A Semiautomatic Pixel-Object Method for Detecting Landslides Using Multitemporal ALOS-2 Intensity Images

Adriano, Bruno; Yokoya, Naoto; Miura, Hiroyuki; Matsuoka, M.; Koshimura, Shunichi

doi:10.3390/rs12030561

Cited by 26 publications

(8 citation statements)

References 56 publications

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“…Landslide detection using SAR intensity imagery is an alternative to optical image-based approaches in adverse weather conditions. However, its accuracy is limited by the presence of layovers and shadowing, particularly for narrow debris flows [19]- [22]. Interferometric SAR has been demonstrated to be advantageous in detecting large-scale, slowly moving landslides [23].…”

Section: A Flood and Landslide Mapping Via Remote Sensingmentioning

confidence: 99%

Breaking Limits of Remote Sensing by Deep Learning From Simulated Data for Flood and Debris-Flow Mapping

Yokoya

Yamanoi

et al. 2022

IEEE Trans. Geosci. Remote Sensing

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We propose a framework that estimates the inundation depth (maximum water level) and debris-flow-induced topographic deformation from remote sensing imagery by integrating deep learning and numerical simulation. A water and debris-flow simulator generates training data for various artificial disaster scenarios. We show that regression models based on Attention U-Net and LinkNet architectures trained on such synthetic data can predict the maximum water level and topographic deformation from a remote sensing-derived change detection map and a digital elevation model. The proposed framework has an inpainting capability, thus mitigating the false negatives that are inevitable in remote sensing image analysis. Our framework breaks limits of remote sensing and enables rapid estimation of inundation depth and topographic deformation, essential information for emergency response, including rescue and relief activities. We conduct experiments with both synthetic and real data for two disaster events that caused simultaneous flooding and debris flows and demonstrate the effectiveness of our approach quantitatively and qualitatively. Our code and data sets are available at https://github.com/nyokoya/dlsim.

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Section: A Flood and Landslide Mapping Via Remote Sensingmentioning

confidence: 99%

Breaking Limits of Remote Sensing by Deep Learning From Simulated Data for Flood and Debris-Flow Mapping

Yokoya

Yamanoi

et al. 2022

IEEE Trans. Geosci. Remote Sensing

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“…The study area is located in the southwest of the Hokkaido region ( Figure 1A). The dominant land cover of the study area consists of forests and paddy fields and has a rugged, mountainous, and high slope topography (Zhang et al, 2019;Adriano et al, 2020). Hokkaido, which includes the study area, is a tectonically active region in the world.…”

Section: Study Areamentioning

confidence: 99%

“…Active and passive remote sensing systems offer great advantages in rapid landslide mapping (Aimaiti et al, 2019). With remote sensing systems, Optical images (Zhao et al, 2017;Shao et al, 2019), synthetic aperture radar (SAR) (Aimaiti et al, 2019;Adriano et al, 2020), LIDAR systems (Liu et al, 2019), Unmanned Aerial Vehicle (UAV) systems (Comert et al, 2019) or synthesis of optical and SAR images (Shirvani et al, 2019) can be used in the landslide mapping. The most common method preferred in mapping landslides is visual image interpretation (Guzzetti et al, 2012;Rosi et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Effect of the Dataset Size and Type in the Earthquake-Triggered Landslides Mapping: A Case Study for the 2018 Hokkaido Iburu Landslides

Çömert

2021

Front. Earth Sci.

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Rapid mapping of landslides that occur after an earthquake is important for rapid crisis management. In this study, experimental research was conducted on the size of the model area and the data types used in developing classifiers for the supervised classification approaches used in rapid landslide mapping. The Hokkaido Iburu earthquake zone that occurred on September 6, 2018, was selected as the study area. PlanetScope pre-event and post-event images and ALOS-PALSAR Digital Elevation Model (DEM) were used in the analysis processes. In this context, five model areas with different sizes and one test area were determined. Object-based image analysis (OBIA) was used as a landslide mapping approach. Random Forest classifier, which is a supervised classification algorithm, was performed in the mapping of image objects produced by the segmentation stage of OBIA. Two different data sets were created for landslide mapping: change-based dataset and post-event dataset. The change-based dataset is generated from change data such as the difference of normalized difference vegetation index (δNDVI), change detection Image (CDI), princiable component analysis (PCA), and Independent component analysis (ICA) which are used in change detection applications. The post-event dataset was created from data generated from post-event image bands. When the obtained results were examined, higher accuracy results were obtained with the post-event dataset. Increasing the size of the model area, in other words, increasing the training data slightly increases the accuracy of landslide mapping. However, a model area that represents the region to be mapped in small sizes to make rapid decisions provides a 94% F-measure accuracy for earthquake-triggered landslide detection.

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“…Landslide detection using SAR intensity imagery is an alternative to optical image-based approaches in adverse weather conditions. But its accuracy is limited by the presence of layovers and shadowing particularly for narrow debris flows [19]- [22]. Interferometric SAR has been demonstrated to be advantageous in detecting large-scale, slowly moving landslides [23].…”

Section: Related Work a Flood And Landslide Mapping Via Remote Sensingmentioning

confidence: 99%

Breaking the Limits of Remote Sensing by Simulation and Deep Learning for Flood and Debris Flow Mapping

Yokoya,

Yamanoi,

et al. 2020

Preprint

Self Cite

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We propose a framework that estimates inundation depth (maximum water level) and debris-flow-induced topographic deformation from remote sensing imagery by integrating deep learning and numerical simulation. A water and debris flow simulator generates training data for various artificial disaster scenarios. We show that regression models based on Attention U-Net and LinkNet architectures trained on such synthetic data can predict the maximum water level and topographic deformation from a remote sensing-derived change detection map and a digital elevation model. The proposed framework has an inpainting capability, thus mitigating the false negatives that are inevitable in remote sensing image analysis. Our framework breaks the limits of remote sensing and enables rapid estimation of inundation depth and topographic deformation, essential information for emergency response, including rescue and relief activities. We conduct experiments with both synthetic and real data for two disaster events that caused simultaneous flooding and debris flows and demonstrate the effectiveness of our approach quantitatively and qualitatively.

show abstract

A Semiautomatic Pixel-Object Method for Detecting Landslides Using Multitemporal ALOS-2 Intensity Images

Cited by 26 publications

References 56 publications

Breaking Limits of Remote Sensing by Deep Learning From Simulated Data for Flood and Debris-Flow Mapping

Breaking Limits of Remote Sensing by Deep Learning From Simulated Data for Flood and Debris-Flow Mapping

Investigation of the Effect of the Dataset Size and Type in the Earthquake-Triggered Landslides Mapping: A Case Study for the 2018 Hokkaido Iburu Landslides

Breaking the Limits of Remote Sensing by Simulation and Deep Learning for Flood and Debris Flow Mapping

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