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Auteurs principaux: Parand, Parisa, Samadpour, Mahmoud
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2512.15544
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author Parand, Parisa
Samadpour, Mahmoud
author_facet Parand, Parisa
Samadpour, Mahmoud
contents Hyperspectral optical imaging provides rich spectral information for estimating continuous environmental and material parameters; however, its high dimensionality and strong feature correlation pose significant challenges for machine learning models, especially when ground-truth datasets are limited. In this study, we investigate a hyperspectral dataset composed of 150 spectral bands with soil moisture as the target variable. To address the curse of dimensionality, Principal Component Analysis (PCA) was employed as a baseline dimensionality reduction technique. The optimal number of principal components was determined to be two, retaining more than 99% of the total variance. This selection was supported by the analysis of the covariance matrix, eigenvalue distribution, and the scree plot. Projecting the data onto the first two principal components enabled improved visualization and interpretability compared to the original high-dimensional feature space. The reduced representation also revealed a clearer separation of target values, effectively decreasing data complexity. To evaluate the impact of dimensionality reduction on predictive performance, a Random Forest regression model was trained to estimate soil moisture from the PCA-transformed data. The model achieved a coefficient of determination (R2) of 94.7 %, demonstrating that PCA-based feature reduction can enhance computational efficiency while preserving strong predictive capability in hyperspectral machine learning workflows.
format Preprint
id arxiv_https___arxiv_org_abs_2512_15544
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Assessing the Effect of PCA-Based Dimensionality Reduction on Machine Learning Performance in Hyperspectral Optical Imaging
Parand, Parisa
Samadpour, Mahmoud
Optics
Hyperspectral optical imaging provides rich spectral information for estimating continuous environmental and material parameters; however, its high dimensionality and strong feature correlation pose significant challenges for machine learning models, especially when ground-truth datasets are limited. In this study, we investigate a hyperspectral dataset composed of 150 spectral bands with soil moisture as the target variable. To address the curse of dimensionality, Principal Component Analysis (PCA) was employed as a baseline dimensionality reduction technique. The optimal number of principal components was determined to be two, retaining more than 99% of the total variance. This selection was supported by the analysis of the covariance matrix, eigenvalue distribution, and the scree plot. Projecting the data onto the first two principal components enabled improved visualization and interpretability compared to the original high-dimensional feature space. The reduced representation also revealed a clearer separation of target values, effectively decreasing data complexity. To evaluate the impact of dimensionality reduction on predictive performance, a Random Forest regression model was trained to estimate soil moisture from the PCA-transformed data. The model achieved a coefficient of determination (R2) of 94.7 %, demonstrating that PCA-based feature reduction can enhance computational efficiency while preserving strong predictive capability in hyperspectral machine learning workflows.
title Assessing the Effect of PCA-Based Dimensionality Reduction on Machine Learning Performance in Hyperspectral Optical Imaging
topic Optics
url https://arxiv.org/abs/2512.15544