Flood Mapping and Damage Analysis Using Multispectral Sentinel-2 Satellite Imagery and Machine Learning Techniques

Q3 Computer Science

Recent Advances in Computer Science and Communications Pub Date : 2024-07-15 DOI:10.2174/0126662558309143240529104953

Rashmi Saini, Shivam Rawat, Suraj Singh, Prabhakar Semwal

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引用次数: 0

Abstract

Floods are among the deadliest natural calamities, devastating ecosystems and human lives worldwide. In India, Bihar is a state grappling with economic hardships and faces severe agricultural devastation due to recurring floods, destroying crops and natural resources, which significantly impacts local farmers. This research addresses the critical need to deeply understand the flood dynamics of selected study areas. This research presents a case study that focuses on leveraging Remote Sensing tools and Machine Learning techniques for comprehensive flood mapping and damage analysis in Gopalganj District, Bihar, India, using remote sensing data. More specifically, this research presents three major objectives: (i) Flood damage mapping and change analysis before and after the flood using the Sentinel-2 satellite dataset, (ii) Evaluation of the impact of integrating spectral indices on the accuracy of classification, (iii) Identification of most robust predictor spectral indices for the classification. The Sentinel-2 satellite dataset encompasses 13 bands with resolutions of 10m, 20m, and 60m. Here, four spectral bands (NIR, Red, Green, and Blue) with the finest resolution of 10m have been selected for this study. These bands are integrated with four spectral indices, namely Normalized Difference Water Index (NDWI), MNDWI (Modified NDWI), Normalized Difference Vegetation Index (NDVI), and Soil Adjusted Vegetation Index (SAVI). Two ML classifiers, namely Support Vector Machine (SVM) and Random Forest (RF) have been employed for pixel-based supervised classification. Results have shown that RF outperformed and worked well in extracting water bodies and flood-damaged areas effectively. The results demonstrated that RF obtained (Overall Accuracy (OA)= 89.54% and kappa value (ka) = 0.872) and SVM reported (OA= 87.69%, ka= 0.849) for pre-crisis data, whereas, for post-crisis, RF reported (OA=91.54%, ka = 0.897), SVM reported (OA= 89.77%, ka= 0.875). It was reported that the integration of spectral indices improved the OA by +3.41% and +2.86% using RF and SVM, respectively. The results of this study demonstrated that the waterbody area increased from 12.72 to 88.23 km2, as shown by the RF classifier. The variable importance computation results indicated that MNDWI is the most important predictor variable, followed by NDWI. This study recommends the use of these two predictor variables for flood mapping.

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利用多光谱哨兵-2 卫星图像和机器学习技术进行洪水测绘和损害分析

洪水是最致命的自然灾害之一，在全球范围内对生态系统和人类生活造成了严重破坏。在印度，比哈尔邦是一个经济困难的邦，由于洪水频发，农业面临严重破坏，农作物和自然资源被毁，给当地农民造成了巨大影响。本研究针对深入了解选定研究地区洪水动态的迫切需要，提出了一个案例研究，重点是利用遥感数据，利用遥感工具和机器学习技术，在印度比哈尔邦戈帕尔甘杰区进行全面的洪水绘图和损害分析。更具体地说，这项研究有三个主要目标：(i) 利用哨兵-2 号卫星数据集绘制洪水损失图并分析洪水前后的变化；(ii) 评估综合光谱指数对分类准确性的影响；(iii) 识别最稳健的预测光谱指数用于分类。本研究选择了分辨率最高为 10 米的四个光谱波段（近红外、红、绿和蓝）。这些波段与四个光谱指数进行了整合，即归一化差异水指数（NDWI）、MNDWI（修正的归一化差异水指数）、归一化差异植被指数（NDVI）和土壤调整植被指数（SAVI）。结果表明，RF 在有效提取水体和洪水灾区方面表现出色，效果良好。结果表明，对于危机前的数据，RF 获得了（总体准确率 (OA)= 89.54%，kappa 值 (ka) = 0.872），SVM 报告了（OA= 87.69%，ka=0.849），而对于危机后的数据，RF 报告了（OA=91.据报告，使用 RF 和 SVM 将光谱指数整合后，OA 分别提高了+3.41%和+2.86%。研究结果表明，RF 分类器可将水体面积从 12.72 平方公里增加到 88.23 平方公里。变量重要性计算结果表明，MNDWI 是最重要的预测变量，其次是 NDWI。本研究建议在洪水测绘中使用这两个预测变量。

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来源期刊

Recent Advances in Computer Science and Communications Computer Science-Computer Science (all)

CiteScore

2.50

自引率

0.00%

发文量

142