FUZZY LOGIC-BASED ROBOT NAVIGATION IN STATIC ENVIRONMENT WITH DEAD CYCLE OBSTACLES

Mohsen Shayestegan, Mohammad H. Marhaban, Suhaidi Shafie, and Abdul Sattar b. Din

References

1. [1] L. Kleeman, Optimal estimation of position and heading for mobile robots using ultrasonic beacons and dead reckoning, Proc. IEEE Conf. on Robotics and Automation, 1992, 2582–2587.
2. [2] S. Haihang, G. Muhe, and H. Kezhong, An integrated GPS/CEPS position estimation system for outdoor mobile robot, Proc. IEEE Int. Conf. on Intelligent Processing Systems, Beijing, China, 1997, 28–31.
3. [3] S.Y. Yi, Global ultrasonic system with selective activation for autonomous navigation of an indoor mobile robot, Robotica, 26, 2008, 277–283.
4. [4] S. Garrido, L. Moreno, D. Blanco, and M.L. Munoz, Sensor-based global planning for mobile robot navigation, Robotica, 25, 2007, 189–199.
5. [5] Y. Zhuang, Y. Sun, and W. Wang, Mobile robot hybrid path planning in an obstacle-cluttered environment based on steering control and improved distance propagating, International Journal of Innovative Computing, Information and Control, 8, 2012, 4095–4109.
6. [6] M. Wang and J.N.K. Liu, Fuzzy logic based robot path planning in unknown environments, Proc. 2005 Int. Conf. on Machine Learning, and Cybernet, 2005, 813–818.
7. [7] M. Wang and J.N.K. Liu, Fuzzy logic-based real-time robot navigation in unknown environment with dead ends, Robotics and Autonomous systems, 56, 2008, 625–643.
8. [8] A. Zhu and S.X. Yang, A fuzzy logic approach to reactive navigation of behavior-based mobile robots, Proc. 2004 IEEE Int. Conf. on Robotics and Automation, 2004, 5045–5050.
9. [9] H. Noborio, R. Nogami, and S. Hirao, A new sensor-based path-planning algorithm whose path length is shorter on the average, IEEE International Conference on Robotics and Automation, New Orleans, LA, 2004, 2832–2839.
10. [10] R. Nogami, S. Hirao, and H. Noborio, On the average path lengths of typical sensor-based path-planning algorithms by uncertain random mazes, IEEE International Symposium on Computational Intelligence in Robotics and Automation, Kobe, Japan, 2003, 471–478.
11. [11] A. Sankaranarayanan and M. Vidyasagar, A new path planning algorithm for moving a point object amidst unknown obstacles in a plane, IEEE International Conference on Robotics and Automation, Cincinnati, OH, 1990, 1930–1936.
12. [12] T. Yoshioka and H. Noborio, On a proof of the deadlock-free property in an online path-planning by using world topology, lEEE International Conference on Intelligent Robots and Systems, Advanced Robotic Systems and the Real World, IROS’94, Munich, Germany, 1994, 1946–1953.
13. [13] M.B. Montaner and A.R. Serrano, Fuzzy knowledge-based controller design for autonomous robot navigation, Expert Systems with Applications, 14, 1998, 179–186.
14. [14] P.S. Lee and L.L. Wang, Collision avoidance by fuzzy logic control for automated guided vehicle navigation, Journal of Robotic Systems, 11, 1994, 743–760.
15. [15] T. Balch and R. Arkin, Avoiding the past: a simple but effective strategy for reactive navigation, IEEE Conference on Robotics and Automation, 1993, 678–685.
16. [16] M. Khatib, Real-time obstacle avoidance for manipulators and mobile robots, Real-time obstacle avoidance for manipulators and mobile robots, 5(1), 1986, 90–98.
17. [17] Y. Koren and J. Borenstein, Potential field methods and their inherent limitations for mobile robot navigation, Proc. IEEE Conf. on Robotics and Automation, 1991, 1398–1404.
18. [18] S.S. Ge and Y.J. Cui, New potential functions for mobile robot path planning, IEEE Transactions on Robotics and Automation, 16, 2000, 615–620.
