a) Fabrication process of a silk fabric-based respiration sensor. (b)
$ 11.50 · 5 (452) · In stock
Download scientific diagram | (a) Fabrication process of a silk fabric-based respiration sensor. (b) Real-time monitoring of shallow breathing (black), normal breathing (blue), and fast breathing (red) with a humidity-sensitive textile-based device. Inset Fig. 4b is the optical photo of the EL device at different breathing states. (c) are the enlarged response curves corresponding to shallow breathing, normal breathing, and fast breathing, respectively. from publication: Textile-Based Humidity-Driven Wearable Electroluminescent for Visual Sensing | Miniaturization and integration have become a trend of modern wearable intelligent electronics. But how to visualize sensing information in a single-level device remains a challenge. Here, we present a humidity-driven textile-based electroluminescent (EL) interactive display | Electroluminescence, Sensing and Devices | ResearchGate, the professional network for scientists.
Micromachines, Free Full-Text
Zhen Jiang's research works Shanghai University, Shanghai (SHU
Sensors, Free Full-Text
Mei Liu's research works Shanghai University, Shanghai (SHU) and
Photograph of the chip after post-processing with PI2555 and 3.8
Dependences of output frequency (a) and absolute error (b) on
Functionalized Fiber-Based Strain Sensors: Pathway to Next-Generation Wearable Electronics
Biosensors, Free Full-Text
A skin-conformal and breathable humidity sensor for emotional mode recognition and non-contact human-machine interface
XRD pattern of ZnO/CuO nanocomposite.
Fabrication process of a silk fabric-based respiration sensor.
Fabrication Techniques and Sensing Mechanisms of Textile-Based Strain Sensors: From Spatial 1D and 2D Perspectives
Textile-based electroluminescent interactive device. (a) Optical
Recent progress in silk fibroin-based flexible electronics