Authors: M. Samaka

Abstract:

This paper presents the development of a software application for Off-line robot task programming and simulation. Such application is designed to assist in robot task planning and to direct manipulator motion on sensor based programmed motion. The concept of the designed programming application is to use the power of the knowledge base for task accumulation. In support of the programming means, an interactive graphical simulation for manipulator kinematics was also developed and integrated into the application as the complimentary factor to the robot programming media. The simulation provides the designer with useful, inexpensive, off-line tools for retain and testing robotics work cells and automated assembly lines for various industrial applications.

Keywords: Robot programming, task-level programming, robot languages, robot simulation, robotics software.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1075555

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References:

[1] R. Willgoss, and J. Iqbal, "Neurofuzzy Learning of Mobile Robot Behaviors", Proceeding of the12th Australian Joint Conference on Artificial Intelligence, AI '99, Sydney, Australia, December 6-10, 1999, pp. 278-290.
[2] S. Lopes, and J. Connell, "Sentience in Robots: Applications and Challenges", IEEE Intelligent Systems, Computer Society, 5(16), 2001, pp. 66-84.
[3] T. Längle, T. Lüth, E. Stopp, and G. Herzog, "Natural Language Access to Intelligent Robots: Explaining Automatic Error Recovery", In: A. M. Ramsay (ed.), Artificial Intelligence: Methodology, Systems, Applications, Amsterdam, IOS Press, 1996, pp. 259-267.
[4] W. Suwannik, and P. Chongstitvatana, "Improving the robustness of evolved robot arm control programs with multiple configurations", Proceeding of the 2nd Asian Symposium on Industrial Automation and Robotics, Bangkok, Thailand, May 17-18, 2001, pp. 87-90.
[5] H. Cheng, and K. Gupta, "A Study of Robot Inverse Kinematics Based upon the Solution of Differential Equations", Journal of Robotic Systems, 8(2), 1991, pp. 159-175.
[6] J. Buhmann, W. Burgard, A. Cremers, D. Fox, T. Hofmann, E. Schneider, J. Strikos, and S. Thurn, "The Mobile Robot RHINO", AI Magazine, 1(16), 1995, pp. 31-38.
[7] EASY-ROB "3D Robot Simulation", CARAT robotic innovation, Germany. Available: http://www.easy-rob.de/product.html.
[8] ROBOT3D- "Robot Offline Programming & Simulation", Portugal, Available: http://clientes.netvisao.pt/fnavegan/example2.htm.
[9] J. Denavit, and R. Hartenberg, "A kinematics notation for lower pair mechanisms based on matrices", ASME Journal of Applied Mechanics, June, 1955, Volume 22, pp. 215-221.