INVERSE MATCHING-BASED MOBILE ROBOT FOLLOWING ALGORITHM USING FUZZY LOGIC

Harun Šiljak

References

1. [1] A. Korodi, A. Codrean, L. Banita, and C. Volonescu, Aspects regarding the object following control procedure for wheeled mobile robots, WSEAS Transactions on Systems and Control, 3, 2008, 537–546.
2. [2] L. Freda and G. Oriolo, Vision-based interception of a moving target with a nonholonomic mobile robot, Robotics and Autonomous Systems, 55, 2007, 419–432.
3. [3] I. Ullah, F. Ullah, and Q. Ullah, Real-time object following fuzzy controller for a mobile robot, ICCNIT Proceedings, 2011, 241–244.
4. [4] C. Santos, et al., Fuzzy Decentralized Control for guidance of a convoy of robots in nonlinear trajectories, Proc. IEEE Conf. on ETFA 2010, 1–8.
5. [5] J. Minguez, F. Lamiraux, and L. Montesano, Metric-based scan matching algorithms for mobile robot displacement estimation, Proc. IEEE International ICRA Conf., 2005, 3557–3563.
6. [6] P. Chakravarty, A.M. Zhang, R. Jarvis, and L. Kleeman, Anomaly detection and tracking for a patrolling robot, Proc. of ACRA, 2007.
7. [7] M.F. Miskon and R.A. Russell, Mapping normal sensor measurement using regions, Proc. of IEEE ICIT, 2009.
8. [8] J. Velagic, N. Osmic, F. Hodzic, and H. Siljak, Outdoor navigation of a mobile robot using GPS and GPRS communication system, ELMAR Proc., 2011, 173–177.
9. [9] H. Šiljak and J. Velagié, A novel algorithm for following of moving target in outdoor mobile robot environment based on inverse matching, 20th Mediterranean Conf. on Control and Automation (MED), 2012, 548–554.
10. [10] B.P. Gerkey, R.T. Vaughan, and A. Howard, The Player/Stage Project: Tools for multi-robot and distributed sensor systems, ICAR Conf. Proc., 2003, 317–323.
11. [11] K. Morioka, J-H. Lee, and H. Hashimoto, Human-following mobile robot in a distributed intelligent sensor network, IEEE Transactions on Industrial Electronics, 51(1), 2004, 229–237.
12. [12] S. Marsland, U. Nehmzow, and J. Shapiro, On-line novelty detection for autonomous mobile robots, Robotics and Autonomous Systems, 51, 2005, 191–206.
13. [13] P. Nunez, et al., Novelty detection and 3D shape retrieval based on Gaussian Mixture Models for autonomous surveillance robotics, The 2009 IEEE/RSJ Conf. on Intelligent Robots and Systems, St. Louis, MO, 2009.
14. [14] H. Andreasson, M. Magnusson, and A. Lillienthal, Has something changed here? Autonomous difference detection for security patrol robots, The 2007 IEEE/RSJ Conf. on Intelligent Robots and Systems, St. Louis, MO, 2007.
15. [15] T-H.S. Li, S.-J. Chang, and W. Tong, Fuzzy target tracking control of autonomous mobile robots by using infrared sensors, IEEE Transactions on Fuzzy Systems, 12(4), 2004, 491–501.
16. [16] A. Melendez, O. Castillo, and P. Melin, Evolutionary optimization of the fuzzy controllers in a navigation system for a mobile robot, International Journal of Innovating Computing, Information and Control, 9(2), 2013, 451–464.
17. [17] L. Astudillo, P. Melin, and O. Castillo, Chemical optimization paradigm applied to a fuzzy tracking controller for an autonomous mobile robot, International Journal of Innovating Computing, Information and Control, 9(5), 2013, 2007–2018.
18. [18] W. Khaksar, T.-S. Hong, M. Khaksar, and O.R.E. Motlagh, A genetic-based optimized fuzzy-Tabu controller for mobile robot randomized navigation in unknown environment, International Journal of Innovating Computing, Information and Control, 9(5), 2013, 2185–2202.

Important Links:

• Abstract
• DOI: 10.2316/Journal.206.2014.4.206-4036
• From Journal (206) International Journal of Robotics and Automation - 2014

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