Instantaneous fuzzy modelling for obstacle avoidance

Instantaneous fuzzy modelling for obstacle avoidance

A wheeled mobile robot in its work space has to cope with moving or static obstacles. In order to achieve specific tasks it has to manage with its environment. Two extremes cases can be presented, in one hand when robot has a complete modelling of its workspace, and in an other hand, when there is n...

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Bibliographic Details
Published in:1995 IEEE International Conference on Systems, Man and Cybernetics. Intelligent Systems for the 21st Century Vol. 3; pp. 2546 - 2551 vol.3
Main Authors: Bourdon, G., Ruaux, P., Delaplace, S.
Format: Conference Proceeding
Language:English
Published: IEEE 1995
Subjects:
Environmental management
Europe
Fuzzy reasoning
Mobile robots
Motion control
Orbital robotics
Robot motion
Robustness
Space technology
Wheels
Online Access:Get full text
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Summary:A wheeled mobile robot in its work space has to cope with moving or static obstacles. In order to achieve specific tasks it has to manage with its environment. Two extremes cases can be presented, in one hand when robot has a complete modelling of its workspace, and in an other hand, when there is no a priori knowledge about the external world. First case can be solved with the definition of free paths in the global plan but only if the obstacles configurations are perfectly known. When asynchronous events occur, the system needs a local perception to correct the initial path. In second case robot motion is directly controlled by the local perception and according to the local plan modifications. Robot is so able to manage with statics or dynamics obstacles. Such algorithms are reflex loops. We propose an avoiding strategy based on reflex loop method. This approach is a qualitative one lying on fuzzy reasoning. We develop a method integrating obstacles space configuration and admissible displacements of the system. Obstacle avoidance results from a qualitative local model of the external world, through the estimation of a constraint weight of the current robot configuration in the local environment. We will describe all steps of our reasoning to lead to a robust avoiding strategy in front flexibility and local minima. Example in unknown environment will illustrate the efficiency of our approach.
ISBN:0780325591
9780780325593
DOI:10.1109/ICSMC.1995.538165