AI Article Synopsis
- This paper presents a fiber-optic sensor array utilizing Fabry-Perot interference and machine learning to identify volatile organic liquids (VOLs).
- The sensor array includes three types of optical fiber tips—an intrinsic flat endface, a hydrophobic-coated endface, and a hydrophilic-coated endface—to enhance classification accuracy.
- Machine learning methods, particularly convolutional neural networks, effectively classify different organic liquids by analyzing time-transient response signals from droplet evaporation, demonstrating improved performance through diverse data collection.
Article Abstract
In this paper, we report an array of fiber-optic sensors based on the Fabry-Perot interference principle and machine learning-based analyses for identifying volatile organic liquids (VOLs). Three optical fiber tip sensors with different surfaces were included in the array of sensors to improve the accuracy for identifying liquids: an intrinsic (unmodified) flat cleaved endface, a hydrophobic-coated endface, and a hydrophilic-coated endface. The time-transient responses of evaporating droplets from the optical fiber tip sensors were monitored and collected following the controlled immersion tests of 11 different organic liquids. A continuous wavelet transform was used to convert the time-transient response signal into images. These images were then utilized to train convolution neural networks for classification (identification of VOLs). We show that diversity in the information collected using the array of three sensors helps machine learning-based methods perform significantly better. We explore different pipelines for combining the information from the array of sensors within a machine learning framework and their effect on the robustness of models. The results showed that the machine learning-based methods achieved high accuracy in their classification of different liquids based on their droplet evaporation time-transient events.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9909791 | PMC |
| http://dx.doi.org/10.1021/acsomega.2c05451 | DOI Listing |
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