Neuromodulatory developmental learning of the mobile robots corresponding to the unexpected obstacles

IF 2.1 3区心理学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Cognitive Systems Research Pub Date : 2024-10-10 DOI:10.1016/j.cogsys.2024.101296

Hongyan Zhao , Dongshu Wang , Lei Liu

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引用次数: 0

Abstract

With the gradual expansion of robot applications, the operating environment is becoming more and more complex, and various uncertainty may be encountered. Investigating how to efficiently respond to various uncertainty in the environment has become an important challenge in the field of robotics research. For the autonomous obstacle avoidance of mobile robots in case of sudden appeared obstacles, a dynamic obstacle avoidance algorithm with a motivated developmental network that simulates the visual attention mechanism is proposed. Simulating the response mechanism of biological vision, a depth camera is used to achieve the detection and recognition of obstacles. To enhance the behavioral regulation of mobile robots, the response mechanism of the human brain attention network is simulated, and an attention model containing the ventral attention network and dorsal attention network is proposed, then a motivated developmental network is designed to simulate this attention mechanism. Furthermore, the working mechanism of the neuromodulation system is simulated to better regulate the robot’s motion and improve its ability to quickly respond to dynamic obstacles suddenly appeared in the environment. A new collision risk is designed by considering the influence of the obstacle’s speed, direction, and distance to the mobile robot. Finally, the feasibility of the proposed method is verified by the experimental results in different physical environments.

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移动机器人应对意外障碍的神经调节发展学习

随着机器人应用领域的逐步扩大，其工作环境也变得越来越复杂，可能会遇到各种不确定性。研究如何有效地应对环境中的各种不确定性已成为机器人研究领域的一个重要挑战。针对移动机器人在突然出现障碍物时的自主避障问题，提出了一种模拟视觉注意机制的动机发展网络动态避障算法。模拟生物视觉的反应机制，利用深度摄像头实现障碍物的检测和识别。为了加强对移动机器人的行为调控，模拟了人脑注意力网络的反应机制，提出了一个包含腹侧注意力网络和背侧注意力网络的注意力模型，并设计了一个动机发展网络来模拟这种注意力机制。此外，还模拟了神经调节系统的工作机制，以更好地调节机器人的运动，提高其对环境中突然出现的动态障碍物的快速反应能力。考虑到障碍物的速度、方向和与移动机器人距离的影响，设计了一种新的碰撞风险。最后，通过在不同物理环境下的实验结果验证了所提方法的可行性。

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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来源期刊

Cognitive Systems Research 工程技术-计算机：人工智能

CiteScore

9.40

自引率

5.10%

发文量

审稿时长

>12 weeks

期刊介绍： Cognitive Systems Research is dedicated to the study of human-level cognition. As such, it welcomes papers which advance the understanding, design and applications of cognitive and intelligent systems, both natural and artificial. The journal brings together a broad community studying cognition in its many facets in vivo and in silico, across the developmental spectrum, focusing on individual capacities or on entire architectures. It aims to foster debate and integrate ideas, concepts, constructs, theories, models and techniques from across different disciplines and different perspectives on human-level cognition. The scope of interest includes the study of cognitive capacities and architectures - both brain-inspired and non-brain-inspired - and the application of cognitive systems to real-world problems as far as it offers insights relevant for the understanding of cognition. Cognitive Systems Research therefore welcomes mature and cutting-edge research approaching cognition from a systems-oriented perspective, both theoretical and empirically-informed, in the form of original manuscripts, short communications, opinion articles, systematic reviews, and topical survey articles from the fields of Cognitive Science (including Philosophy of Cognitive Science), Artificial Intelligence/Computer Science, Cognitive Robotics, Developmental Science, Psychology, and Neuroscience and Neuromorphic Engineering. Empirical studies will be considered if they are supplemented by theoretical analyses and contributions to theory development and/or computational modelling studies.