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EvaNet: Elevation-Guided Flood Extent Mapping on Earth Imagery (Extended Version)

Mirza Tanzim Sami, Da Yan, Saugat Adhikari, Lyuheng Yuan, Jiao Han, Zhe Jiang, Jalal Khalil, Yang Zhou

Abstract

Accurate and timely mapping of flood extent from high-resolution satellite imagery plays a crucial role in disaster management such as damage assessment and relief activities. However, current state-of-the-art solutions are based on U-Net, which can-not segment the flood pixels accurately due to the ambiguous pixels (e.g., tree canopies, clouds) that prevent a direct judgement from only the spectral features. Thanks to the digital elevation model (DEM) data readily available from sources such as United States Geological Survey (USGS), this work explores the use of an elevation map to improve flood extent mapping. We propose, EvaNet, an elevation-guided segmentation model based on the encoder-decoder architecture with two novel techniques: (1) a loss function encoding the physical law of gravity that if a location is flooded (resp. dry), then its adjacent locations with a lower (resp. higher) elevation must also be flooded (resp. dry); (2) a new (de)convolution operation that integrates the elevation map by a location sensitive gating mechanism to regulate how much spectral features flow through adjacent layers. Extensive experiments show that EvaNet significantly outperforms the U-Net baselines, and works as a perfect drop-in replacement for U-Net in existing solutions to flood extent mapping.

EvaNet: Elevation-Guided Flood Extent Mapping on Earth Imagery (Extended Version)

Abstract

Accurate and timely mapping of flood extent from high-resolution satellite imagery plays a crucial role in disaster management such as damage assessment and relief activities. However, current state-of-the-art solutions are based on U-Net, which can-not segment the flood pixels accurately due to the ambiguous pixels (e.g., tree canopies, clouds) that prevent a direct judgement from only the spectral features. Thanks to the digital elevation model (DEM) data readily available from sources such as United States Geological Survey (USGS), this work explores the use of an elevation map to improve flood extent mapping. We propose, EvaNet, an elevation-guided segmentation model based on the encoder-decoder architecture with two novel techniques: (1) a loss function encoding the physical law of gravity that if a location is flooded (resp. dry), then its adjacent locations with a lower (resp. higher) elevation must also be flooded (resp. dry); (2) a new (de)convolution operation that integrates the elevation map by a location sensitive gating mechanism to regulate how much spectral features flow through adjacent layers. Extensive experiments show that EvaNet significantly outperforms the U-Net baselines, and works as a perfect drop-in replacement for U-Net in existing solutions to flood extent mapping.
Paper Structure (15 sections, 10 equations, 7 figures, 12 tables)

This paper contains 15 sections, 10 equations, 7 figures, 12 tables.

Table of Contents

  1. Introduction
  2. Related Work
  3. Method
  4. Elevation-Guided Loss
  5. Elevation-Regulated Convolutions
  6. Experiments & Results
  7. Conclusion
  8. Appendix
  9. Related Work on KGML
  10. Distribution of Pixel-Pair Cases
  11. Input Data Visualization
  12. Model Setting Tuning
  13. Effectiveness of Normal-Time Imagery
  14. Ablation Study with FCN-8s
  15. Effect as a U-Net Drop-in Replacement

Figures (7)

  • Figure 1: Physical law of gravity: if pixel $A$ is dry, then its higher adjacent pixel $B$ must be dry; while if pixel $D$ is flooded, then its lower adjacent pixel $E$ must be flooded.
  • Figure 2: EvaNet architecture overview.
  • Figure 3: Five cases for pixel-pair $(\mathbf{p}, \mathbf{p}_n)$.
  • Figure 4: EvaNet encoder-decoder network architecture.
  • Figure 5: Histograms of the five cases.
  • ...and 2 more figures