for publication in the JOURNAL OF DYNAMIC SYSTEMS, MEASUREMENT, AND CONTROL. Manuscript received November 2, 2016; final manuscript received November 12, 2017; published online December 19, 2017. Editor: Joseph Beaman.

J. Dyn. Sys., Meas., Control 140(6), 061002 (Dec 19, 2017) (11 pages) Paper No: DS-16-1530; doi: 10.1115/1.4038492 History: Received November 02, 2016; Revised November 12, 2017

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Abstract

Abstract | Introduction | The Mitsubishi RM-501 Robot System | Kinematics | References

In this study, a control system was designed to control the robot's movement (The Mitsubishi RM-501 robot manipulator) based on the quantum neural network (QNN). A proposed method was used to solve the inverse kinematics in order to determine the angles values for the arm's joints when it follows through any path. The suggested method is the QNN algorithm. The forward kinematics was derived according to Devavit–Hartenberg representation. The dynamics model for the arm was modeled based on Lagrange method. The dynamic model is considered to be a very important step in the world of robots. In this study, two methods were used to improve the system response. In the first method, the dynamic model was used with the traditional proportional–integral–derivative (PID) controller to find its parameters (Kp, Ki, Kd) by using Ziegler Nichols method. In the second method, the PID parameters were selected depending on QNN without the need to a mathematical model of the robot manipulator. The results show a better response to the system when replacing the traditional PID controller with the suggested controller.

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References

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Figures

Fig. 2

Coordinate frames of Mitsubishi RM-501 robotic arm

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Fig. 1

Mitsubishi RM-501 robot

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Fig. 3

Trajectory planning flowchart

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Fig. 4

The proposed controller

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Fig. 5

Position control of the robot

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Fig. 6

Flowchart of the position control of one joint

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Fig. 7

Main window of GUI program

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Fig. 8

Block diagram of the interface card

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Fig. 9

A photograph of the RM-501 manipulator system

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Fig. 17

Joint 1 response, with Kp = 5, Ki = 10, and Kd = 0.5

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Fig. 18

Joint 2 response, with Kp = 5.2, Ki = 8.4, and Kd = 0.3

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Fig. 19

Joint 3 response, with Kp = 5.4, Ki = 10.5, and Kd = 0.6

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Fig. 20

Joint 4 response, with Kp = 5.1, Ki = 10, and Kd = 0.5

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Fig. 10

Initial angles

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Fig. 11

The robot arm configuration

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Fig. 12

End-effector track

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Fig. 13

(a) The desired and estimated values for θ1, (b) the desired and estimated values for θ2, (c) the desired and estimated values for θ3, and (d) the desired and estimated values for θ4

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Fig. 15

Quantic polynomial trajectory

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Fig. 16

Closed-loop PID controller

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Fig. 21

Response of the base joint motor with PID and optimized PID controllers

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Fig. 22

Response of the shoulder joint motor with PID and optimized PID controllers

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Fig. 23

Response of the elbow joint motor with PID and optimized PID controllers

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Fig. 24

Response of the pitch joint motor with PID and optimized PID controllers

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Fig. 14

Cubic trajectory

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Abdulridha H, Hassoun Z. Control Design of Robotic Manipulator Based on Quantum Neural Network. ASME. J. Dyn. Sys., Meas., Control. 2017;140(6):061002-061002-11. doi:10.1115/1.4038492.

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Control Design of Robotic Manipulator Based on Quantum Neural Network

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