Nature Communications (Nov 2023)

A robotic sensory system with high spatiotemporal resolution for texture recognition

  • Ningning Bai,
  • Yiheng Xue,
  • Shuiqing Chen,
  • Lin Shi,
  • Junli Shi,
  • Yuan Zhang,
  • Xingyu Hou,
  • Yu Cheng,
  • Kaixi Huang,
  • Weidong Wang,
  • Jin Zhang,
  • Yuan Liu,
  • Chuan Fei Guo

DOI
https://doi.org/10.1038/s41467-023-42722-4
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 11

Abstract

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Abstract Humans can gently slide a finger on the surface of an object and identify it by capturing both static pressure and high-frequency vibrations. Although modern robots integrated with flexible sensors can precisely detect pressure, shear force, and strain, they still perform insufficiently or require multi-sensors to respond to both static and high-frequency physical stimuli during the interaction. Here, we report a real-time artificial sensory system for high-accuracy texture recognition based on a single iontronic slip-sensor, and propose a criterion—spatiotemporal resolution, to corelate the sensing performance with recognition capability. The sensor can respond to both static and dynamic stimuli (0-400 Hz) with a high spatial resolution of 15 μm in spacing and 6 μm in height, together with a high-frequency resolution of 0.02 Hz at 400 Hz, enabling high-precision discrimination of fine surface features. The sensory system integrated on a prosthetic fingertip can identify 20 different commercial textiles with a 100.0% accuracy at a fixed sliding rate and a 98.9% accuracy at random sliding rates. The sensory system is expected to help achieve subtle tactile sensation for robotics and prosthetics, and further be applied to haptic-based virtual reality and beyond.