Classification of soil horizons based on VisNIR and SWIR hyperespectral images and machine learning models

IF 3.8 Q2 ENVIRONMENTAL SCIENCES

Remote Sensing Applications-Society and Environment Pub Date : 2024-09-26 DOI:10.1016/j.rsase.2024.101362

Karym Mayara de Oliveira , João Vitor Ferreira Gonçalves , Renan Falcioni , Caio Almeida de Oliveira , Daiane de Fatima da Silva Haubert , Weslei Augusto Mendonça , Luís Guilherme Teixeira Crusiol , Roney Berti de Oliveira , Amanda Silveira Reis , Everson Cezar , Marcos Rafael Nanni

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引用次数: 0

Abstract

The use of spectral signature to classify soil horizons and orders is becoming increasingly popular in the field of geotechnology. With the introduction of precise sensors and robust models for obtain data and classifying attributes, the traditional surveys can be improved with a computational analytical approach. Despite the benefits, few authors have addressed the classification of soil horizons given the budget and time-consuming required to obtain and analyze data. This study aimed to assess the efficiency of combining soil spectral reflectance (obtained by two hyperspectral imaging sensors) with robust ML (machine learning) models for classifying soil horizons. Six monoliths were collected from soil profiles located in the central northern region of Parana State, Brazil. The monoliths were scanned by VIS-NIR and SWIR hyperspectral cameras in the laboratory. Spectral signatures were obtained and explored by principal component analysis (PCA). The spectral data were subdivided into training (70%) and test (30%) sets and subjected to the random forest (RF), support vector machine (SVM), and K-nearest neighbors (KNN) methods for the classification of soil horizons. The overall accuracy, F1-score, and confusion matrix were used to verify the performance of the models. There was a significant influence of particle size and soil organic carbon on the spectral signature of the soils. Despite the data overlap between adjacent horizons observed in the PCA, the machine learning models were able to classify the horizons with promising accuracy and PCA explained the dataset with a percentage above 98%. For VIS-NIR spectra, the accuracies varied between 81.4% (KNN) and 89.9% (RF), and the F1-scores varied between 51.9% (SVM) and 78.3% (RF). For the SWIR spectra, the variation in accuracy was between 72.1% (SVM) and 86.5% (RF), but the variation in the F1-score was between 61.9% (SVM) and 85.4% (RF). These results demonstrate the promising potential of using hyperspectral imaging and machine learning models combined with traditional soil classification methods as tools.

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基于可见近红外和 SWIR 高光谱图像及机器学习模型的土壤层分类

利用光谱特征对土壤层和阶次进行分类在地质技术领域越来越受欢迎。随着用于获取数据和属性分类的精确传感器和强大模型的引入，传统的勘测方法可以通过计算分析方法得到改进。尽管有这些优势，但由于获取和分析数据所需的预算和时间，很少有学者研究土壤层的分类问题。本研究旨在评估将土壤光谱反射率（由两个高光谱成像传感器获得）与鲁棒性 ML（机器学习）模型相结合，对土壤层进行分类的效率。研究人员从位于巴西巴拉那州中北部地区的土壤剖面上采集了六块单体。在实验室中使用 VIS-NIR 和 SWIR 高光谱照相机对这些单片进行了扫描。通过主成分分析 (PCA) 获得并探索了光谱特征。光谱数据被细分为训练集（70%）和测试集（30%），并采用随机森林（RF）、支持向量机（SVM）和 K-近邻（KNN）方法对土壤层进行分类。总体准确率、F1 分数和混淆矩阵用于验证模型的性能。粒度和土壤有机碳对土壤的光谱特征有显著影响。尽管在 PCA 中观察到相邻地层之间存在数据重叠，但机器学习模型仍能对地层进行分类，而且准确率很高，PCA 对数据集的解释率超过 98%。对于可见光-近红外光谱，准确率介于 81.4%（KNN）和 89.9%（RF）之间，F1 分数介于 51.9%（SVM）和 78.3%（RF）之间。对于 SWIR 光谱，准确率的变化在 72.1%（SVM）和 86.5%（RF）之间，但 F1 分数的变化在 61.9%（SVM）和 85.4%（RF）之间。这些结果表明，将高光谱成像和机器学习模型与传统的土壤分类方法相结合作为工具，具有广阔的应用前景。

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来源期刊

Remote Sensing Applications-Society and Environment Multiple-

CiteScore

8.00

自引率

8.50%

发文量

204

审稿时长

65 days

期刊介绍： The journal ''Remote Sensing Applications: Society and Environment'' (RSASE) focuses on remote sensing studies that address specific topics with an emphasis on environmental and societal issues - regional / local studies with global significance. Subjects are encouraged to have an interdisciplinary approach and include, but are not limited by: " -Global and climate change studies addressing the impact of increasing concentrations of greenhouse gases, CO2 emission, carbon balance and carbon mitigation, energy system on social and environmental systems -Ecological and environmental issues including biodiversity, ecosystem dynamics, land degradation, atmospheric and water pollution, urban footprint, ecosystem management and natural hazards (e.g. earthquakes, typhoons, floods, landslides) -Natural resource studies including land-use in general, biomass estimation, forests, agricultural land, plantation, soils, coral reefs, wetland and water resources -Agriculture, food production systems and food security outcomes -Socio-economic issues including urban systems, urban growth, public health, epidemics, land-use transition and land use conflicts -Oceanography and coastal zone studies, including sea level rise projections, coastlines changes and the ocean-land interface -Regional challenges for remote sensing application techniques, monitoring and analysis, such as cloud screening and atmospheric correction for tropical regions -Interdisciplinary studies combining remote sensing, household survey data, field measurements and models to address environmental, societal and sustainability issues -Quantitative and qualitative analysis that documents the impact of using remote sensing studies in social, political, environmental or economic systems