Driven by the increasing demand for intelligent wearable electronics, pressure sensors have attracted substantial research interest. However, a pressure sensor that possesses both high sensitivity and wearable comfort for practical application in daily activities is still lacking. Herein, we design a fabric−elastomer hybrid pressure sensor that achieves a balance between sensing performance and comfort. In this well-designed sensor, medical gauze coated with silver nanowires acts as substrate to improve the comfort of the sensor, and an elastomer acts as an active sensing element to enhance the sensitivity of the sensor. The sensor exhibits exciting sensing performance, including a high sensitivity (58 kPa −1 , 0−0.5 kPa), long-term endurance (>27 500 cycles), a faster response speed (<27 ms), and an ultralow limit of detection (2.7 Pa). Additionally, by adopting a prestretchable medical bandage as the substrate, the resulting sensor is insensitive to tensile strain and can accurately detect pressure stimuli under complex conditions. Then, we verify the application of the sensor in different scenarios, such as sensing tiny objects, monitoring human physiological information, and recognizing body motion. Additionally, we integrate a 4 × 4 sensor array for spatial information monitoring to provide a proof of concept for future wearable electronics, especially intelligent medical diagnostic systems.
This study proposes a vision‐correcting near‐eye light field display, which computationally manipulates sampling rays according to an eye's refractive error. Besides myopia and hyperopia, the proposed method can correct astigmatism and high‐order aberrations without any hardware modification. Implementation and experimental verification are provided by taking a severely astigmatic eye as an example.
This study proposes a vision‐correcting near‐eye light field display, which computationally manipulates sampling rays according to an eye's refractive error. Besides myopia and hyperopia, the proposed method can correct astigmatism and high‐order aberrations without any hardware modification. Implementation and experimental verification are provided by taking a severely astigmatic eye as an example.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.