期刊
IEEE ROBOTICS AND AUTOMATION LETTERS
卷 7, 期 3, 页码 8487-8494出版社
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/LRA.2022.3187616
关键词
Wearable biofeedback system; instrumented footwear; human-in-the-loop; reinforcement learning; fuzzy logic; gait training
类别
资金
- U.S. National Science Foundation [IIS-1838799, IIS-1838725, CMMI-1944203]
This letter introduces a novel biofeedback engine (RLFLE) that uses reinforcement learning and fuzzy inference to personalize overground walking speed training. The RLFLE adjusts underfoot vibrotactile stimuli to encourage users to achieve a target walking speed and determine their maximum steady-state walking speed. Experimental results show that participants had lower walking speed errors when using RLFLE and it was more effective in determining an individual's maximum steady-state walking speed.
Wearable biofeedback systems (WBS) have been proposed to aid physical rehabilitation of individuals with motor impairments. Due to significant inter- and intra-individual differences, the effectiveness of a given biofeedback strategy may vary for different users and across therapeutic sessions, as a patient's functional recovery progresses. To date, only a paucity of research has investigated the use of biofeedback strategies that can self-adapt based on the user's response. This letter introduces a novel reinforcement learning with fuzzy logic biofeedback engine (RLFLE) for personalized overground walking speed training. The method leverages reinforcement learning and a fuzzy inference strategy to continuously modulate underfoot vibrotactile stimuli that encourage users to achieve a target walking speed. This stimulation strategy also enables the determination of a user's maximum steady-state walking speed during a gait training session overground. The RLFLE was implemented in a custom-engineered WBS and validated against two simpler biofeedback strategies during walking tests with healthy adults. Participants showed lower walking speed errors when training with the RLFLE. Additionally, results indicate that the new method is more effective in determining an individual's maximum steady-state walking speed. Given the importance of walking speed as an indicator of health status and as an essential outcome of exercise-based interventions, these results show promise for implementation in future technology-enhanced gait rehabilitation protocols.
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