Lateral Walking Gait Recognition and Hip Angle Prediction Using a Dual-Task Learning Framework.

IF 10.5 Q1 ENGINEERING, BIOMEDICAL

Cyborg and bionic systems (Washington, D.C.) Pub Date : 2025-05-01 eCollection Date: 2025-01-01 DOI:10.34133/cbsystems.0250

Mingxiang Luo, Meng Yin, Jinke Li, Ying Li, Worawarit Kobsiriphat, Hongliu Yu, Tiantian Xu, Xinyu Wu, Wujing Cao

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Abstract

Lateral walking exercise is beneficial for the hip abductor enhancement. Accurate gait recognition and continuous hip joint angle prediction are essential for the control of exoskeletons. We propose a dual-task learning framework, the "Twin Brother" model, which fuses convolutional neural network (CNN), long short-term memory (LSTM), neural networks (NNs), and the squeezing-elicited attention mechanism to classify the lateral gait stage and estimate the hip angle from electromyography (EMG) signals. The EMG signals of 6 muscles from 10 subjects during lateral walking were collected. Four gait phases were recognized, and the hip angles of both legs were continuously estimated. The sliding window length of 250 ms and the sliding increment of 3 ms were determined by the requirements of response time and recognition accuracy of the real-time system. We compared the performance of CNN-LSTM, CNN, LSTM, support vector machine, NN, K-nearest neighbor, and the "Twin Brother" models. The "Twin Brother" model achieved a recognition accuracy (mean ± SD) of 98.81% ± 0.14%. The model's predicted root mean square error (RMSE) for the left and right hip angles are 0.9183° ± 0.024° and 1.0511° ± 0.027°, respectively, where the R ² are 0.9853 ± 0.006 and 0.9808 ± 0.008. The accuracy of recognition and estimation are both better than comparative models. For gait phase percentage prediction, RMSE and R ² predicted by the model can reach 0.152° ± 0.014° and 0.986 ± 0.011, respectively. These results demonstrate that the method can be applied to lateral walking gait recognition and hip joint angle prediction.

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基于双任务学习框架的侧行步态识别和髋角预测。

侧行运动有利于髋关节外展肌增强。准确的步态识别和连续的髋关节角度预测是外骨骼控制的必要条件。我们提出了一种双任务学习框架，即“孪生兄弟”模型，该模型融合了卷积神经网络（CNN）、长短期记忆（LSTM）、神经网络（NNs）和挤压引起的注意机制，对侧向步态阶段进行分类，并从肌电图（EMG）信号中估计髋关节角度。收集10例受试者侧走时6块肌肉的肌电图信号。识别四种步态阶段，连续估计两条腿的髋角。根据实时系统对响应时间和识别精度的要求，确定滑动窗口长度为250 ms，滑动增量为3 ms。我们比较了CNN-LSTM、CNN、LSTM、支持向量机、NN、k近邻和“孪生兄弟”模型的性能。“孪生兄弟”模型的识别准确率（平均±SD）为98.81%±0.14%。模型预测左臀角和右臀角的均方根误差（RMSE）分别为0.9183°±0.024°和1.0511°±0.027°，r2分别为0.9853±0.006和0.9808±0.008。识别和估计的精度均优于比较模型。对于步态相位百分比预测，模型预测的RMSE和r2分别可达到0.152°±0.014°和0.986±0.011。结果表明，该方法可用于侧行步态识别和髋关节角度预测。

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