Deep Learning for Raman Spectroscopy: : A Review

GND
1305980743
Affiliation
Institute of Physical Chemistry, Friedrich Schiller University Jena
Luo, Ruihao;
GND
131701819
Affiliation
Institute of Physical Chemistry, Friedrich Schiller University Jena
Popp, Juergen;
GND
101788207X
ORCID
0000-0003-2778-6624
Affiliation
Institute of Physical Chemistry, Friedrich Schiller University Jena
Bocklitz, Thomas

Raman spectroscopy (RS) is a spectroscopic method which indirectly measures the vibrational states within samples. This information on vibrational states can be utilized as spectroscopic fingerprints of the sample, which, subsequently, can be used in a wide range of application scenarios to determine the chemical composition of the sample without altering it, or to predict a sample property, such as the disease state of patients. These two examples are only a small portion of the application scenarios, which range from biomedical diagnostics to material science questions. However, the Raman signal is weak and due to the label-free character of RS, the Raman data is untargeted. Therefore, the analysis of Raman spectra is challenging and machine learning based chemometric models are needed. As a subset of representation learning algorithms, deep learning (DL) has had great success in data science for the analysis of Raman spectra and photonic data in general. In this review, recent developments of DL algorithms for Raman spectroscopy and the current challenges in the application of these algorithms will be discussed.

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