Imperceptible, designable, and scalable braided electronic cord

Flexible sensors, friendly interfaces, and intelligent recognition are important in the research of novel human-computer interaction and the development of smart devices. However, major challenges are still encountered in designing user-centered smart devices with natural, convenient, and efficient interfaces. Inspired by the characteristics of textile-based flexible electronic sensors, in this article, we report a braided electronic cord with a low-cost, and automated fabrication to realize imperceptible, designable, and scalable user interfaces. The braided electronic cord is in a miniaturized form, which is suitable for being integrated with various occasions in life. To achieve high-precision interaction, a multi-feature fusion algorithm is designed to recognize gestures of different positions, different contact areas, and different movements performed on a single braided electronic cord. The recognized action results are fed back to varieties of interactive terminals, which show the diversity of cord forms and applications. Our braided electronic cord with the features of user friendliness, excellent durability and rich interaction mode will greatly promote the development of human-machine integration in the future. Inspired by the characteristics of textile-based flexible electronic sensors, the authors report a braided electronic cord with a low-cost, and automated fabrication to realize imperceptible, designable, and scalable user interfaces with the features of user-friendliness, excellent durability and rich interaction mode.

Automated summary

Flexible sensors, friendly interfaces, and intelligent recognition are important in the research of human-computer interaction and smart device development. This article presents a low-cost, automated fabrication method for a braided electronic cord that allows for imperceptible, designable, and scalable user interfaces. A multi-feature fusion algorithm is used to recognize gestures on the cord, providing high-precision interaction. The cord's user-friendly features, durability, and rich interaction mode have great potential for advancing human-machine integration.