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Effect of non-resonant background on the extraction of Raman signals from CARS spectra using deep neural networks

Rajendhar Junjuri, Ali Saghi, Lasse Lensu, Erik M. Vartiainen∥

2022RSC Advances17 citationsDOIOpen Access PDF

Abstract

(1) product of two sigmoids following the original SpecNet model, (2) Single Sigmoid, and (3) fourth-order polynomial function. Later, 50 000 CARS spectra were separately synthesized using each NRB type to train the CNN model and, after training, we tested its performance on 300 simulated test spectra. The results have shown that imaginary part extraction capability is superior for the model trained with Polynomial NRB, and the extracted line shapes are in good agreement with the ground truth. Moreover, correlation analysis was carried out to compare the retrieved Raman signals to real ones, and a higher correlation coefficient was obtained for the model trained with the Polynomial NRB (on average, ∼0.95 for 300 test spectra), whereas it was ∼0.89 for the other NRBs. Finally, the predictive capability is evaluated on three complex experimental CARS spectra (DMPC, ADP, and yeast), where the Polynomial NRB model performance is found to stand out from the rest. This approach has a strong potential to simplify the analysis of complex CARS spectroscopy and can be helpful in real-time microscopy imaging applications.

Topics & Concepts

Raman spectroscopyPolynomialSpectral lineSigmoid functionArtificial neural networkConvolutional neural networkCorrelation coefficientComputer scienceGround truthRaman scatteringBiological systemArtificial intelligencePattern recognition (psychology)Materials scienceMathematicsPhysicsOpticsMathematical analysisMachine learningBiologyAstronomySpectroscopy Techniques in Biomedical and Chemical ResearchSpectroscopy and Chemometric AnalysesLaser-induced spectroscopy and plasma
Effect of non-resonant background on the extraction of Raman signals from CARS spectra using deep neural networks | Litcius