A flexible wearable strain sensor for human-motion detection and a human-machine interface

With the development of Internet-of-Things (IoT) technology and fifth-generation mobile communications technology (5G), the demand for smart wearable devices is increasing. Therefore, strain sensors with high stretchability have been developed rapidly. The realization of electronic skin and smart wearable products requires continuous breakthroughs in flexible strain sensors. Here, a flexible, stretchable sensor with a sandwich structure was fabricated using two layers of polydimethylsiloxane (PDMS) and one sensing layer. The highly conductive sensing layer consisted of silver nanoflowers (AgNFs) and multi-walled carbon nanotubes (MWCNTs), whose synergistic effect successfully improved the flexibility and conductivity of the films. The sensor has high scalability (100%), a fast response time (60 ms), a high gauge factor (1187.07), and high stability, enabling the detection of physiological and motion signals such as the pulse, speech recognition, and the positions of joints. An electronic skin array was fabricated based on sensor-array technology to realize the multi-point-distributed detection of skin surface pressure. Moreover, a smart glove was designed using this electronic skin, and hand-gesture tracking was realized using a virtual-display interface through wireless transmission and 3D modeling technology. The sensor has broad development prospects in the fields of human-computer interactions, mechanical control and wearable electronic devices.

Automated summary

With the advancements in IoT and 5G technology, the demand for smart wearable devices is increasing. Flexible strain sensors with high scalability, fast response time, high gauge factor, and stability are being rapidly developed to meet the requirements of electronic skin and smart wearable products. These sensors have diverse applications in detecting physiological and motion signals such as pulse, speech recognition, and joint positions.