The problem of the optimal control of multiple-robot systems in the presence of obstacles is solved. All the robots are subject to state and control constraints. The method is based on nonlinear programming and decomposition coordination. The problem is solved by satisfying the constraints on the states and the controls as well as those on the obstacles. To generalize the problem, N/sub R/ robots with N/sub O/ obstacles are considered. No distinction is made between the different types of robots, allowing the generalization of this problem to the case of mobile robots with a known work space. In order to generate an optimal control that accounts for the presence of obstacles, all robot segments and obstacles are considered as convex and compact sets in R/sup 3/. An additional property is used to obtain a distance function C/sup 1/. The proposed method is programmed on a VAX station and is used as a CACSD tool for the path planning of two modular assembly robots.
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机译:解决了存在障碍物时多机器人系统的最优控制问题。所有机器人都受状态和控制约束。该方法基于非线性规划和分解协调。通过满足对状态和控制以及对障碍物的约束来解决该问题。为了概括该问题,考虑使用具有N / sub O /个障碍物的N / sub R /个机器人。在不同类型的机器人之间没有区别,允许将此问题推广到具有已知工作空间的移动机器人。为了生成考虑到障碍物存在的最佳控制,所有机器人节段和障碍物均被视为R / sup 3 /中的凸集和紧集。附加属性用于获得距离函数C / sup 1 /。所提出的方法在VAX工作站上进行了编程,并用作CACSD工具来规划两个模块化组装机器人的路径。
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