npj Flexible Electronics (Apr 2023)

Ultra-stable and tough bioinspired crack-based tactile sensor for small legged robots

  • Taewi Kim,
  • Insic Hong,
  • Minho Kim,
  • Sunghoon Im,
  • Yeonwook Roh,
  • Changhwan Kim,
  • Jongcheon Lim,
  • Dongjin Kim,
  • Jieun Park,
  • Seunggon Lee,
  • Daseul Lim,
  • Junggwang Cho,
  • Seokhaeng Huh,
  • Seung-Un Jo,
  • ChangHwan Kim,
  • Je-Sung Koh,
  • Seungyong Han,
  • Daeshik Kang

DOI
https://doi.org/10.1038/s41528-023-00255-2
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 12

Abstract

Read online

Abstract For legged robots, collecting tactile information is essential for stable posture and efficient gait. However, mounting sensors on small robots weighing less than 1 kg remain challenges in terms of the sensor’s durability, flexibility, sensitivity, and size. Crack-based sensors featuring ultra-sensitivity, small-size, and flexibility could be a promising candidate, but performance degradation due to crack growing by repeated use is a stumbling block. This paper presents an ultra-stable and tough bio-inspired crack-based sensor by controlling the crack depth using silver nanowire (Ag NW) mesh as a crack stop layer. The Ag NW mesh inspired by skin collagen structure effectively mitigated crack propagation. The sensor was very thin, lightweight, sensitive, and ultra-durable that maintains its sensitivity during 200,000 cycles of 0.5% strain. We demonstrate sensor’s feasibility by implementing the tactile sensation to bio-inspired robots, and propose statistical and deep learning-based analysis methods which successfully distinguished terrain type.