Haicheng Yao

TL;DR: Energy-efficient and secure wireless body sensor networks that are interconnected through radio surface plasmons propagating on metamaterial textiles are reported, created by using conductive fabrics that support surface-plasmon-like modes at radio communication frequencies.

TL;DR: The Asynchronously Coded Electronic Skin (ACES) is introduced—a neuromimetic architecture that enables simultaneous transmission of thermotactile information while maintaining exceptionally low readout latencies, even with array sizes beyond 10,000 sensors.

TL;DR: Near-field-enabled clothing capable of establishing wireless power and data connectivity between multiple distant points around the body to create a network of battery-free sensors interconnected by proximity to functional textile patterns is reported.

TL;DR: The Tactile Resistive Annularly Cracked E-Skin (TRACE) sensor is introduced to address the inherent trade-off between sensitivity and hysteresis in tactile sensors when using soft materials and it is discovered that piezoresistive sensors made using an array of three-dimensional (3D) metallic annular cracks on polymeric microstructures possess high sensitivities, low hyesteresis, and fast response.

TL;DR: In this paper, the confluence of wireless technology and biosensors offers the possibility to detect and manage medical conditions outside of clinical settings, such as wound infections, which represent a major clinical challen...