Performance of Classification Models of Toxins Based on Raman Spectroscopy Using Machine Learning Algorithms

Zhang, Pengjie; Liu, Bing; Mu, Xihui; Xu, Jiwei; Du, Bin; Wang, Jiang; Liu, Zhiwei; Tong, Zhaoyang

doi:10.3390/molecules29010197

Cited by 2 publications

(2 citation statements)

References 57 publications

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“…In the process of fluorescence hyperspectral data acquisition, due to the influence of environmental factors, there is a certain amount of noise in the acquired fluorescence hyperspectral data, which adversely affects the performance of the final modeling. Therefore, fluorescence hyperspectral data need to be preprocessed before modeling [22,24]. Figure 3 shows the fluorescence hyperspectral curves after MC, SG, SNV, and FD preprocessing.…”

Section: Fluorescence Hyperspectral Data Preprocessingmentioning

confidence: 99%

The Rapid Non-Destructive Differentiation of Different Varieties of Rice by Fluorescence Hyperspectral Technology Combined with Machine Learning

Kang,

Fan,

Zhan

et al. 2024

Molecules

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A rice classification method for the fast and non-destructive differentiation of different varieties is significant in research at present. In this study, fluorescence hyperspectral technology combined with machine learning techniques was used to distinguish five rice varieties by analyzing the fluorescence hyperspectral features of Thai jasmine rice and four rice varieties with a similar appearance to Thai jasmine rice in the wavelength range of 475–1000 nm. The fluorescence hyperspectral data were preprocessed by a first-order derivative (FD) to reduce the background and baseline drift effects of the rice samples. Then, a principal component analysis (PCA) and t-distributed stochastic neighborhood embedding (t-SNE) were used for feature reduction and 3D visualization display. A partial least squares discriminant analysis (PLS-DA), BP neural network (BP), and random forest (RF) were used to build the rice classification models. The RF classification model parameters were optimized using the gray wolf algorithm (GWO). The results show that FD-t-SNE-GWO-RF is the best model for rice classification, with accuracy values of 99.8% and 95.3% for the training and test sets, respectively. The fluorescence hyperspectral technique combined with machine learning is feasible for classifying rice varieties.

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Section: Fluorescence Hyperspectral Data Preprocessingmentioning

confidence: 99%

The Rapid Non-Destructive Differentiation of Different Varieties of Rice by Fluorescence Hyperspectral Technology Combined with Machine Learning

Kang,

Fan,

Zhan

et al. 2024

Molecules

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“…Li et al's [31] study utilised image-based modelling and deep learning to predict the mechanical properties of heterogeneous materials, highlighting the potential of deep learning to establish implicit mappings between macroscale and mesoscale structures, providing insights for material behaviour optimisation. Additionally, Zhang et al [32] explored the performance of classification models for toxins based on Raman spectroscopy using machine learning algorithms. Their study demonstrated the effectiveness of preprocessing methods and classification models in accurately identifying protein toxins, offering promising avenues for toxin detection and public health protection.…”

Section: Literature Reviewmentioning

confidence: 99%

Advancing Visible Spectroscopy through Integrated Machine Learning and Image Processing Techniques

Patra,

Kumari,

Barua

et al. 2024

Applied Sciences

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This research introduces an approach to visible spectroscopy leveraging image processing techniques and machine learning (ML) algorithms. The methodology involves calculating the hue value of an image and deriving the corresponding dominant wavelength. Initially, a six-degree polynomial regression supervised machine learning model is trained to establish a relationship between the hue values and dominant wavelengths. Subsequently, the ML model is employed to analyse the visible wavelengths emitted by various sources, including sodium vapour, neon lamps, mercury vapour, copper vapour lasers, and helium vapour. The performance of the proposed method is evaluated through error analysis, revealing remarkably low error percentages of 0.04%, 0.01%, 3.7%, 1%, and 0.07% for sodium vapour, neon lamp, copper vapour laser, and helium vapour, respectively. This approach offers a promising avenue for accurate and efficient visible spectroscopy, with potential applications in diverse fields such as material science, environmental monitoring, and biomedical research. This research presents a visible spectroscopy method harnessing image processing and machine learning algorithms. By calculating hue values and identifying dominant wavelengths, the approach demonstrates consistently low error rates across diverse light sources.

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Performance of Classification Models of Toxins Based on Raman Spectroscopy Using Machine Learning Algorithms

Cited by 2 publications

References 57 publications

The Rapid Non-Destructive Differentiation of Different Varieties of Rice by Fluorescence Hyperspectral Technology Combined with Machine Learning

The Rapid Non-Destructive Differentiation of Different Varieties of Rice by Fluorescence Hyperspectral Technology Combined with Machine Learning

Advancing Visible Spectroscopy through Integrated Machine Learning and Image Processing Techniques

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