Terrain slope parameter recognition for exoskeleton robot in urban multi-terrain environments

IF 5 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Complex & Intelligent Systems Pub Date : 2024-01-11 DOI:10.1007/s40747-023-01319-6
Ran Guo, Wenjiang Li, Yulong He, Tangjian Zeng, Bin Li, Guangkui Song, Jing Qiu
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Abstract

Lower limb augmentation exoskeletons (LLAE) have been applied in several domains to enforce human walking capability. As humans can adjust their joint moments and generate different amounts of mechanical energy while walking on different terrains, the LLAEs should provide adaptive augmented torques to the wearer in multi-terrain environments, which requires LLAEs to implement accurate terrain parameter recognition. However, the outputs of previous terrain parameter recognition algorithms are more redundant, and the algorithms have higher computational complexity and are susceptible to external interference. Therefore, to resolve the above issues, this paper proposed a neural network regression (NNR)-based algorithm for terrain slope parameter recognition. In particular, this paper defined for the first time a unified representation of terrain parameters: terrain slope (TS), a single parameter that can provide enough information for exoskeleton control. In addition, our proposed NNR model uses only basic human parameters and LLAE joint motion posture measured by an Inertial Measurement Unit (IMU) as inputs to predict the TS, which is computationally simpler and less susceptible to interference. The model was evaluated using K-fold cross-validation and the results showed that the model had an average error of only 2.09\(^\circ \). To further validate the effectiveness of the proposed algorithm, it was verified on a homemade LLAE and the experimental results showed that the proposed TS parameter recognition algorithm only produces an average error of 3.73\(^\circ \) in multi-terrain environments. The defined terrain parameters can meet the control requirements of LLAE in urban multi-terrain environments. The proposed TS parameter recognition algorithm could facilitate the optimization of the adaptive gait control of the exoskeleton system and improve user experience, energy efficiency, and overall comfort.

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城市多地形环境中外骨骼机器人的地形坡度参数识别
下肢增强外骨骼(LLAE)已被应用于多个领域,以增强人类的行走能力。由于人类在不同地形上行走时可以调整关节力矩并产生不同的机械能,因此下肢增强外骨骼应在多地形环境中为穿戴者提供自适应增强力矩,这就要求下肢增强外骨骼实现精确的地形参数识别。然而,以往的地形参数识别算法输出冗余较多,算法计算复杂度较高,且易受外界干扰。因此,为了解决上述问题,本文提出了一种基于神经网络回归(NNR)的地形坡度参数识别算法。特别是,本文首次定义了地形参数的统一表示:地形坡度(TS),这一单一参数可为外骨骼控制提供足够的信息。此外,我们提出的 NNR 模型仅使用基本人体参数和由惯性测量单元(IMU)测量的 LLAE 关节运动姿势作为预测 TS 的输入,这在计算上更简单,且不易受干扰。利用K-fold交叉验证对模型进行了评估,结果表明该模型的平均误差仅为2.09(^\circ \)。为了进一步验证所提算法的有效性,在自制的 LLAE 上进行了验证,实验结果表明,所提 TS 参数识别算法在多地形环境下产生的平均误差仅为 3.73(^\circ \)。所定义的地形参数能够满足城市多地形环境下 LLAE 的控制要求。所提出的TS参数识别算法可以促进外骨骼系统自适应步态控制的优化,改善用户体验、能效和整体舒适度。
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来源期刊
Complex & Intelligent Systems
Complex & Intelligent Systems COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-
CiteScore
9.60
自引率
10.30%
发文量
297
期刊介绍: Complex & Intelligent Systems aims to provide a forum for presenting and discussing novel approaches, tools and techniques meant for attaining a cross-fertilization between the broad fields of complex systems, computational simulation, and intelligent analytics and visualization. The transdisciplinary research that the journal focuses on will expand the boundaries of our understanding by investigating the principles and processes that underlie many of the most profound problems facing society today.
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