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基于足迹阴影图像处理和深度学习的智能蹦床健身系统的三维脚部位置估计。

Three-Dimensional Foot Position Estimation Based on Footprint Shadow Image Processing and Deep Learning for Smart Trampoline Fitness System.

机构信息

Ansan R&D Campus, LG Innotek, Ansan 15588, Korea.

Renewable Energy Solution Group, Korea Electric Power Research Institute (KEPRI), Naju 58277, Korea.

出版信息

Sensors (Basel). 2022 Sep 13;22(18):6922. doi: 10.3390/s22186922.

DOI:10.3390/s22186922
PMID:36146261
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9504811/
Abstract

In the wake of COVID-19, the digital fitness market combining health equipment and ICT technologies is experiencing unexpected high growth. A smart trampoline fitness system is a new representative home exercise equipment for muscle strengthening and rehabilitation exercises. Recognizing the motions of the user and evaluating user activity is critical for implementing its self-guided exercising system. This study aimed to estimate the three-dimensional positions of the user's foot using deep learning-based image processing algorithms for footprint shadow images acquired from the system. The proposed system comprises a jumping fitness trampoline; an upward-looking camera with a wide-angle and fish-eye lens; and an embedded board to process deep learning algorithms. Compared with our previous approach, which suffered from a geometric calibration process, a camera calibration method for highly distorted images, and algorithmic sensitivity to environmental changes such as illumination conditions, the proposed deep learning algorithm utilizes end-to-end learning without calibration. The network is configured with a modified Fast-RCNN based on ResNet-50, where the region proposal network is modified to process location regression different from box regression. To verify the effectiveness and accuracy of the proposed algorithm, a series of experiments are performed using a prototype system with a robotic manipulator to handle a foot mockup. The three root mean square errors corresponding to X, Y, and Z directions were revealed to be 8.32, 15.14, and 4.05 mm, respectively. Thus, the system can be utilized for motion recognition and performance evaluation of jumping exercises.

摘要

在 COVID-19 之后,结合健康设备和 ICT 技术的数字健身市场正在经历意想不到的高速增长。智能蹦床健身系统是一种新的代表性家庭运动设备,用于肌肉强化和康复运动。识别用户的动作并评估用户的活动对于实施其自主锻炼系统至关重要。本研究旨在使用基于深度学习的图像处理算法估计用户脚部的三维位置,该算法是从系统获取的脚印阴影图像。该系统包括一个跳跃健身蹦床;一个带有广角和鱼眼镜头的向上看的相机;和一个用于处理深度学习算法的嵌入式板。与我们之前的方法相比,该方法存在几何校准过程、高度失真图像的相机校准方法以及算法对光照条件等环境变化的敏感性问题,所提出的深度学习算法利用无需校准的端到端学习。该网络配置了一个基于 ResNet-50 的修改后的 Fast-RCNN,其中区域提议网络被修改为处理不同于框回归的位置回归。为了验证所提出算法的有效性和准确性,使用带有机器人机械手的原型系统进行了一系列实验,以处理脚部模型。X、Y 和 Z 方向的三个均方根误差分别为 8.32、15.14 和 4.05 毫米。因此,该系统可用于跳跃运动的运动识别和性能评估。

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