Abstract
During the last decades the whispering gallery mode based sensors have become a prominent solution for label-free sensing of various physical and chemical parameters. At the same time, the widespread utilization of the approach is hindered by the restricted applicability of the known configurations for ambient variations quantification outside the laboratory conditions and their low affordability, where necessity on the spectrally-resolved data collection is among the main limiting factors. In this paper we demonstrate the first realization of an affordable whispering gallery mode sensor powered by deep learning and multi-resonator imaging at a fixed frequency. It has been shown that the approach enables refractive index unit (RIU) prediction with an absolute error at 3×10-6 level for dynamic range of the RIU variations from 0 to 2×10-3 with temporal resolution of several milliseconds and instrument-driven detection limit of 3×10−5. High sensing accuracy together with instrumental affordability and production simplicity places the reported detector among the most cost-effective realizations of the whispering gallery mode approach. The proposed solution is expected to have a great impact on the shift of the whole sensing paradigm away from the model-based and to the flexible self-learning solutions.
Highlights
Optical resonance in the dielectric circular microcavities referred to as the effect of whispering gallery modes (WGM) has drawn a great attention as a highly sensitive and label-free instrument for biochemical components detection[1,2,3,4]
In this work we have demonstrated the first example of an affordable self-learning whispering gallery mode sensor and analyzed its performance on refractive index variations detection
It has been shown that the selected instrument configuration provides the detection limit for the refractive index variations estimations of at least 4×10−5
Summary
Optical resonance in the dielectric circular microcavities referred to as the effect of whispering gallery modes (WGM) has drawn a great attention as a highly sensitive and label-free instrument for biochemical components detection[1,2,3,4]. Confinement and guiding of the optical ray along the microcavity’s periphery, which meets the resonance conditions when the returning light wave starts to interfere with itself, form a WGM that is characterized by high quality (Q)-factors[5,6]. The efficient light coupling into the cavity is realized via the evanescent field, where among others the prism-based method yields to the tapered fiber one (most widely employed) in efficiency, but excels in robustness and affordability[11]. The sensing mechanism of a WGM instrument is based on the response of the mode field to the variations in the ambient environment via the evanescent wave. Based on the nature of the external stimuli, one can distinguish between the monitoring of the resonance frequency shift
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