基于遮挡环境中物体跟踪的动态同步定位和映射

IF 1.9 4区 计算机科学 Q3 ROBOTICS Robotica Pub Date : 2024-05-27 DOI:10.1017/s0263574724000420
Weili Ding, Ziqi Pei, Tao Yang, Taiyu Chen
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引用次数: 0

摘要

在实际应用中,许多配备嵌入式设备的机器人计算能力有限。这些限制往往会妨碍现有动态 SLAM 算法的性能,尤其是在面临遮挡或处理器限制时。这些挑战导致定位精度和效率低下。本文介绍了一种新颖的轻量级动态 SLAM 算法,该算法主要用于减轻移动物体遮挡所造成的干扰。我们提出的方法结合了深度学习物体检测算法和卡尔曼滤波器。这种组合为每个 SLAM 算法帧提供了动态物体的先验信息。利用 RANSAC 和外极约束等几何技术,我们的方法可以过滤掉动态特征点,专注于静态特征点的姿态确定,并增强 SLAM 算法在动态环境中的鲁棒性。我们在 TUM 公共数据集上进行了实验验证,结果表明我们的方法在动态场景中将定位精度提高了约 54%,将运行速度提高了 75.47%。
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Dynamic simultaneous localization and mapping based on object tracking in occluded environment
In practical applications, many robots equipped with embedded devices have limited computing capabilities. These limitations often hinder the performance of existing dynamic SLAM algorithms, especially when faced with occlusions or processor constraints. Such challenges lead to subpar positioning accuracy and efficiency. This paper introduces a novel lightweight dynamic SLAM algorithm designed primarily to mitigate the interference caused by moving object occlusions. Our proposed approach combines a deep learning object detection algorithm with a Kalman filter. This combination offers prior information about dynamic objects for each SLAM algorithm frame. Leveraging geometric techniques like RANSAC and the epipolar constraint, our method filters out dynamic feature points, focuses on static feature points for pose determination, and enhances the SLAM algorithm’s robustness in dynamic environments. We conducted experimental validations on the TUM public dataset, which demonstrated that our approach elevates positioning accuracy by approximately 54% and boosts the running speed by 75.47% in dynamic scenes.
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来源期刊
Robotica
Robotica 工程技术-机器人学
CiteScore
4.50
自引率
22.20%
发文量
181
审稿时长
9.9 months
期刊介绍: Robotica is a forum for the multidisciplinary subject of robotics and encourages developments, applications and research in this important field of automation and robotics with regard to industry, health, education and economic and social aspects of relevance. Coverage includes activities in hostile environments, applications in the service and manufacturing industries, biological robotics, dynamics and kinematics involved in robot design and uses, on-line robots, robot task planning, rehabilitation robotics, sensory perception, software in the widest sense, particularly in respect of programming languages and links with CAD/CAM systems, telerobotics and various other areas. In addition, interest is focused on various Artificial Intelligence topics of theoretical and practical interest.
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