Abstract
In recent years, remote-sensing (RS) technologies have been used together with image processing and traditional techniques in various disaster-related works. Among these is detecting building damage from orthophoto imagery that was inflicted by earthquakes. Automatic and visual techniques are considered as typical methods to produce building damage maps using RS images. The visual technique, however, is time-consuming due to manual sampling. The automatic method is able to detect the damaged building by extracting the defect features. However, various design methods and widely changing real-world conditions, such as shadow and light changes, cause challenges to the extensive appointing of automatic methods. As a potential solution for such challenges, this research proposes the adaption of deep learning (DL), specifically convolutional neural networks (CNN), which has a high ability to learn features automatically, to identify damaged buildings from pre- and post-event RS imageries. Since RS data revolves around imagery, CNNs can arguably be most effective at automatically discovering relevant features, avoiding the need for feature engineering based on expert knowledge. In this work, we focus on RS imageries from orthophoto imageries for damaged-building detection, specifically for (i) background, (ii) no damage, (iii) minor damage, and (iv) debris classifications. The gist is to uncover the CNN architecture that will work best for this purpose. To this end, three CNN models, namely the twin model, fusion model, and composite model, are applied to the pre- and post-orthophoto imageries collected from the 2016 Kumamoto earthquake, Japan. The robustness of the models was evaluated using four evaluation metrics, namely overall accuracy (OA), producer accuracy (PA), user accuracy (UA), and F1 score. According to the obtained results, the twin model achieved higher accuracy (OA = 76.86%; F1 score = 0.761) compare to the fusion model (OA = 72.27%; F1 score = 0.714) and composite (OA = 69.24%; F1 score = 0.682) models.
Highlights
Earthquakes are considered as some of the significant damaging forms of natural hazards, and they regularly happen with a little notice to entirely without any notice
This study analyzed the use of three convolutional neural networks (CNN) models, namely composite, twin, and fusion, for earthquake damage detection
The RGB images before and after the mainshock during the 2016 Kumamoto, Japan earthquake were selected as the study area
Summary
Earthquakes are considered as some of the significant damaging forms of natural hazards, and they regularly happen with a little notice to entirely without any notice. They usually cause massive destruction to properties such as buildings and infrastructures, as well as the environment [1]. Human life is threatened during high-intensity earthquakes, especially in populated areas. Remote-sensing (RS) technologies have been presented to be valuable tools for damage detection and estimations for post-earthquake emergency responses [3]. ImAatgyepPicraeplrsotceepsstiongall kinds of neural networks is the need for normalization. TAhseaabsoilliutytionf ,awuteoamdaotpict loevaerrnsianmgpolfinthgetocoincterexatusealthfeeantuurmesbefrroomf otbhseefreveadtionngsi.mages, providing a suitable platform for very high-Arestyopluictiaolnstiempatgoesalpl rkoicnedsssionfgn[e3u2r].al networks is the need for normalization. Normalization is a preprAorcteifissciinagl nteecuhrnailqnueetwtoomrkask(eAsNuNre)tgheant etrhaelldyactoanisicsotsnosifsotennet iannpduht alasyaeru, nseifvoerrmalshcaidled.eInn liamyaegrse, apnrodcaenssoinugt,pcuotmlamyeorn.lCy NusNed, wdahtiachprisepaatryaptieonofteAcNhnNiqmueasininlycluusdeedpfioxrelimnoargme adlaiztat,ifoonll.oIwn tshtihsestseipm,itlhaer cnounmvernitciopnix.eIlnvathluiseswaorerkr,etshcaeleindptuotbleaybertwtaekeens0inanimd 1agbeysd(ibveifdoirnegaenadchapftiexretlhbeym25a5i.nNshoorcmka).lizMatainony ims oafgtesnaarererqequuiriereddstoepprionpoerrdlyertrtaoinreadCuNceNthtoe gdeantaerdaitme aecncsuiorant,ewrehsiuclhtsa. iAdsfteinr tdhreaisntipcualtllyayredr,uacginengetrhael CtrNaiNnincgontitmainesanthdeifmolplorowviinngg: the classification results [30]
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