蒙特卡罗定位算法的改进全局定位和重采样技术

Humam Abualkebash, H. Ocak
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引用次数: 1

摘要

全局室内定位算法使机器人能够在初始姿态未知的情况下,利用传感器测量来估计其在预映射环境中的姿态。传统的自适应蒙特卡罗定位(AMCL)是一种能够成功处理全局不确定性的高效定位算法。由于移动机器人的全局定位问题是至关重要的,我们提出了一种新的方法,可以显著减少算法收敛到真实姿态所需的时间。在给定地图和初始扫描数据的情况下,基于观测模型检测高似然区域。因此,建议的样品分发将加快本地化进程。在本研究中,我们还提出了一种有效的重采样策略来处理绑架机器人问题,该策略使机器人在由于传感器视野内未映射的动态障碍物而导致样本权重下降时能够快速恢复。该方法通过考虑最近成功姿态估计的先验知识,将随机样本分布在以机器人姿态为中心的圆形区域内。由于样本分布在具有高概率的区域上,因此样本收敛到实际姿态所需的时间更短。小样本集(500个样本)的改进百分比超过了大地图的90%,在减少计算资源方面发挥了重要作用。总的来说,即使在小样本集的情况下,结果也证明了该方法的定位效果。因此,在降低计算成本方面,该方案将算法的实时性平均提高了85.12%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Improved Global Localization and Resampling Techniques for Monte Carlo Localization Algorithm
Global indoor localization algorithms enable the robot to estimate its pose in pre-mapped environments using sensor measurements when its initial pose is unknown. The conventional Adaptive Monte Carlo Localization (AMCL) is a highly efficient localization algorithm that can successfully cope with global uncertainty. Since the global localization problem is paramount in mobile robots, we propose a novel approach that can significantly reduce the amount of time it takes for the algorithm to converge to true pose. Given the map and initial scan data, the proposed algorithm detects regions with high likelihood based on the observation model. As a result, the suggested sample distribution will expedite the process of localization. In this study, we also present an effective resampling strategy to deal with the kidnapped robot problem that enables the robot to recover quickly when the sample weights drop-down due to unmapped dynamic obstacles within the sensor’s field of view. The proposed approach distributes the random samples within a circular region centered around the robot’s pose by taking into account the prior knowledge about the most recent successful pose estimation. Since the samples are distributed over the region with high probabilities, it will take less time for the samples to converge to the actual pose. The percentage of improvement for the small sample set (500 samples) exceeded 90% over the large maps and played a big role in reducing computational resources. In general, the results demonstrate the localization efficacy of the proposed scheme, even with small sample sets. Consequently, the proposed scheme significantly increases the real-time performance of the algorithm by 85.12% on average in terms of decreasing the computational cost.
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