Abstract
Autonomous vehicles for agricultural applications should be able to perform complex tasks, which require planning and optimization before execution, as well as context-dependent reactive behaviour during execution in the field. Hybrid control architectures are well suited to such applications. In this paper, a formal task-modelling framework is proposed and implemented, based on such a hybrid architecture. Each task is modelled as a sequence of transitions among operational modes, and each mode is defined as an instance of a set of elementary object-behaviours, which execute concurrently. A case-study “navigation” task was implemented, where deterministic path following and reactive obstacle avoidance behaviours were combined. The robot’s operation was successfully tested in an open field and “smooth” mode switching without chattering was observed in the presence of both static and dynamic obstacles. The virtual force field method based on a dynamic occupancy grid seems to be a very good candidate — in terms of smoothness of mode transitions — for implementing obstacle avoidance behaviour.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Blackmore, S., Have, H., Fountas, S. (2001). A specification of behavioural requirements for an autonomous tractor. 6th International Symposium on Fruit, Nut and Vegetable Production Engineering Conference, Potsdam — Bornim, Germany, pp. 25–36.
Blackmore, S., Fountas, S., Have, H. (2002). Proposed system architecture to enable behavioural control of an autonomous tractor. ASAE Conference on Automation Technology for Off-road Equipment, Chicago, USA, July 26–26, pp. 13–23
Borenstein, J. and Koren, Y. (1989). Real-time Obstacle Avoidance for Fast Mobile Robots. Real-time Obstacle Avoidance for Fast Mobile Robots. IEEE Transactions on Systems, Man, and Cybernetics,19(5), p.p. 1179–1187.
Brooks, R. (1986). A Layered Intelligent Control System for a Mobile Robot. IEEE Journal Robotics and Automation, RA-2, pp. 14–23
Egerstedt, M., Johansson, K., Lygeros, J., Sastry, S. (1999). Behavior Based Robotics Using Regularized Hybrid Automata. Proc. of CDC’99, Phoenix, Arizona.
Garcia-Alegre, M.C., Guinea, G. (1997). Building an architecture for a farming robot. In: juste, F., Andreu, G., Valiente, J.M., Benlloch, J.V. (Eds.). Proceedings of the international Workshop on Robotics and Automated Machinery for Bio-Robotics, Gandia, Spain, pp. 255–260.
Jahns, G. (1997). Automatic Guidance of Agricultural Field machinery. Proceedings of the Joint International Conference on Agricultural Engineering & Technology exhibition, Dec. 15–18, Bangladesh, 70–79.
Khatib, O. (1985). Real-Time Obstacle Avoidance for Manipulators and Mobile Robots. IEEE International Conference on Robotics and Automation, pp. 500–505.
Kosecka, J. and Bajcsy, R. (1994). Discrete Event Systems for Autonomous Mobile Agents. Journal of Robotics and Autonomous Systems.
Lygeros, J., Tomlin, C., Sastry., S. (1999). Controllers for Reachability Specifications for Hybrid Systems. Automatica,35(3), March 1999.
Martin, M.C. and Moravec H.P. (1996). Robot Evidence Grids. Technical Report CMU-RI-TR-96-06, The Robotics Institute, Carnegie Mellon University.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Vougioukas, S., Fountas, S., Blackmore, S. et al. Combining reactive and deterministic behaviours for mobile agricultural robots. Oper Res Int J 5, 153–163 (2005). https://doi.org/10.1007/BF02944168
Issue Date:
DOI: https://doi.org/10.1007/BF02944168