2018
DOI: 10.3390/s18113921
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A Deep Learning Approach on Building Detection from Unmanned Aerial Vehicle-Based Images in Riverbank Monitoring

Abstract: Buildings along riverbanks are likely to be affected by rising water levels, therefore the acquisition of accurate building information has great importance not only for riverbank environmental protection but also for dealing with emergency cases like flooding. UAV-based photographs are flexible and cloud-free compared to satellite images and can provide very high-resolution images up to centimeter level, while there exist great challenges in quickly and accurately detecting and extracting building from UAV im… Show more

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Cited by 52 publications
(35 citation statements)
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“…The FCN is an end-to-end model that maintains a two-dimensional structure of a feature map and uses contextual and location information to predict class labels, reducing the computational cost significantly. Semantic segmentation models based on FCN can be divided into four categories: encoder-decoder structure [23,24], dilated convolutions [34], and spatial pyramid pooling [35], which are described below.…”
Section: Introductionmentioning
confidence: 99%
“…The FCN is an end-to-end model that maintains a two-dimensional structure of a feature map and uses contextual and location information to predict class labels, reducing the computational cost significantly. Semantic segmentation models based on FCN can be divided into four categories: encoder-decoder structure [23,24], dilated convolutions [34], and spatial pyramid pooling [35], which are described below.…”
Section: Introductionmentioning
confidence: 99%
“…As such, it includes a broad range of algorithms, encompassing everything from simple linear regressions to deep learning-based neural networks [52]. The application of AI/ML for geomorphic error thresholding purposes is novel, with existing studies within freshwater settings applying it predominantly for classification of land cover types from image-derived parameters (e.g., [53][54][55][56]) or for the identification of other specific features of interest such as buildings (e.g., [57]) and invasive species (e.g., [58]). As such, our ultimate aim is to create the first high resolution, spatially continuous SfM-derived topographic change models in submerged fluvial environments constrained by spatially variable error estimates.…”
mentioning
confidence: 99%
“…Moreover, the adaption of camera parameters, as well as motion parameters estimation based on the integration of video measurements and data obtained by UAVs, have always to be seriously taken into account [32]. The relentless motivation for image classification tasks based on deep learning and aerial images captured by UAVs has led to an abundance of research including vehicles [24,33,34], aerial vehicles [35,36,37,38,39], roads [40], buildings [41,42], cracks [43], birds [44], cattle [45], and wilt [46] detection. Another remarkable approach for object detection in very high-resolution aerial images has been proposed in [47].…”
Section: Related Researchmentioning
confidence: 99%