Yun Yang, Lei Jia, Ziheng Wang, Jie Suo, Xiaorui Yang, Shuping Xue, Yingying Zhang, Hui Li, Tingting Cai
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By combining neural network algorithms with the signal acquisition module and the master computer, an intelligent multi-sensor node system for badminton monitoring is established. The FA-Sensor exhibits high sensitivity to bending and twisting motions due to its elastic TPE shell and arched shape design. It minimizes interference with human motion during bending (10°–150°) or twisting (20°–100°) over a wide range. The peak output voltage of the FA-Sensor demonstrates a clear functional relationship with the bending angle, exhibiting piecewise sensitivities of 7.98 and 29.28 mV/°, respectively. For seven different parts of the human body, it can be quickly customized to different sizes, with stable and repeatable response outputs. In application, the badminton sports monitoring system enables real-time feedback and recognition of four typical technical movements, achieving a recognition accuracy rate of 97.2%. 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引用次数: 0
摘要
有效监测和识别运动对提高运动成绩至关重要。传统方法存在场地要求高和功耗大的局限性,不适合长期跟踪和监测。三电传感器是体区网络低功耗监测的一个潜在解决方案。然而,目前羽毛球三电感应数据的分析方法相对简单,而基于 3D 打印技术的柔性三电感应器则面临关节大范围弯曲或扭曲时的不适等问题。有鉴于此,我们提出了一种基于 3D 打印的柔性拱形三电传感器(FA-Sensor)。通过将神经网络算法与信号采集模块和主控计算机相结合,建立了用于羽毛球运动监测的智能多传感器节点系统。FA 传感器采用弹性 TPE 外壳和弧形设计,对弯曲和扭转运动具有高灵敏度。它能在较大范围内最大限度地减少弯曲(10°-150°)或扭转(20°-100°)时对人体运动的干扰。FA 传感器的峰值输出电压与弯曲角度有明显的功能关系,片状灵敏度分别为 7.98 和 29.28 mV/°。对于人体的七个不同部位,它可以根据不同的尺寸快速定制,并具有稳定和可重复的响应输出。在应用中,羽毛球运动监测系统可对四个典型技术动作进行实时反馈和识别,识别准确率达到 97.2%。该系统在帮助运动员分析和提升羽毛球技术的同时,也展现出在其他智能运动领域的应用潜力。
Flexible arch-shaped triboelectric sensor based on 3D printing for badminton movement monitoring and intelligent recognition of technical movements
Efficient monitoring and recognition of movement are crucial in enhancing athletic performance. Traditional methods have limitations in terms of high site requirements and power consumption, making them unsuitable for long-term tracking and monitoring. A potential solution to low-power monitoring of body area networks is triboelectric sensors. However, the current analysis method for badminton triboelectric sensing data is relatively simple, while flexible, triboelectric sensors based on 3D printing face issues such as discomfort when joints are bent or twisted in a large range. In light of this, a flexible arch-shaped triboelectric sensor based on 3D printing (FA-Sensor) is proposed. By combining neural network algorithms with the signal acquisition module and the master computer, an intelligent multi-sensor node system for badminton monitoring is established. The FA-Sensor exhibits high sensitivity to bending and twisting motions due to its elastic TPE shell and arched shape design. It minimizes interference with human motion during bending (10°–150°) or twisting (20°–100°) over a wide range. The peak output voltage of the FA-Sensor demonstrates a clear functional relationship with the bending angle, exhibiting piecewise sensitivities of 7.98 and 29.28 mV/°, respectively. For seven different parts of the human body, it can be quickly customized to different sizes, with stable and repeatable response outputs. In application, the badminton sports monitoring system enables real-time feedback and recognition of four typical technical movements, achieving a recognition accuracy rate of 97.2%. The system enables athletes to analyze and enhance badminton technology while also exhibiting promising potential for application in other intelligent sports domains.
期刊介绍:
APL Materials features original, experimental research on significant topical issues within the field of materials science. In order to highlight research at the forefront of materials science, emphasis is given to the quality and timeliness of the work. The journal considers theory or calculation when the work is particularly timely and relevant to applications.
In addition to regular articles, the journal also publishes Special Topics, which report on cutting-edge areas in materials science, such as Perovskite Solar Cells, 2D Materials, and Beyond Lithium Ion Batteries.