Transferability of Convolutional Neural Network Models for Identifying Damaged Buildings Due to Earthquake

Yang, Wanting; Zhang, Xianfeng; Luo, Peng

doi:10.3390/rs13030504

Cited by 44 publications

(27 citation statements)

References 52 publications

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“…The works [29,41] concerned with developing methodologies to infer new disasters used model architectures similar to the ones described in the previous paragraph. Other studies extrapolated to different disasters types [32,42,43,44,45]. In many of these cases, transferability is dependent on the similarity between to the train and test regions [29] and is usually degraded by data heterogeneity [29,44].…”

Section: Cross-domain Transfer For Disaster Damage Detectionmentioning

confidence: 99%

“…Other studies extrapolated to different disasters types [32,42,43,44,45]. In many of these cases, transferability is dependent on the similarity between to the train and test regions [29] and is usually degraded by data heterogeneity [29,44]. Other solutions proposed including a small number of test samples with the training data [41,44], a multi-domain adaptive batch normalization and a stochastic weight averaging [42].…”

Section: Cross-domain Transfer For Disaster Damage Detectionmentioning

confidence: 99%

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BLDNet: A Semi-supervised Change Detection Building Damage Framework using Graph Convolutional Networks and Urban Domain Knowledge

Ismail¹,

Awad²

2022

Preprint

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Change detection is instrumental to localize damage and understand destruction in disaster informatics. While convolutional neural networks are at the core of recent change detection solutions, we present in this work, BLDNet, a novel graph formulation for building damage change detection and enable learning relationships and representations from both local patterns and non-stationary neighborhoods. More specifically, we use graph convolutional networks to efficiently learn these features in a semisupervised framework with few annotated data. Additionally, BLDNet formulation allows for the injection of additional contextual building meta-features. We train and benchmark on the xBD dataset to validate the effectiveness of our approach. We also demonstrate on urban data from the 2020 Beirut Port Explosion that performance is improved by incorporating domain knowledge building meta-features.

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Section: Cross-domain Transfer For Disaster Damage Detectionmentioning

confidence: 99%

Section: Cross-domain Transfer For Disaster Damage Detectionmentioning

confidence: 99%

BLDNet: A Semi-supervised Change Detection Building Damage Framework using Graph Convolutional Networks and Urban Domain Knowledge

Ismail¹,

Awad²

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…e initial system consisted of 17 initial evaluation indicators, which were revised and improved following interviews and surveys with experts. Finally, we created a comprehensive vulnerability assessment index for urban seismic activity (Table 1) consisting of 13 evaluation indicators in the four criteria categories of building vulnerability, secondary disaster risk, socioeconomic vulnerability, and urban emergency response capabilities [45][46][47][48][49]. e vulnerability of buildings is largely a reflection of a city's exposure to earthquakes.…”

Section: Calculation Stepsmentioning

confidence: 99%

A Hybrid Intelligent Model for Urban Seismic Risk Assessment from the Perspective of Possibility and Vulnerability Based on Particle Swarm Optimization

Chu

Zhang

et al. 2021

Scientific Programming

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Assessing seismic risk is an essential element of urban risk management and urban spatial security work. In response to the issues posed by the complexity and openness of urban systems, the nonlinearity of driving factors, and sudden changes in geological processes that affect urban seismic research, this paper is based on a variety of intelligent algorithms to develop a hybrid intelligent model that integrates probability and vulnerability to evaluate and quantify the difference in the urban spatial units distribution of earthquake risk. We applied this model to Hefei, one of the few superlarge provincial capital cities on the “Tancheng-Lujiang” fault zone, one of the four major earthquake zones in China, which suffers frequent earthquakes. Our method combined the genetic algorithm (GA), particle swarm optimization (PSO), and backpropagation neural network methods (BP) to automatically calculate rules from inputted data on known seismic events and predict the probability of seismic events in unknown areas. Then, based on the analytic hierarchy process (AHP), spatial appraisal and valuation of environment and ecosystems method (SAVEE), and EMYCIN model, an urban seismic vulnerability was evaluated from the four perspectives of buildings, risk of secondary disasters, socioeconomic conditions, and urban emergency response capabilities. In the next step, the overall urban seismic risk was obtained by standardizing and superimposing seismic probability and vulnerability. Using the hybrid intelligent model, earthquake probability, seismic vulnerability, and overall seismic risk were obtained for Hefei, and the spatial characteristics of its overall seismic risk were examined. This study concludes that areas with very high, high, low, and very low earthquake risk in Hefei account for 8.10%, 31.90%, 40.94%, and 19.06% of its total area, respectively. Areas with very high earthquake risk are concentrated in the old city, the government affairs district, Science City, and Xinzhan District. This study concludes that government authorities of Hefei should target earthquake safety measures consisting of basic earthquake mitigation measures and pre- and postearthquake emergency measures. In the face of regional disasters such as earthquakes, coordinating and governing should be strengthened between cities and regions.

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“…At present, with the development of big data and deep learning technologies, convolutional neural networks (CNN) are widely used in mapping ice-wedge polygon (IWP) [5,6], identifying damaged buildings [7], classifying sea ice cover and land type [8][9][10], and so on.…”

Section: Introductionmentioning

confidence: 99%

Ship Detection and Feature Visualization Analysis Based on Lightweight CNN in VH and VV Polarization Images

Geng

Shi

et al. 2021

Remote Sensing

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Synthetic aperture radar (SAR) is a significant application in maritime monitoring, which can provide SAR data throughout the day and in all weather conditions. With the development of artificial intelligence and big data technologies, the data-driven convolutional neural network (CNN) has become widely used in ship detection. However, the accuracy, feature visualization, and analysis of ship detection need to be improved further, when the CNN method is used. In this letter, we propose a two-stage ship detection for land-contained sea area without a traditional sea-land segmentation process. First, to decrease the possibly existing false alarms from the island, an island filter is used as the first step, and then threshold segmentation is used to quickly perform candidate detection. Second, a two-layer lightweight CNN model-based classifier is built to separate false alarms from the ship object. Finally, we discuss the CNN interpretation and visualize in detail when the ship is predicted in vertical–horizontal (VH) and vertical–vertical (VV) polarization. Experiments demonstrate that the proposed method can reach an accuracy of 99.4% and an F1 score of 0.99 based on the Sentinel-1 images for a ship with a size of less than 32 × 32.

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Transferability of Convolutional Neural Network Models for Identifying Damaged Buildings Due to Earthquake

Cited by 44 publications

References 52 publications

BLDNet: A Semi-supervised Change Detection Building Damage Framework using Graph Convolutional Networks and Urban Domain Knowledge

BLDNet: A Semi-supervised Change Detection Building Damage Framework using Graph Convolutional Networks and Urban Domain Knowledge

A Hybrid Intelligent Model for Urban Seismic Risk Assessment from the Perspective of Possibility and Vulnerability Based on Particle Swarm Optimization

Ship Detection and Feature Visualization Analysis Based on Lightweight CNN in VH and VV Polarization Images

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