Integrating Robust Gait Tracking Control and Variable Admittance Model for Pediatric Exoskeleton: An ‘Assist-as-Needed’ Framework

Q3 Engineering IFAC-PapersOnLine Pub Date : 2024-01-01 DOI:10.1016/j.ifacol.2024.05.020

Jyotindra Narayan , Mohamed Abbas , Subhash Pratap , Rahul Ranjan Bharti , Santosha K. Dwivedy

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Abstract

Traditional passive-assist rehabilitation, using a fixed trajectory, often falls short in engaging patients with residual muscle strength, leading to substandard outcomes. This work proposes a novel ‘assist-as-needed’ control strategy for a pediatric lower-limb exoskeleton system. It employs variable admittance control (VAC) based on the neuro-fuzzy inference technique, encouraging realistic subject-exoskeleton interactions and participation. Thereafter, a robust adaptive backstepping sliding mode (ABSM) control with a rapid reaching law (RRL) for gait tracking is introduced. The stability of the proposed position control is established using carefully selected Lyapunov candidate functions. Through numerical simulations, we compare our approach (ABSM-VAC) with an adaptive backstepping-fixed admittance control (AB-FAC), demonstrating improved tracking, compliance, and safety in active-assist gait training. This innovative method can significantly enhance rehabilitation outcomes, particularly for those with partial muscle strength, providing a more engaging and effective therapy experience.

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为儿科外骨骼整合鲁棒步态跟踪控制和可变间歇模型：按需辅助 "框架

传统的被动辅助康复使用固定的轨迹，往往无法让有残余肌力的患者参与其中，导致康复效果不达标。这项研究为儿科下肢外骨骼系统提出了一种新颖的 "按需辅助 "控制策略。它采用了基于神经模糊推理技术的可变导纳控制（VAC），鼓励真实的主体-外骨骼互动和参与。之后，还引入了用于步态跟踪的鲁棒自适应反步态滑动模式（ABSM）控制和快速到达律（RRL）。通过精心选择的 Lyapunov 候选函数，确定了所建议的位置控制的稳定性。通过数值模拟，我们将我们的方法（ABSM-VAC）与自适应反步态固定导纳控制（AB-FAC）进行了比较，结果表明，在主动辅助步态训练中，我们的方法改善了步态跟踪、顺应性和安全性。这种创新方法可以大大提高康复效果，特别是对那些肌肉力量不足的人，提供更有吸引力和更有效的治疗体验。

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来源期刊

IFAC-PapersOnLine Engineering-Control and Systems Engineering

CiteScore

1.70

自引率

0.00%

发文量

1122

期刊介绍： All papers from IFAC meetings are published, in partnership with Elsevier, the IFAC Publisher, in theIFAC-PapersOnLine proceedings series hosted at the ScienceDirect web service. This series includes papers previously published in the IFAC website.The main features of the IFAC-PapersOnLine series are: -Online archive including papers from IFAC Symposia, Congresses, Conferences, and most Workshops. -All papers accepted at the meeting are published in PDF format - searchable and citable. -All papers published on the web site can be cited using the IFAC PapersOnLine ISSN and the individual paper DOI (Digital Object Identifier). The site is Open Access in nature - no charge is made to individuals for reading or downloading. Copyright of all papers belongs to IFAC and must be referenced if derivative journal papers are produced from the conference papers. All papers published in IFAC-PapersOnLine have undergone a peer review selection process according to the IFAC rules.

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