Mobile Robot Path Planning in the Presence of Obstacles and Lack of Information about the Environment

Mobile robot motion is a complex field of research intensively studied during the recent decades. In this article the authors consider the problem of path planning for a mobile robot with two degrees of freedom (ground vehicle) in a priori undetermined environment. The authors formulate the path planning problem and propose a computationally effective algorithm for solving the problem of movement path construction in a priori unknown environment. The proposed algorithm decomposes the path planning problem in two main phases: construction of a graph-based presentation of a free space and graph search. The authors propose a dual graph of a free space polygon triangulation as a means of a free space presentation. This approach allows us to minimize the graph size without an uncontrollable loss of accuracy of environment representation. This approach uses Dijkstra algorithm for the conduct path search on a free space graph, but it is possible to replace this algorithm by another one with account of the particular constraints. The proposed algorithm envisages a continuous collection of the environment information by a robot using its sensors. A brief review of the existing approaches to the problem is presented, as well as a theoretical comparison of these approaches with the proposed one in terms of the computational complexity theory. The proposed algorithm's computational efficiency is demonstrated via a computational experiment, where the proposed and reference algorithms operate on a set of synthetic environment models of different geometric size, but with a similar structure. An experiment proved the algorithm's supremacy in speed.

одновременная локализация и картирование, мобильный робот, поиск пути, построение маршрута, планирование траектории, simultaneous localization and mapping, mobile robot, path finding, trajectory planning, path planning

1. Чернухин Ю. В., Бутов П. А. Синтез тормозных квазиполей препятствий для бортовой системы автономного планирования траектории движения малогабаритных мобильных роботов // Инженерный вестник Дона. 2014. № 2. Т. 29. С. 66-76.

2. Михайлов Б. Б. Техническое зрение мобильных роботов // Техническое зрение в системах управления мобильными объектами. Тр. науч.-техн. конф.-семинара. М.: Книжный дом "Университет", 2011. С. 191-201.

3. Хрущ А. В. Управление мобильным роботом с бортовой системой объемного зрения // Техническое зрение в системах управления. Сб. тр. науч.-техн. конф. 2012. С. 62-67.

4. O'Rourke J. Computational Geometry in C. Cambridge University Press, 1998.

5. O'Rourke J. Art gallery theorems and algorithms. New York: Oxford university press, 1987.

6. Seidel R. A simple and fast incremental randomized algorithm for computing trapezoidal decompositions and for triangulating polygons // Computational Geometry: Theory and Applications. 1991. Vol. 1. N. 1. P. 51-64.

7. Бутов П. А. Разработка и исследование элементов систем управления, реализующих автономные режимы навигации для малогабаритных мобильных роботов: дис.. канд. техн. наук: 05.13.05. Таганрог, 2014.

8. Яковлев К. С., Сарафанов В. Ю., Храмоин И. В. Об одной проблеме, возникающей при планировании траектории на плоскости // Тринадцатая национальная конф. по искусственному интеллекту с междунар. участием КИИ-2012. Тр. конф. Т. 3. Белгород: Изд-во БГТУ, 2012. С. 256-267.

9. Likhachev M., Stentz A. R* Search // Proc. of the National Conference on Artificial Intelligence, 2008.

10. Левитин А. Алгоритмы: введение в разработку и анализ. М.: Вильямс, 2006.