IEEE Trans Biomed Eng. 2022 Nov;69(11):3460-3471. doi: 10.1109/TBME.2022.3170850. Epub 2022 Oct 19.
This study introduces a deep learning approach to accurately predict challenging mechanical environments that possibly cause decreasing postural stability.
Dual-axis robotic platforms were utilized to simulate various environments and collect center-of-pressure data during narrow and wide stance. A convolutional neural network (CNN) was developed to predict environmental conditions given segmented time-series balance data. Different window sizes were examined to investigate its minimal length for reliable prediction. Effectiveness of the presented CNN was additionally compared with that of conventional machine learning models. Its applicability with low sampled data or more natural stance data was then evaluated.
The CNN achieved above 94.5% in the overall prediction accuracy even with 2.5-second length postural sway data, which cannot be achieved by traditional machine learning (ps < 0.05). Increasing data length beyond 2.5 seconds slightly improved the accuracy of CNN but substantially increased training time (60% longer). Importantly, results from averaged normalized confusion matrices revealed that CNN is much more capable of differentiating the mid-level environmental condition. Deep learning could also produce comparable performance in predicting environments even with much lower sampled data or with standing posture changed.
CNN removed the burden of feature preparation and accurately predicted environments when dealing with short-length data. It also indicated potentials to real life applications.
This study contributes to the advancement of wearable devices and human interactive robots (e.g., exoskeletons and prostheses) by predicting environmental contexts and preventing potential falls.
本研究提出了一种深度学习方法,以准确预测可能导致姿势稳定性下降的挑战性机械环境。
利用双轴机器人平台模拟各种环境,并在窄位和宽位时采集压力中心数据。开发了一个卷积神经网络(CNN),用于根据分段时间序列平衡数据预测环境条件。研究了不同的窗口大小,以探讨其可靠预测的最小长度。还将提出的 CNN 的有效性与传统机器学习模型进行了比较。然后评估了其在低采样数据或更自然的站立姿势数据下的适用性。
即使使用 2.5 秒长的姿势摆动数据,CNN 的总体预测准确率也超过 94.5%,而传统机器学习无法达到这一准确率(p<0.05)。将数据长度增加到 2.5 秒以上略微提高了 CNN 的准确性,但大大增加了训练时间(长 60%)。重要的是,平均归一化混淆矩阵的结果表明,CNN 更能够区分中级环境条件。即使在采样数据较少或站立姿势改变的情况下,深度学习也可以在预测环境方面产生相当的性能。
CNN 减轻了特征准备的负担,并在处理短数据时准确预测了环境。它还表明了在实际应用中的潜力。
本研究通过预测环境背景和防止潜在跌倒,为可穿戴设备和人机交互机器人(如外骨骼和假肢)的发展做出了贡献。
