| Literature DB >> 31372108 |
Siyi Xu1, Daniel M Vogt1, Wen-Hao Hsu2, John Osborne2, Timothy Walsh2, Jonathan R Foster2, Sarah K Sullivan2, Vincent C Smith3, Andreas Rousing2, Eugene C Goldfield2, Robert J Wood1.
Abstract
Fluidic soft sensors have been widely used in wearable devices for human motion capturing. However, thus far, the biocompatibility of the conductive liquid, the linearity of the sensing signal, and the hysteresis between the loading and release processes have limited the sensing quality as well as the applications of these sensors. In this paper, silicone based strain and force sensors composed of a novel biocompatible conductive liquid (potassium iodide and glycerol solution) are introduced. The strain sensors exhibit negligible hysteresis up to 5 Hz, with a gauge factor of 2.2 at 1 Hz. The force sensors feature a novel multi-functional layered structure, with micro-cylinder-filled channels to achieve high linearity, low hysteresis (5.3% hysteresis at 1 Hz), and good sensitivity (100% resistance increase at a 5 N load). The sensors' gauge factors are stable at various temperatures and humidity levels. These bio-compatible, low hysteresis, and high linearity sensors are promising for safe and reliable diagnostic devices, wearable motion capture, and compliant human-computer interfaces.Entities:
Keywords: biocompatible sensors; fluidic soft sensors; wearable sensors
Year: 2018 PMID: 31372108 PMCID: PMC6675035 DOI: 10.1002/adfm.201807058
Source DB: PubMed Journal: Adv Funct Mater ISSN: 1616-301X Impact factor: 18.808