Robust hydrogel sensors for unsupervised learning enabled sign‐to‐verbal translation
Hude Ma,
Haiyang Qin,
Xiao Xiao,
Na Liu,
Shaolei Wang,
Junye Li,
Sophia Shen,
Shuqi Dai,
Mengmeng Sun,
Peiyi Li,
Xiaofang Pan,
Mingjun Huang,
Baoyang Lu,
Jun Chen,
Lidong Wu
Affiliations
Hude Ma
Fisheries Engineering Institute, Chinese Academy of Fishery Sciences Beijing the People's Republic of China
Haiyang Qin
Fisheries Engineering Institute, Chinese Academy of Fishery Sciences Beijing the People's Republic of China
Xiao Xiao
Department of Bioengineering University of California Los Angeles California USA
Na Liu
Fisheries Engineering Institute, Chinese Academy of Fishery Sciences Beijing the People's Republic of China
Shaolei Wang
Department of Bioengineering University of California Los Angeles California USA
Junye Li
College of Electronics and Information Engineering Shenzhen University Shenzhen the People's Republic of China
Sophia Shen
Department of Bioengineering University of California Los Angeles California USA
Shuqi Dai
South China Advanced Institute for Soft Matter Science and Technology, School of Molecular Science and Engineering, South China University of Technology Guangzhou the People's Republic of China
Mengmeng Sun
Fisheries Engineering Institute, Chinese Academy of Fishery Sciences Beijing the People's Republic of China
Peiyi Li
Fisheries Engineering Institute, Chinese Academy of Fishery Sciences Beijing the People's Republic of China
Xiaofang Pan
College of Electronics and Information Engineering Shenzhen University Shenzhen the People's Republic of China
Mingjun Huang
South China Advanced Institute for Soft Matter Science and Technology, School of Molecular Science and Engineering, South China University of Technology Guangzhou the People's Republic of China
Baoyang Lu
Chinese Academy of Fishery Sciences Beijing the People's Republic of China
Jun Chen
Department of Bioengineering University of California Los Angeles California USA
Lidong Wu
Fisheries Engineering Institute, Chinese Academy of Fishery Sciences Beijing the People's Republic of China
Abstract Highly stretchable and robust strain sensors are rapidly emerging as promising candidates for a diverse of wearable electronics. The main challenge for the practical application of wearable electronics is the energy consumption and device aging. Energy consumption mainly depends on the conductivity of the sensor, and it is a key factor in determining device aging. Here, we design a liquid metal (LM)‐embedded hydrogel as a sensing material to overcome the barrier of energy consumption and device aging of wearable electronics. The sensing material simultaneously exhibits high conductivity (up to 22 S m−1), low elastic modulus (23 kPa), and ultrahigh stretchability (1500%) with excellent robustness (consistent performance against 12 000 mechanical cycling). A motion monitoring system is composed of intrinsically soft LM‐embedded hydrogel as sensing material, a microcontroller, signal‐processing circuits, Bluetooth transceiver, and self‐organizing map developed software for the visualization of multi‐dimensional data. This system integrating multiple functions including signal conditioning, processing, and wireless transmission achieves monitor hand gesture as well as sign‐to‐verbal translation. This approach provides an ideal strategy for deaf‐mute communicating with normal people and broadens the application of wearable electronics.
