Research article Special Issues

3D imaging technology for improvement of and application in architecturalmonitoring

  • Received: 29 July 2018 Accepted: 24 September 2018 Published: 12 October 2018
  • MSC : 93

  • We consider the problem of laser scanners are increasingly being employed as surveying instruments for numerous applications. In this paper we have constructed a system for monitoring dangerous parts of archaeological sites or buildings. In order to the fragile parts of an archaeological site or building are protected without human intervention, the system will perform a 3D scan of the building in real time and collect the data. The system will restore the collected data and monitor the building by comparing and analyzing the data at di erent times. At the same time, in order to reduce the error generated in the coordinate system transformation process, we have established a "flattened" model to optimize 3D imaging to ensure that the final image does not exhibit distortion. By simulating di erent data, we can determine that our "flattened" model produces good results in 3D imaging.

    Citation: Miao Zhu, Giulio Ventura. 3D imaging technology for improvement of and application in architecturalmonitoring[J]. AIMS Mathematics, 2018, 3(3): 426-438. doi: 10.3934/Math.2018.3.426

    Related Papers:

  • We consider the problem of laser scanners are increasingly being employed as surveying instruments for numerous applications. In this paper we have constructed a system for monitoring dangerous parts of archaeological sites or buildings. In order to the fragile parts of an archaeological site or building are protected without human intervention, the system will perform a 3D scan of the building in real time and collect the data. The system will restore the collected data and monitor the building by comparing and analyzing the data at di erent times. At the same time, in order to reduce the error generated in the coordinate system transformation process, we have established a "flattened" model to optimize 3D imaging to ensure that the final image does not exhibit distortion. By simulating di erent data, we can determine that our "flattened" model produces good results in 3D imaging.


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    [1] V. Barrile, G. Bilotta, G. M. Meduri, et al. Laser Scanner Technology, Ground-Penetrating Radar and Augmented Reality for the Survey and Recovery of Artistic, ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences, (2017), 123-127.
    [2] M. Kincey, C. Gerrard, J. Warburton, Quantifying erosion of 'at risk' archaeological sites using repeat terrestrial laser scanning, Journal of Archaeological Science: Reports, 12 (2017), 405-424.
    [3] D. G. Hadjimitsis, K. Themistocleous, A. Agapiou, et al. Monitoring Archaeological Site Landscapes in Cyprus using Multi-temporal Atmospheric Corrected Image Data, International Journal of Architectural Computing, 7 (2009), 121-138.
    [4] M. Gaiani, E. Gamberini, G. Tonelli, VR as work tool for architectural and archaeological restoration: the ancient Appian way 3D web virtual GIS, Virtual Systems and Multimedia, (2001), 86-95.
    [5] F. M. Abed, M. U. Mohammed, S. J. Kadhim, Architectural And Cultural Heritage Conservation Using Low-Cost Cameras, Applied Research Journal, 3 (2017), 376-384.
    [6] Z. Zhang and L. Yuan. Building a 3D scanner system based on monocular vision, Appl. Optics, 51 (2012), 1638-1644.
    [7] J. Shi, Z. Sun and S. Bai, Large-scale three-dimensional measurement via combining 3D scanner and laser rangefinder, Appl. Optics, 54 (2015), 2814-2823.
    [8] C. Fröhlich, M. Mettenleiter. Terrestrial Laser Scanning - New Perspectives in 3D Surveying, International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, (2004), 7-13.
    [9] F. Remondino, Heritage Recording and 3D Modeling with Photogrammetry and 3D Scanning, Remote Sensing, 3 (2011), 1104-1138.
    [10] F. M. Giammusso Surveying, analysis and 3D modeling in archaeological virtual reconstruction The inner colonnade of the naos of Temple G of Selinunte, Virtual Systems and Multimedia (VSMM), 2012 18th International Conference on IEEE, 2012, 57-64.
    [11] H. S. Park, H. M. Lee, H. Adeli, et al. A New Approach for Health Monitoring of Structures: Terrestrial Laser Scanning, Comput-Aided Civ. Inf., 22 (2007), 19-30.
    [12] G. Teza, A. Galgaro, N. Zaltron, et al. Terrestrial laser scanner to detect landslide displacement fields: a new approach, International Journal of Remote Sensing, 28 (2007), 3425-3446.
    [13] G. Bitelli, M. Dubbini and A. Zanutta, Terrestrial laser scanning and digital photogrammetry techniques to monitor landslide bodies, International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 35 (2004), 246-251.
    [14] P. J. Besl, N. D. McKay, A method for registration of 3D shapes, IEEE T. Pattern Anal., 14 (1992), 239-256.
    [15] S. Al-khedera, Y. Al-shawabkeha, N. Haalab, Developing a documentation system for desert palaces in Jordan using 3D laser scanning and digital photogrammetry, J. Archaeol. Sci., 36 (2009), 537-546.
    [16] J. Armesto-González, B. Riveiro-Rodrguez, D. González-Aguilera, et al.Terrestrial laser scanning intensity data applied to damage detection for historical buildings, J. Archaeol. Sci., 37 (2010), 3037-3047.
    [17] S. C. Kuzminskya, M. S. Gardinerb, Three-dimensional laser scanning: potential uses for museum conservation and scientific research, J. Archaeol. Sci., 39 (2012), 2744-2751.
    [18] M. Cigola, A. Gallozzi, L. J. Senatore, et al. The Use of Remote Monitored Mobile Tools for the Survey of Architectural and Archaeological Heritage, INTBAU International Annual Event. Springer, Cham, (2017), 756-765.
    [19] M. Canciani, C. Falcolini, M. Saccone, et al. The architectural 3D survey vs archaeological 3D survey, Digital Heritage International Congress (DigitalHeritage), 1 (2013), 765-765.
    [20] F. Fischnaller, A. Guidazzoli, S. Imboden, et al. Sarcophagus of the Spouses installation intersection across archaeology, 3D video mapping, holographic techniques combined with immersive narrative environments and scenography, Digital Heritage, 1 (2015), 365-368.
    [21] J. H. R. Burns, D. Delparte, R. D. Gates, et al. Integrating structure-from-motion photogrammetry with geospatial software as a novel technique for quantifying 3D ecological characteristics of coral reefs, PeerJ, 3 (2015), e1077.
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