Light: Science & Applications (Apr 2023)

Deep-learning-based gas identification by time-variant illumination of a single micro-LED-embedded gas sensor

  • Incheol Cho,
  • Kichul Lee,
  • Young Chul Sim,
  • Jae-Seok Jeong,
  • Minkyu Cho,
  • Heechan Jung,
  • Mingu Kang,
  • Yong-Hoon Cho,
  • Seung Chul Ha,
  • Kuk-Jin Yoon,
  • Inkyu Park

DOI
https://doi.org/10.1038/s41377-023-01120-7
Journal volume & issue
Vol. 12, no. 1
pp. 1 – 12

Abstract

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Abstract Electronic nose (e-nose) technology for selectively identifying a target gas through chemoresistive sensors has gained much attention for various applications, such as smart factory and personal health monitoring. To overcome the cross-reactivity problem of chemoresistive sensors to various gas species, herein, we propose a novel sensing strategy based on a single micro-LED (μLED)-embedded photoactivated (μLP) gas sensor, utilizing the time-variant illumination for identifying the species and concentrations of various target gases. A fast-changing pseudorandom voltage input is applied to the μLED to generate forced transient sensor responses. A deep neural network is employed to analyze the obtained complex transient signals for gas detection and concentration estimation. The proposed sensor system achieves high classification (~96.99%) and quantification (mean absolute percentage error ~ 31.99%) accuracies for various toxic gases (methanol, ethanol, acetone, and nitrogen dioxide) with a single gas sensor consuming 0.53 mW. The proposed method may significantly improve the efficiency of e-nose technology in terms of cost, space, and power consumption.