Self-Organizing Decision-Making System for AUV

2007 Symposium on Underwater Technology and Workshop on Scientific Use of Submarine Cables and Related Technologies Pub Date : 2007-04-17 DOI:10.1109/UT.2007.370774

S. Nishida, K. Ishii, T. Furukawa

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引用次数: 7

Abstract

Autonomous underwater vehicles (AUVs) have great advantages for activities in deep oceans, and are expected as the attractive tool for near future underwater development or investigation. However, AUVs have various problems which should be solved for motion control, acquisition of sensors' information, behavioral decision, navigation without collision, self-localization and so on. In order to realize the useful and practical robots which can work in the ocean, underwater vehicles should take their action by judging the changing condition from their own sensors and actuators, and are desirable to make their behaviors with limited efforts of the operators, because of the features caused by the working environment. Therefore, the AUVs should be autonomous and have adaptive function to their environment. AUVs have non-liner coupled dynamics in six degrees of freedom, and the changes of the equipments of robots have influence on the control system. In this paper, a new control system for AUVs using modular network SOM (mnSOM) proposed by Tokunaga et al. is described. The mnSOM is an extension of the conventional SOM in which each vector unit is replaced by function modules such as NN and SOM, and has both characteristic of NN (supervised learning, non-linear mapping, etc.) and SOM (interpolation, topology preservation, etc.). The proposed system has two maps (forward model map and controller map) using recurrent type NN mnSOM. A forward model map (FMM) expresses the relationship between control force and states variables, and is used to estimate a current dynamics of an AUV. A controller map (CM) expresses suitable controllers corresponding to the FMM. The efficiency of the system is investigated through the simulations and experiments.

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AUV自组织决策系统

自主水下航行器(auv)在深海活动中具有巨大的优势，有望在不久的将来成为水下开发或研究的重要工具。然而，auv在运动控制、传感器信息获取、行为决策、无碰撞导航、自定位等方面存在诸多问题需要解决。为了实现能够在海洋中工作的实用机器人，由于工作环境的特点，水下航行器应该通过自身的传感器和执行器来判断变化的条件来采取行动，并且希望在操作者有限的努力下做出行动。因此，auv必须具有自主性和对环境的自适应功能。水下机器人具有六自由度非线性耦合动力学特性，机器人装备的变化会对控制系统产生影响。本文介绍了Tokunaga等人提出的一种基于模块化网络SOM (mnSOM)的新型auv控制系统。mnSOM是传统SOM的扩展，其中每个向量单元都被NN和SOM等功能模块取代，并且具有NN(监督学习，非线性映射等)和SOM(插值，拓扑保存等)的特性。该系统采用循环型NN mnSOM，有两个映射(前向模型映射和控制器映射)。正演模型映射(FMM)表达了控制力与状态变量之间的关系，并用于估计AUV的当前动态。控制器映射(CM)表示与FMM相对应的合适控制器。通过仿真和实验验证了该系统的有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2007 Symposium on Underwater Technology and Workshop on Scientific Use of Submarine Cables and Related Technologies

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