Abstract

The human skin can reliably capture a wide range of multimodal data over a large surface while providing a soft interface. Artificial technologies using microelectromechanical systems (MEMS) can emulate these biological functions but present numerous challenges in fabrication, delamination due to soft-rigid interfaces, and electrical interference. To address these difficulties, we present a single-layer multimodal sensory skin made using only a highly sensitive hydrogel membrane. Using electrical impedance tomography techniques, we accessed up to 863,040 conductive pathways across the membrane, allowing us to identify at least six distinct types of multimodal stimuli, including human touch, damage, multipoint insulated presses, and local heating. Through comprehensive physical testing, we demonstrate that the highly redundant and coupled sensory information from these pathways can be structured using data-driven techniques, selecting which pathways should be monitored for efficient multimodal perception. To demonstrate our approach's versatility, we cast the hydrogel into the shape and size of an adult human hand. Using our information structuring strategy, we demonstrate the hand's ability to predict environmental conditions, localize human touch, and generate proprioceptive data. Our framework addresses the challenge of physically extracting meaningful information in multimodal soft sensing, opening new directions for the information-led design of single-layer skins in sensitive systems.