Thermal Mapping from Point Clouds to 3D Building Model Facades

Biswanath, Manoj Kumar; Hoegner, Ludwig; Stilla, Uwe

doi:10.3390/rs15194830

rs15194830

Dokumenttyp:: Zeitschriftenaufsatz
Autor(en):: Biswanath, Manoj Kumar; Hoegner, Ludwig; Stilla, Uwe
Titel:: Thermal Mapping from Point Clouds to 3D Building Model Facades
Abstract:: Thermal inspection of buildings regarding efficient energy use is an increasing need in today’ s energy-demanding world. This paper proposes a framework for mapping temperature attributes from thermal point clouds onto building facades. The goal is to generate thermal textures for three-dimensional (3D) analysis. Classical texture generation methods project facade images directly onto a 3D building model. Due to the limited level of detail of these models, projection errors occur. Therefore, we use point clouds from mobile laser scanning extended by intensities extracted from thermal infrared (TIR) image sequences. We are not using 3D reconstructed point clouds because of the limited geometric density and accuracy of TIR images, which can lead to poor 3D reconstruction. We project these thermal point clouds onto facades using a mapping algorithm. The algorithm uses a nearest neighbor search to find an optimal nearest point with three different approaches: “ Minimize angle to normal” , “ Minimize perpendicular distance to normal” , and “ Minimize only distance” . Instead of interpolation, nearest neighbor is used because it retains the original temperature values. The thermal intensities of the optimal nearest points are weighted by resolution layers and mapped to the facade. The approach “ Minimize perpendicular distance to normal” yields the finest texture resolution at a reasonable processing time. The accuracy of the generated texture is evaluated based on estimating the shift of the window corner points from a ground truth texture. A performance metric root-mean-square deviation (RMSD) value that measures this shift is calculated. In terms of accuracy, the nearest neighbor method outperformed bilinear interpolation and an existing TIR image-based texturing method.
Stichworte:: LOCenter; LOCTop_Data_Generation_and_Object_Reconstruction; ai4twinning; thermal mapping; point clouds; TIR textures; nearest neighborhood algorithm; thermal images; building models; texels
Zeitschriftentitel:: Remote Sensing
Jahr:: 2023
Band / Volume:: 15
Jahr / Monat:: 2023-10
Heft / Issue:: 19
Reviewed:: ja
Sprache:: en
Volltext / DOI:: doi:10.3390/rs15194830
WWW:: https://www.mdpi.com/2072-4292/15/19/4830
Print-ISSN:: 2072-4292
Impact Factor:: 5.0
Status:: Verlagsversion / published
Eingereicht (bei Zeitschrift):: 29.07.2023
Angenommen (von Zeitschrift):: 02.10.2023
Publikationsdatum:: 05.10.2023
Semester:: SS 23
BibTeX

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mediaTUM Gesamtbestand Einrichtungen Schools TUM School of Engineering and Design Departments Aerospace and Geodesy Photogrammetrie und Fernerkundung (Prof. Holst komm.)Publikationen 2023

mediaTUM Gesamtbestand Hochschulbibliographie 2023 Schools und Fakultäten TUM School of Engineering and Design Photogrammetrie und Fernerkundung (Prof. Stilla)