Neural-Networks-Based Inverse Kinematics for a Robotic Manipulator
Fouz, M., Bayoumy, A., Rezeka, S. (2013). Neural-Networks-Based Inverse Kinematics for a Robotic Manipulator. EKB Journal Management System, 15(AEROSPACE SCIENCES & AVIATION TECHNOLOGY, ASAT - 15 – May 28 - 30, 2013), 1-18. doi: 10.21608/asat.2013.22084
M. A. Fouz; A. M. Bayoumy; Sohair F. Rezeka. "Neural-Networks-Based Inverse Kinematics for a Robotic Manipulator". EKB Journal Management System, 15, AEROSPACE SCIENCES & AVIATION TECHNOLOGY, ASAT - 15 – May 28 - 30, 2013, 2013, 1-18. doi: 10.21608/asat.2013.22084
Fouz, M., Bayoumy, A., Rezeka, S. (2013). 'Neural-Networks-Based Inverse Kinematics for a Robotic Manipulator', EKB Journal Management System, 15(AEROSPACE SCIENCES & AVIATION TECHNOLOGY, ASAT - 15 – May 28 - 30, 2013), pp. 1-18. doi: 10.21608/asat.2013.22084
Fouz, M., Bayoumy, A., Rezeka, S. Neural-Networks-Based Inverse Kinematics for a Robotic Manipulator. EKB Journal Management System, 2013; 15(AEROSPACE SCIENCES & AVIATION TECHNOLOGY, ASAT - 15 – May 28 - 30, 2013): 1-18. doi: 10.21608/asat.2013.22084

Neural-Networks-Based Inverse Kinematics for a Robotic Manipulator

International Conference on Aerospace Sciences and Aviation Technology
Article 31, Volume 15, AEROSPACE SCIENCES & AVIATION TECHNOLOGY, ASAT - 15 – May 28 - 30, 2013, May 2013, Page 1-18  XML PDF (671.27 K)
Document Type: Original Article
DOI: 10.21608/asat.2013.22084
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Authors
M. A. Fouz1; A. M. Bayoumy2; Sohair F. Rezeka3
1GTA in AASTMT, Cairo, Egypt, (B.Sc.).
2Egyptian Armed Forces, Egypt.
3Professor in Alexandria University, Alexandria, Egypt (currently on leave at AASTMT).
Abstract
The solution of inverse kinematics problem of robotic manipulator is a fundamental problem in robot control. This paper involves the study of forward and inverse kinematics of a robotic manipulator platform with revolute joints. The (Denavit-Hartenberg) kinematic model of the prescribed manipulator is presented to robot links and joints. In addition inverse kinematics solution has been provided using geometric approach. This solution is used to develop a dataset used to train three artificial feed forward neural networks (ANN). Each network is used to calculate one joint variable using position and orientation of the end effector as an input. Experimental results have shown a good mapping over the working area of the robot with smaller RMS error than that reported in the cited literature.
Keywords
Robotics; Denavit-Hartenberg; Inverse kinematics; artificial neural network
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