用于算法辅助手势识别的有机水凝胶软 SEMG 电极

Yixin Xu, Lianjun Deng, Yuyao Lu, Jianhuan Zhang, Zhouyi Xu, Kaichen Xu, Chentao Zhang
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引用次数: 0

摘要

可监测表面肌电图(sEMG)信号等生理信号的表皮电子元件在个性化医疗保健、人机界面(HMI)和虚拟/增强现实(AR/VR)领域受到广泛关注。然而,传统的肌电图电极存在皮肤不适、易受运动伪影干扰和使用寿命短等问题。本文通过在高度交联的有机水凝胶网络中掺入部分还原氧化石墨烯(pRGO),开发了一种基于有机水凝胶的 sEMG 电极,它具有高导电性、低模量和长期稳定性。制成的聚丙烯酰胺/海藻酸钠/单宁酸/部分还原氧化石墨烯(PAM/SA/TA/pRGO)有机水凝胶具有告别性导电率(4.22 S m-1),同时保持了类似组织的顺应性(杨氏模量≈32 KPa)、优异的可拉伸性(≈600%)、高粘附性以及卓越的抗干燥性能。此外,通过将有机水凝胶电极固定在柔性高粘合剂(VHB)基底上,还制造出了可长期可靠使用的可拉伸 sEMG 电极。因此,集成电极显示出与商用电极相当的高信噪比(SNR)(35.15 db)。此外,在深度学习的辅助下,所提出的 sEMG 电极在区分复杂手势方面的识别准确率高达 97.11%。该系统可进一步用于实时远程操作,在人机沉浸式交互应用中具有广阔的前景。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Organohydrogel-Based Soft SEMG Electrodes for Algorithm-Assisted Gesture Recognition

Organohydrogel-Based Soft SEMG Electrodes for Algorithm-Assisted Gesture Recognition

Epidermal electronics that can monitor physiological signals such as surface electromyogram (sEMG) signals attract widespread attentions in personalized healthcare, human–machine interfaces (HMI) and virtual/augmented reality (AR/VR). However, conventional electromyographic electrodes suffer from skin discomfort, susceptibility to motion artifact interference, and short service lifetime. Here, an organohydrogel-based sEMG electrode endows with high conductivity, low modulus and long-term stability is developed by doping partially reduced graphene oxide (pRGO) into highly cross-linked organohydrogel network. The as-fabricated polyacrylamide/sodium alginate/tannic acid/partially reduced graphene oxide (PAM/SA/TA/pRGO) organohydrogel possesses farewell conductivity (4.22 S m−1) while preserving tissue-like compliance (Young's modulus ≈32 KPa), excellent stretchability (≈600%), high adhesion as well as superior anti-drying properties. In addition, a stretchable sEMG electrode for long-term reliable service is fabricated via immobilizing the organohydrogel electrodes onto a flexible very high bond (VHB) substrate. As a result, the integrated electrodes show high signal-to-noise ratio (SNR) (35.15 db) comparable to that of the commercial electrodes. Furthermore, with assistance of deep learning, the proposed sEMG electrodes obtain high identification accuracy of 97.11% in distinguishing sophisticated gestures. This system can be further exploited for real-time tele-operations and offers broad prospects in human–machine immersive interactive application.

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