Abstract
Remote sensing technology in recent years has been regarded the most important source to provide substantial information for delineating the flooding extent to the disaster management authority. There have been numerous studies proposing mathematical or statistical classification models for flood mapping. However, conventional pixel-wise classifications methods rely on the exact match of the spectral signature to label the target pixel. In this study, we propose a fully convolutional neural networks (F-CNNs) classification model to map the flooding extent from Landsat satellite images. We utilised the spatial information from the neighbouring area of target pixel in classification. A total of 64 different models were generated and trained with a variable neighbourhood size of training samples and number of learnable filters. The training results revealed that the model trained with 3 × 3 neighbourhood sized training samples and with 32 convolutional filters achieved the best performance out of the experiments. A new set of different Landsat images covering flooded areas across Australia were used to evaluate the classification performance of the model. A comparison of our proposed classification model to the conventional support vector machines (SVM) classification model shows that the F-CNNs model was able to detect flooded areas more efficiently than the SVM classification model. For example, the F-CNNs model achieved a maximum precision rate (true positives) of 76.7% compared to 45.27% for SVM classification.
Highlights
Every year, flood incidents are accountable for huge impacts on social well being and economic infrastructure all over the world
The fully convolutional neural networks (F-convolutional neural networks (CNNs)) model does not able to achieve more than 70% overall accuracy level for every classification tasks, but it is clear from the results that the model is able to distinguish flood water from permanent-water features that the support vector machines (SVM) classification method is not able to obtain as we observed in Figures 9(D-2) and 9(D-6)
This study presents a novel approach of using neighbourhood information of pixel spectral properties into an advanced machine learning model with optimal architectural design for mapping the flooding extent from multispectral Landsat images
Summary
Flood incidents are accountable for huge impacts on social well being and economic infrastructure all over the world. Mapping flooding extent during a flood event has become a key tool needed to assist various private and government disaster management departments (local and state government emergency departments, and environmental groups) in mitigating, responding to and recovering from flood disasters [1,2,3] These organizations seek different types of quantitative and qualitative information, their primary requirement is rapid acquisition of maps showing the extent of flood affected areas to plan relief work efficiently. With advancements in airborne technology, it is possible to conduct an aerial survey of extensive flooded areas for ground truth collection as we have observed in the studies by Damian Ortega-Terol et al [5] where the authors proposed a low-cost aircraft-based survey that can help in classification for detection of large woody debris along a segment of Jucar River in Spain. With the advancement in on-board space-borne sensors, it has been possible to acquire flood data over large geographical areas from satellite images [2]
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