| Literature DB >> 31335257 |
Minkyung Sim1, Kyung Hwa Lee2, Kwon Sik Shin1, Jeong Hee Shin1, Ji-Woong Choi1, Hongsoo Choi3, Cheil Moon4, Hyun Sik Kim5, Yuljae Cho6, Seung Nam Cha6, Jae Eun Jung7, Jung Inn Sohn6, Jae Eun Jang1.
Abstract
An artificial tactile system has attracted tremendous interest and intensive study, since it can be applied as a new functional interface between humans and electronic devices. Unfortunately, most previous works focused on improving the sensitivity of sensors. However, humans also respond to psychological feelings for sensations such as pain, softness, or roughness, which are important factors for interacting with others and objects. Here, we present an electronic skin concept that generates a "pain" warning signal, specifically, to sharp "prick" and "hot" sensations. To simplify the sensor structure for these two feelings, a single-body tactile sensor design is proposed. By exploiting "hot" feeling based on the Seebeck effect instead of the pyroelectric property, it is possible to distinguish points registering a "hot" feeling from those generating a "prick" feeling, which is based on the piezoelectric effect. The control of free carrier concentration in nanowire induced the appropriate level of Seebeck current, which enabled the sensor system to be more reliable. The first derivatives of the piezo and Seebeck output signals are the key factors for the signal processing of the "pain" feeling. The main idea can be applied to mimic other psychological tactile feelings.Entities:
Keywords: Seebeck effect; ZnO nanowire; artificial pain feeling; electronic skin; piezoelectric effect; pyroelectric effect; tactile sensor
Year: 2019 PMID: 31335257 DOI: 10.1089/soro.2018.0049
Source DB: PubMed Journal: Soft Robot ISSN: 2169-5172 Impact factor: 8.071