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Papers/A Practical Noise2Noise Denoising Pipeline for High-Throughput Raman Spectroscopy
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A Practical Noise2Noise Denoising Pipeline for High-Throughput Raman Spectroscopy

May 18, 2026

arXiv
Abstract

A lightweight and reproducible denoising pipeline for high-throughput Raman spectroscopy is presented. The approach relies on a one-dimensional convolutional autoencoder trained using a Noise2Noise strategy, requiring neither external spectral libraries nor high signal-to-noise reference spectra for training. From a reduced training subset composed of repeated short-exposure acquisitions, the model learns to reconstruct Raman spectra while efficiently suppressing stochastic noise. The method is evaluated on a heterogeneous mineral sample, using both quantitative spectral fidelity metrics (RMSE, SNR, SSIM) and task-oriented criteria based on unsupervised K-means classification. Results demonstrate that integration times as short as 5 ms per spectrum, which are typically insufficient for reliable interpretation, yield denoised spectra with high fidelity to the reference data while preserving chemically coherent maps. This work provides a practical trade-off between spectral quality and acquisition speed, enabling fast, adaptable Raman workflows compatible with routine laboratory use. It also offers a transferable framework for other one-dimensional spectroscopic modalities.

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Authors
David Martin-Calle, Cesar Alvarez Llamas, Vincent Motto- Ros, Christophe Dujardin, Jérémie Margueritat, David Rodney
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arXiv:2605.18511