Terrain-aware path planning via semantic segmentation and uncertainty rejection filter with adversarial noise for mobile robots

IF 4.2 2区 计算机科学 Q2 ROBOTICS Journal of Field Robotics Pub Date : 2024-08-09 DOI:10.1002/rob.22411
Kangneoung Lee, Kiju Lee
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Abstract

In ground mobile robots, effective path planning relies on their ability to assess the types and conditions of the surrounding terrains. Neural network-based methods, which primarily use visual images for terrain classification, are commonly employed for this purpose. However, the reliability of these models can vary due to inherent discrepancies between the training images and the actual environment, leading to erroneous classifications and operational failures. Retraining models with additional images from the actual operating environment may enhance performance, but obtaining these images is often impractical or impossible. Moreover, retraining requires substantial offline processing, which cannot be performed online by the robot within an embedded processor. To address this issue, this paper proposes a neural network-based terrain classification model, trained using an existing data set, with a novel uncertainty rejection filter (URF) for terrain-aware path planning of mobile robots operating in unknown environments. A robot, equipped with a pretrained model, initially collects a small number of images (10 in this work) from its current environment to set the target uncertainty ratio of the URF. The URF then dynamically adjusts its sensitivity parameters to identify uncertain regions and assign associated traversal costs. This process occurs entirely online, without the need for offline procedures. The presented method was evaluated through simulations and physical experiments, comparing the point-to-point trajectories of a mobile robot equipped with (1) the neural network-based terrain classification model combined with the presented adaptive URF, (2) the classification model without the URF, and (3) the classification model combined with a nonadaptive version of the URF. Path planning performance measured the Hausdorff distances between the desired and actual trajectories and revealed that the adaptive URF significantly improved performance in both simulations and physical experiments (conducted 10 times for each setting). Statistical analysis via t-tests confirmed the significance of these results.

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通过语义分割和带有对抗性噪声的不确定性抑制滤波器实现移动机器人的地形感知路径规划
对于地面移动机器人来说,有效的路径规划有赖于其评估周围地形类型和条件的能力。基于神经网络的方法主要利用视觉图像进行地形分类,通常用于此目的。然而,由于训练图像与实际环境之间存在固有差异,这些模型的可靠性可能会有所不同,从而导致分类错误和运行失败。使用实际运行环境中的其他图像重新训练模型可能会提高性能,但获取这些图像往往是不切实际或不可能的。此外,重新训练需要大量离线处理,而机器人无法在嵌入式处理器中进行在线处理。为解决这一问题,本文提出了一种基于神经网络的地形分类模型,该模型利用现有数据集进行训练,并配有新型不确定性抑制滤波器(URF),用于在未知环境中运行的移动机器人的地形感知路径规划。配备了预训练模型的机器人最初会从当前环境中收集少量图像(本文中为 10 幅),以设定 URF 的目标不确定性比率。然后,URF 会动态调整其灵敏度参数,以识别不确定区域并分配相关的穿越成本。这一过程完全在线进行,无需离线程序。我们通过模拟和物理实验对所提出的方法进行了评估,比较了移动机器人的点对点轨迹,该移动机器人配备了(1)基于神经网络的地形分类模型与所提出的自适应 URF,(2)无 URF 的分类模型,以及(3)分类模型与非自适应版本的 URF。路径规划性能测量了期望轨迹与实际轨迹之间的豪斯多夫距离,结果表明自适应 URF 显著提高了模拟和物理实验(每种设置进行 10 次)的性能。通过 t 检验进行的统计分析证实了这些结果的重要性。
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
Journal of Field Robotics
Journal of Field Robotics 工程技术-机器人学
CiteScore
15.00
自引率
3.60%
发文量
80
审稿时长
6 months
期刊介绍: The Journal of Field Robotics seeks to promote scholarly publications dealing with the fundamentals of robotics in unstructured and dynamic environments. The Journal focuses on experimental robotics and encourages publication of work that has both theoretical and practical significance.
期刊最新文献
Issue Information Cover Image, Volume 42, Number 1, January 2025 Back Cover, Volume 42, Number 1, January 2025 Issue Information Cover Image, Volume 41, Number 8, December 2024
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