Supervised Detection of Façade Openings in 3D Point Clouds with Thermal Attributes

Jarząbek-Rychard, Małgorzata; Lin, Defu; Maas, Hans‐Gerd

doi:10.3390/rs12030543

Cited by 23 publications

(10 citation statements)

References 37 publications

(45 reference statements)

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“…The low spatial resolution of the thermal images can impose a severe obstacle to the proper reconstruction of the surveyed structures' geometry. Moreover, the radiometric characteristics of TIR images make the direct use of SfM challenging [32]: for this reason, some critical issues are generally encountered during the tie-points extraction phase [34], especially if the acquisition has been performed without following rigorous photogrammetric overlapping criteria.…”

Section: Uas-based Applicationsmentioning

confidence: 99%

“…This approach requires the registration of both thermal and optical images in the same reference system, which is based on the identification of the Ground Control Points (GCPs) also in thermal images, a challenging task due to the intrinsic characteristics of this kind of data. This problem can be solved using the image geo-tag [34], which is often embedded in the acquired images (if the system used is equipped with a GNSS receiver). However, this solution's positional accuracy is generally low (few meters) unless RTK-enabled platforms are adopted [37].…”

Section: Uas-based Applicationsmentioning

confidence: 99%

See 1 more Smart Citation

3D Thermal Mapping of Architectural Heritage

Adamopoulos

Patrucco

Volinia

et al. 2021

Digital Heritage. Progress in Cultural Heritage: Documentation, Preservation, and Protection

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The combination of thermographic and geometric recording has always been an issue for architectural heritage diagnostic investigations. Multidisciplinary projects often require integrating multi-sensor informationincluding metric and temperature data-to extract valid conclusions regarding the state-of-preservation of historical buildings. Towards this direction, recent technological advancements in thermographic cameras and three-dimensional (3D) documentation instrumentation and software have contributed significantly, assisting the rapid creation of detailed 3D thermal-textured results, which can be exploited for non-destructive diagnostical surveys. This paper aims to briefly review and evaluate the current workflows for thermographic architectural 3D modeling, which implement state-of-the-art sensing procedures and processing techniques, while also presenting some applications on case studies of significant heritage value to help discuss current problems and identify topics for relevant future research.

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Section: Uas-based Applicationsmentioning

confidence: 99%

Section: Uas-based Applicationsmentioning

confidence: 99%

3D Thermal Mapping of Architectural Heritage

Adamopoulos

Patrucco

Volinia

et al. 2021

Digital Heritage. Progress in Cultural Heritage: Documentation, Preservation, and Protection

View full text Add to dashboard Cite

show abstract

“…3D reconstruction with thermal mapping has a wide range of applications, such as in energy-efficiency monitoring of buildings [ 12 , 19 ], Object Detection [ 21 ] or even fruit tree characterization [ 38 ], but also critical applications such as hotspot and fire detection [ 15 , 28 ] in buildings. Related to fumarole field monitoring, Lewis et al .…”

Section: Related Workmentioning

confidence: 99%

A Hand-Held Sensor System for Exploration and Thermal Mapping of Volcanic Fumarole Fields

Irmisch

Ernst

Baumbach

et al. 2021

Communications in Computer and Information Science

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Research from the field of planetary- and geoscience require investigation of geological features in harsh environments. Sampled data needs to be precisely localized spatially and in time, and to be prepared appropriately for further inspection and evaluation. In the case of thermal image data, the computer vision community has made enormous progress in the past years to combine thermal with spatial information in form of thermal 3D models. In this paper, we propose to use a camera-based hand-held sensor system to capture and georeference thermal images in rugged terrain and to prepare the data for further investigations by visualizing the thermal data in 3D. We use a global localization solution to gain fast 3D impressions of the environment and further Structure from Motion to generate detailed mid-scale models of selected interesting structures. We demonstrate our application based on a challenging dataset that we acquired in the active fumarole fields of Vulcano, Sicily.

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“…One of the benefits of using image-based modelling is the accessibility of texture information that can enable material recognition and 3D Computer-Aided Design (CAD) model object recognition [11,12]. Moreover, some works used the reconstruction of 3D scene geometry for the purpose of control and management of energy in the field of 3D modelling of buildings [13]. Pileun et al [14] estimated the positions and orientations of the object by using Simultaneous Localization and Mapping (SLAM).…”

Section: D Reconstruction From Capturing Multiple Imagesmentioning

confidence: 99%

Enhanced 3D Point Cloud from a Light Field Image

et al. 2020

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The importance of three-dimensional (3D) point cloud technologies in the field of agriculture environmental research has increased in recent years. Obtaining dense and accurate 3D reconstructions of plants and urban areas provide useful information for remote sensing. In this paper, we propose a novel strategy for the enhancement of 3D point clouds from a single 4D light field (LF) image. Using a light field camera in this way creates an easy way for obtaining 3D point clouds from one snapshot and enabling diversity in monitoring and modelling applications for remote sensing. Considering an LF image and associated depth map as an input, we first apply histogram equalization and histogram stretching to enhance the separation between depth planes. We then apply multi-modal edge detection by using feature matching and fuzzy logic from the central sub-aperture LF image and the depth map. These two steps of depth map enhancement are significant parts of our novelty for this work. After combing the two previous steps and transforming the point–plane correspondence, we can obtain the 3D point cloud. We tested our method with synthetic and real world image databases. To verify the accuracy of our method, we compared our results with two different state-of-the-art algorithms. The results showed that our method can reliably mitigate noise and had the highest level of detail compared to other existing methods.

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Supervised Detection of Façade Openings in 3D Point Clouds with Thermal Attributes

Cited by 23 publications

References 37 publications

3D Thermal Mapping of Architectural Heritage

3D Thermal Mapping of Architectural Heritage

A Hand-Held Sensor System for Exploration and Thermal Mapping of Volcanic Fumarole Fields

Enhanced 3D Point Cloud from a Light Field Image

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