Developing Robust Flood Susceptibility Model with Small Numbers of Parameters in Highly Fertile Regions of Northwest Bangladesh for Sustainable Flood and Agriculture Management

Developing Robust Flood Susceptibility Model with Small Numbers of Parameters in Highly Fertile Regions of Northwest Bangladesh for Sustainable Flood and Agriculture Management

The present study intends to improve the robustness of a flood susceptibility (FS) model with a small number of parameters in data-scarce areas, such as northwest Bangladesh, by employing machine learning-based sensitivity analysis and an analytical hierarchy process (AHP). In this study, the nine m...

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Veröffentlicht in:Sustainability 2022-04, Vol.14 (7), p.3982
Hauptverfasser: Sarkar, Showmitra Kumar, Ansar, Saifullah Bin, Ekram, Khondaker Mohammed Mohiuddin, Khan, Mehedi Hasan, Talukdar, Swapan, Naikoo, Mohd Waseem, Islam, Abu Reza Towfiqul, Rahman, Atiqur, Mosavi, Amir
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Sprache:eng
Schlagworte:
Agricultural management
Catastrophes
Data science
Decision making
Drainage density
Flood control
Flood management
Floods
Hydrology
Land cover
Land use
Mapping
Neural networks
Parameter sensitivity
Rainfall
Rivers
Sensitivity analysis
Soils
Storm damage
Topography
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container_end_page
container_issue 7
container_start_page 3982
container_title Sustainability
container_volume 14
creator Sarkar, Showmitra Kumar
Ansar, Saifullah Bin
Ekram, Khondaker Mohammed Mohiuddin
Khan, Mehedi Hasan
Talukdar, Swapan
Naikoo, Mohd Waseem
Islam, Abu Reza Towfiqul
Rahman, Atiqur
Mosavi, Amir
description The present study intends to improve the robustness of a flood susceptibility (FS) model with a small number of parameters in data-scarce areas, such as northwest Bangladesh, by employing machine learning-based sensitivity analysis and an analytical hierarchy process (AHP). In this study, the nine most relevant flood elements (such as distance from the river, rainfall, and drainage density) were chosen as flood conditioning variables for modeling. The FS model was produced using AHP technique. We used an empirical and binormal receiver operating characteristic (ROC) curves for validating the models. We performed Sensitivity analyses using a random forest (RF)-based mean Gini decline (MGD), mean decrease accuracy (MDA), and information gain ratio to find out the sensitive flood conditioning variables. After performing sensitivity analysis, the least sensitivity variables were eliminated. We re-ran the model with the rest of the parameters to enhance the model’s performance. Based on previous studies and the AHP weighting approach, the general soil type, rainfall, distance from river/canal (Dr), and land use/land cover (LULC) had higher factor weights of 0.22, 0.21, 0.19, and 0.15, respectively. The FS model without sensitivity and with sensitivity performed well in the present study. According to the RF-based sensitivity and information gain ratio, the most sensitive factors were rainfall, soil type, slope, and elevation, while curvature and drainage density were less sensitive parameters, which were excluded in re-running the FS model with just vital parameters. Using empirical and binormal ROC curves, the new FS model yields higher AUCs of 0.835 and 0.822, respectively. It is discovered that the predicted model’s robustness may be maintained or increased by removing less relevant factors. This study will aid decision-makers in developing flood management plans for the examined region.
doi_str_mv 10.3390/su14073982
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The FS model without sensitivity and with sensitivity performed well in the present study. According to the RF-based sensitivity and information gain ratio, the most sensitive factors were rainfall, soil type, slope, and elevation, while curvature and drainage density were less sensitive parameters, which were excluded in re-running the FS model with just vital parameters. Using empirical and binormal ROC curves, the new FS model yields higher AUCs of 0.835 and 0.822, respectively. It is discovered that the predicted model’s robustness may be maintained or increased by removing less relevant factors. 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subjects Agricultural management
Catastrophes
Data science
Decision making
Drainage density
Flood control
Flood management
Floods
Hydrology
Land cover
Land use
Mapping
Neural networks
Parameter sensitivity
Rainfall
Rivers
Sensitivity analysis
Soils
Storm damage
Topography
title Developing Robust Flood Susceptibility Model with Small Numbers of Parameters in Highly Fertile Regions of Northwest Bangladesh for Sustainable Flood and Agriculture Management
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