Image and Signal Processing for Remote Sensing XXV 2019
DOI: 10.1117/12.2533149
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Deep learning-based extraction of building contours for large-scale 3D urban reconstruction

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Cited by 4 publications
(5 citation statements)
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“…AI-based procedures were recently used to infer buildings' features and characteristics. Machine and deep learning methods were increasingly employed for predicting 3D urban geometries and semantics [29][30][31][32], for energy performances [33][34][35], for models generalisation [36], or to infer some missing information, such as buildings' age [37][38][39][40] and height [28,[41][42][43][44]. Prediction algorithms are generally trained using satellite or aerial images [43,44], LiDAR data [37,42], or 2D data (such as photographs, maps, footprints, and attributes) available from historical archives, cadastre datasets, or volunteered geographic information databases [28,38,39,45].…”
Section: Related Workmentioning
confidence: 99%
“…AI-based procedures were recently used to infer buildings' features and characteristics. Machine and deep learning methods were increasingly employed for predicting 3D urban geometries and semantics [29][30][31][32], for energy performances [33][34][35], for models generalisation [36], or to infer some missing information, such as buildings' age [37][38][39][40] and height [28,[41][42][43][44]. Prediction algorithms are generally trained using satellite or aerial images [43,44], LiDAR data [37,42], or 2D data (such as photographs, maps, footprints, and attributes) available from historical archives, cadastre datasets, or volunteered geographic information databases [28,38,39,45].…”
Section: Related Workmentioning
confidence: 99%
“…For this task, we have adopted a U-net convolutional neural network architecture, which has exhibited the highest performance in several benchmarks involving building rooftop labeling [10,4]. A detailed description of the designed model and the Luxcarta database used for its training in given in [11]. We have shown in [11] that a careful design of the model together with an appropriate loss function (we have used a combination of cross-entropy and intersection over union losses) allows to train a generic model, which performs well on different types of urban areas, such as residential, industrial and very dense areas.…”
Section: Rooftop Extractionmentioning
confidence: 99%
“…We have designed a solution to polygonize building contours, which performs a naive polygonization of the mask of every building, followed by a polygon simplification, which searches for a compressed polygon with the best quality/complexity ratio, i.e. with the minimum number of vertices within a specified tolerance of an error [11].…”
Section: Rooftop Extractionmentioning
confidence: 99%
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“…3D outdoor scene reconstruction, a process that entails the reconstruction of the three-dimensional geometric structure of a scene based on one or more 2D images, has the capability to accurately capture the intricate details and textures of the 3D environment [1] . In recent years, the demand for 3D data has surged in various domains, including urban digital modeling [2,3] , the creation of immersive virtual reality environments within the metaverse [4] , and addressing public safety concerns in smart cities [5] . This increasing, demand has fueled extensive research and development efforts in the field of outdoor 3D scene reconstruction.…”
Section: Introductionmentioning
confidence: 99%