19. [19] W.L. Xu and S.K. Tso, Sensor-based fuzzy reactive navigation for a mobile robot through local target switching, IEEE Transactions on Systems, Man, and Cybernetics, Part C, 29(3), 1999, 451–459.
20. [20] M.M. Yang and R.V. Patel, A layered goal-oriented fuzzy motion planning strategy for mobile robot navigation, IEEE Transactions on Systems, Man, and Cybernetics, Part B, 35(6), 2005, 1214–1224.
21. [21] M. Shayestegan and H.M. Marhaban, Mobile robot safe navigation in unknown environment, IEEE Int. Conf. on Control System, Computing and Engineering, Penang, Malaysia, 2012.
22. [22] M. Shayestegan and M.H. Marhaban, A braitenberg approach to mobile robot navigation in unknown environments, S.G. Ponnambalam et al. (Eds.), IRAM, CCIS 330, 2012, 75–93, Springer-Verlag, Berlin Heidelberg.
23. [23] A. Zhu and S.X. Yang, A fuzzy logic approach to reactive navigation of behavior-based mobile robots, IEEE International Conference on Robotics and Automation, 2004, 5045–5050.
24. [24] R.J. Wain, Ch.M. Liu, and You-Wei Lin, Design of switching path-planning control for obstacle avoidance of mobile robot, Journal of the Franklin Institute, 348, 2011, 718–737.
25. [25] W.L. Xu, S.K. Tso, and Y.H. Fung, Sensor-based reactive navigation of a mobile robot through local target switching, Proc. 8th Int. Conf. on Advanced Robotics, ICAR ’97, 1997, 361–366.
26. [26] K.M. Krishna and P.K. Kalra, Perception and remembrance of the environment during real-time navigation of a mobile robot, Robotics and Autonomous Systems, 37, 2001, 25–51.
27. [27] O.R.E. Motlagh, T.S. Hong, and N. Ismail, Development of a new minimum avoidance system for a behavior based mobile robot, Fuzzy Sets and Systems, 160, 2009, 1929–1946.
28. [28] G.-Ch. Luh and W.W. Liu, An immunological approach to mobile robot reactive navigation, Applied Soft Computing, 8, 2008, 30–45.
29. [29] J. Borenstein and Y. Koren, Real-time obstacle avoidance for fast mobile robots, IEEE Transactions on Systems, Man, and Cybernetics, 19, 1989, 1179–1187.
30. [30] Ch.F. Juang and Y.Ch. Chang, Evolutionary group based particle swarm optimized fuzzy controller with application to mobile robot navigation in unknown environments, IEEE Transactions on Fuzzy Systems, 19(2), 2011, 379–392.
31. [31] A. Saffiotti, The uses of fuzzy logic in autonomous robot navigation, International Journal on Soft Computing, 1, 1997, 180–197.
32. [32] I.I. Ismail and M.F. Nordin, Reactive navigation of autonomous guided vehicle using fuzzy logic, Student Conference on Research and Development, 2002, 153–156.
33. [33] H. Li and S.X. Yang, A behavior-based mobile robot with a visual landmark recognition system, IEEE Transactions on Mechatronics, 8, 2003, 390–400.
34. [34] C.H. Lin and L.L. Wang, Intelligent collision avoidance by fuzzy logic control, Robotics and Autonomous Systems, 20, 1997, 61–83.
35. [35] H. Maaref and C. Barret, Sensor-based navigation of a mobile robot in an indoor environment, Robot, Robotics and Autonomous systems, 38(1), 2002, 1–18.
36. [36] F.G. Pin and S.R. Bender, Adding memory processing behavior to the fuzzy behaviorist approach: resolving limit cycle problems in mobile robot navigation, Intelligent Automation and Soft Computing, 5(1), 1999, 31–41.
37. [37] M. Wang and J.N.K. Liu, Fuzzy logic based robot path planning in unknown environments, Proc. Int. Conf. on Machine Learning and Cybernetics, 2005, 813–818.
38. [38] H.P. Huang and P.C. Lee, A real-time algorithm for obstacle avoidance of autonomous mobile robots, Robotica, 10, 1992, 217–227.

Important Links:

• Abstract
• DOI: 10.2316/Journal.206.2013.4.206-3922
• From Journal (206) International Journal of Robotics and Automation - 2013

Go Back