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Somrak, M., Deroski, S., & Kokalj, I. (2020). Learning to classify structures in als-derived visualizations of ancient maya settlements with cnn. Remote Sensing, 12(14), 2215.Search in Google Scholar
Bacco, M., Barsocchi, P., Cassara, P., Germanese, D., & Tampucci, M. (2020). Monitoring ancient buildings: real deployment of an iot system enhanced by uavs and virtual reality. IEEE Access, PP(99), 1-1.Search in Google Scholar
Shao, H., Chen, Y., Yang, Z., Jiang, C., & Hyypp, J. (2020). Feasibility study on hyperspectral lidar for ancient huizhou-style architecture preservation. Remote Sensing.Search in Google Scholar
Biswas, H. K. (2020). Automatic planning for scanning: optimizing 3d laser scanning operations using bim and tls. IAENG International Journal of Computer Science, 46(3).Search in Google Scholar
Yang, J., & Li, Q. (2022). Digital protection of ancient buildings based on bim simulation technology. Advances in multimedia(Pt.1), 2022.Search in Google Scholar
Wang, P. X., Zhang, W., Li, S. C., Hu, C. Y., Macchioni, N., & Yuan, J. L., et al. (2018). Minimally invasive detection technologies for the defects in ancient timber structural building. Key Engineering Materials, 777.Search in Google Scholar
O’Donnell, J., Truong-Hong, L., Boyle, N., Corry, E., Cao, J., & Laefer, D. F. (2019). Lidar point-cloud mapping of building facades for building energy performance simulation. Automation in construction, 107(Nov.), 102905.1-102905.16.Search in Google Scholar
Jaewook, J., Yoonseok, J., & Gunho, S. (2017). Implicit regularization for reconstructing 3d building rooftop models using airborne lidar data. Sensors, 17(621).Search in Google Scholar
Zhang, Z., Vosselman, G., Gerke, M., Persello, C., & Yang, M. Y. (2019). Detecting building changes between airborne laser scanning and photogrammetric data. Remote Sensing, 11(20), 2417-.Search in Google Scholar
Yu, Q., Helmholz, P., & Belton, D. (2017). Semantically enhanced 3d building model reconstruction from terrestrial laser-scanning data. Journal of Surveying Engineering, 143(4), 04017015.1-04017015.9.Search in Google Scholar
Ma, S. (2020). Three-dimensional laser combined with bim technology for building modeling, information data acquisition and monitoring. Nonlinear Optics, Quantum Optics, 52(3a4).Search in Google Scholar
Kwoczynska, B., & Malysa, B. (2022). Integration of data obtained from laser scanning and uav used to develop a 3d model of the building object. Archives of civil engineering.Search in Google Scholar
Trzeciak, M., & Brilakis, I. (2023). Dense 3d reconstruction of building scenes by ai-based camera–lidar fusion and odometry. Journal of computing in civil engineering.Search in Google Scholar
Yu, M. X., Ji, Z. H., Han, J., Liu, W. X., Zhang, H., & Lin, L. S., et al. (2023). On the application of three-dimensional (3-d) laser scanning technology in historic building elevation drawing. Lasers in engineering.Search in Google Scholar
Uotila, U., Saari, A., & Junnonen, J. M. (2021). Investigating the barriers to laser scanning implementation in building refurbishment. Journal of Information Technology in Construction(14).Search in Google Scholar
Terlikowski, W., Gregoriou-Szczepaniak, M., Sobczynska, E., & Wasilewski, K. (2021). Advantages of using 3d scanning in the survey of architectural monuments on example of archeological sites in egypt and russia. Archives of civil engineering(1), 67.Search in Google Scholar
Koeva, M., Luleva, M., & Maldjanski, P. (2017). Integrating spherical panoramas and maps for visualization of cultural heritage objects using virtual reality technology. Sensors, 17(4), 829.Search in Google Scholar
Owda, A., Balsa-Barreiro, José, & Fritsch, D. (2018). Methodology for digital preservation of the cultural and patrimonial heritage: generation of a 3d model of the church st. peter and paul (calw, germany) by using laser scanning and digital photogrammetry. Sensor Review, SR-06-2017-0106.Search in Google Scholar
Liu, X., Chen, Y., Cheng, L., Yao, M., & Cai, D. (2017). Airborne laser scanning point clouds filtering method based on the construction of virtual ground seed points. Journal of Applied Remote Sensing, 11(1), 016032.Search in Google Scholar
Dong, J. (2017). Research and application of virtual reality technology in the restoration of ancient buildings in huizhou. Acta Technica CSAV (Ceskoslovensk Akademie Ved), 62(1), 289-299.Search in Google Scholar
Casula, G., Fais, S., Cuccuru, F., Bianchi, M. G., & Ligas, P. (2023). Diagnostic process of an ancient colonnade using 3d high-resolution models with non-invasive multi techniques. Sensors (Basel, Switzerland), 23.Search in Google Scholar
K. Yuan & W.D. Zhu.(2024).A novel mirror-assisted method for full-field vibration measurement of a hollow cylinder using a three-dimensional continuously scanning laser Doppler vibrometer system. Mechanical Systems and Signal Processing111428-.Search in Google Scholar
Piao Weiying,Yuan Yibao & Lin Haijun.(2018).A Digital Image Denoising Algorithm Based on Gaussian Filtering and Bilateral Filtering.ITM Web of Conferences01006-01006.Search in Google Scholar
Gaofan Ji,Yunhan He,Chuanxiang Li,Li Fan,Haibo Wang & Yantong Zhu.(2024).A Novel Multi-LiDAR-Based Point Cloud Stitching Method Based on a Constrained Particle Filter. Electronics (9), 1777-.Search in Google Scholar
Zhu Guokai,Li Chunmei & Zhong Yuexi.(2022).Point cloud registration method based on Particle Swarm Optimization algorithm and improved ICP.Journal of Physics: Conference Series(1).Search in Google Scholar
Spieringhs Rik Marco,Audenaert Jan,Smet Kevin,Heynderickx Ingrid & Hanselaer Peter.(2023).Road marking BRDF model applicable for a wide range of incident illumination conditions.Journal of the Optical Society of America. A, Optics, image science, and vision(3),590-601.Search in Google Scholar