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基于贝叶斯推理的下肢可穿戴机器人步态估计的鲁棒性增强

Robustification of Bayesian-Inference-Based Gait Estimation for Lower-limb Wearable Robots.

作者信息

Hsu Ting-Wei, Gregg Robert D, Thomas Gray C

机构信息

Ting-Wei Hsu was with the Department of Mechanical Engineering, University of Michigan, Ann Arbor, MI 48109 USA. He is now with Bechamo LLC, Buffalo, NY 14203 USA.

Robert D. Gregg is with the Department of Robotics, University of Michigan, Ann Arbor, MI 48109 USA.

出版信息

IEEE Robot Autom Lett. 2024 Mar;9(3):2104-2111. doi: 10.1109/lra.2024.3354558. Epub 2024 Jan 16.

DOI:10.1109/lra.2024.3354558
PMID:38313832
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10831317/
Abstract

Lower-limb wearable robots designed to assist people in everyday activities must reliably recover from any momentary confusion about what the user is doing. Such confusion might arise from momentary sensor failure, collision with an obstacle, losing track of gait due to an out-of-distribution stride, etc. Systems that infer a user's walking condition from angle measurements using Bayesian filters (e.g., extended Kalman filters) have been shown to accurately track gait across a range of activities. However, due to the fundamental problem structure and assumptions of Bayesian filter implementations, such estimators risk becoming 'lost' with little hope of a quick recovery. In this paper, we 1) introduce a Monte Carlo-based metric to quantify the robustness of pattern-tracking gait estimators, 2) propose strategies for improving tracking robustness, and 3) systematically evaluate them against this new metric using a publicly available gait biomechanics dataset. Our results, aggregating 2,700 trials of simulated walking of 10 able-bodied subjects under random perturbations, suggest that drastic improvements in robustness (from 8.9% to 99%) are possible using relatively simple modifications to the estimation process without noticeably degrading estimator accuracy.

摘要

旨在协助人们进行日常活动的下肢可穿戴机器人必须能够从任何关于用户正在做什么的瞬间混乱中可靠地恢复过来。这种混乱可能源于瞬间的传感器故障、与障碍物碰撞、由于异常步幅而失去步态跟踪等。已证明,使用贝叶斯滤波器(例如扩展卡尔曼滤波器)从角度测量推断用户行走状态的系统能够在一系列活动中准确跟踪步态。然而,由于贝叶斯滤波器实现的基本问题结构和假设,这种估计器有“迷失”的风险,几乎没有快速恢复的希望。在本文中,我们1)引入一种基于蒙特卡洛的度量来量化模式跟踪步态估计器的鲁棒性,2)提出提高跟踪鲁棒性的策略,3)使用公开可用的步态生物力学数据集针对这一新度量对它们进行系统评估。我们的结果汇总了10名健全受试者在随机扰动下2700次模拟行走试验,结果表明,通过对估计过程进行相对简单的修改,在不明显降低估计器准确性的情况下,可以大幅提高鲁棒性(从8.9%提高到99%)。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/bb05/10831317/2e85ead9e5c6/nihms-1957429-f0006.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/bb05/10831317/1e9cd5aeb708/nihms-1957429-f0002.jpg
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