用人工神经网络预测仪表鞋的步态周期百分比

Antonio Prado, Xiya Cao, Xiangzhuo Ding, S. Agrawal
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引用次数: 9

摘要

步态训练被广泛用于治疗步态异常。传统的步态测量系统仅限于仪器实验室。尽管可以在这些环境中进行步态测量,但对步态康复的实时步态参数进行稳健估计是一项挑战,特别是在地面行走时。在本文中,我们提出了一种新的方法来跟踪实验室外地面行走时的连续步态周期。在这种方法中,我们用传感器鞋垫和惯性测量单元来测量标准鞋类。对从鞋垫和imu获得的原始数据使用人工神经网络来计算整个步行过程中步态周期的连续百分比。我们在论文中表明,当对新受试者进行测试时,我们可以以7.2%的均方根误差(RMSE)预测步态周期。每个周期的开始可以在41.5 ms的RMSE时间内检测到,检出率为99%。该算法用从24名成年人身上收集的18840步进行了测试。在本文中,我们测试了全连接层、使用卷积层的编码器-解码器和循环层的组合,以确定提供最佳性能的架构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Prediction of Gait Cycle Percentage Using Instrumented Shoes with Artificial Neural Networks
Gait training is widely used to treat gait abnormalities. Traditional gait measurement systems are limited to instrumented laboratories. Even though gait measurements can be made in these settings, it is challenging to estimate gait parameters robustly in real-time for gait rehabilitation, especially when walking over-ground. In this paper, we present a novel approach to track the continuous gait cycle during overground walking outside the laboratory. In this approach, we instrument standard footwear with a sensorized insole and an inertial measurement unit. Artificial neural networks are used on the raw data obtained from the insoles and IMUs to compute the continuous percentage of the gait cycle for the entire walking session. We show in this paper that when tested with novel subjects, we can predict the gait cycle with a Root Mean Square Error (RMSE) of 7.2%. The onset of each cycle can be detected within an RMSE time of 41.5 ms with a 99% detection rate. The algorithm was tested with 18840 strides collected from 24 adults. In this paper, we tested a combination of fully-connected layers, an Encoder-Decoder using convolutional layers, and recurrent layers to identify an architecture that provided the best performance.
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