Trialling an Accessible Non-Contact Photogrammetric Monitoring Technique to Detect 3D Change on Wall Paintings

References

• Abate, D. 2019a. “Built-Heritage Multi-Temporal Monitoring Through Photogrammetry and 2D/3D Change Detection Algorithms.” Studies in Conservation 64 (7): 423–434.
   Web of Science ®Google Scholar
• Abate, D. 2019b. “Documentation of Paintings Restoration Through Photogrammetry and Change Detection Algorithms.” Heritage Science 7 (1): 13.
   Google Scholar
• Agisoft Metashape Professional. 2019. Version 1.5.2 build 7838 (64 bit), 2019, Agisoft LLC., https://www.agisoft.com/, 15/01/2019.
   Google Scholar
• Ashurst, J., and N. Ashurst. 1988. Practical Building Conservation: English Heritage Technical Handbook. Volume 3, Mortars, Plasters and Renders. Aldershot: Gower Publishing Co. Ltd.
   Google Scholar
• Barazzetti, L., F. Remondino, M. Scaioni, M. Lo Brutto, A. Rizzi, and R. Brumana. 2010. “Geometric and Radiometric Analysis of paintings.” International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences 38 (5): 62–67.
   Google Scholar
• Boochs, F., U. Huxhagen, and K. Kraus. 2008. “Potential of High-Precision Measuring Techniques for the Monitoring of Surfaces from Heritage Objects.” In situ Monitoring of Monumental Surfaces, Proceedings of the International Workshop SMW08, Florence, 97–106.
   Google Scholar
• Cather, S. 2003. “Assessing Causes and Mechanisms of Detrimental Change.” Conserving the Painted Past: Developing Approaches to Wall Painting Conservation (Post-prints of an English Heritage Conference, 1999), edited by R. Gowing and A. Heritage, 64–74. London: English Heritage.
   Google Scholar
• Cather, S., A. Sawdy, and A. Heritage. 1998. “St Botolph’s Church, Hardham: Conservation of the Wall Paintings. Phase I: Investigations, Recording, Treatment Testing and Assessment. Report submitted to English Heritage,” unpublished.
   Google Scholar
• CloudCompare Professional. 2018. Version 2.10.2 Zephyrus (64 bit), the CloudCompare project. Accessed 15 January, 2019. https://www.danielgm.net/cc/.
   Google Scholar
• CloudCompare Wiki. 2016.Accessed 14 May, 2019. https://www.cloudcompare.org/doc/wiki/index.php?title=Main_Page.
   Google Scholar
• Cucchiaro, S., M. Cavalli, D. Vericat, S. Crema, M. Llena, A. Beinat, L. Marchi, and F. Cazorzi. 2018. “Monitoring Topographic Changes Through 4D-Structure-from-Motion Photogrammetry: Application to a Debris-Flow channel.” Environmental Earth Sciences 77 (18): 623.
   Google Scholar
• Del Fa, R. M., C. Riminesi, and P. Tiano. 2016. “Monitoring of the Surface Pattern of Artistic and Architectural Artefacts by Means of Ultra-Close Range Photogrammetry.” European Journal of Science and Theology 11 (2 ): 179–187.
   Web of Science ®Google Scholar
• Elseberg, J., S. Magnenat, R. Siegwart, and A. Nuchter. 2012. “Comparison of Nearest-Neighbor-Search Strategies and Implementations for Efficient Shape Registration.” Journal of Software Engineering for Robotics 3 (1): 2–12.
   Google Scholar
• Feurer, D., and F. Vinatier. 2018. “The Time-SIFT Method: Detecting 3-D Changes from Archival Photogrammetric Analysis with Almost Exclusively Image Information.” arXiv preprint arXiv:1807.09700.
   Google Scholar
• Fox, S. J., C. Babington, F. Macalister, T. Bower, and C. Martin de Fonjaudran. 2018. “Monitoring and Mitigating Particulate Matter Deposition on Decorative Surfaces: Current and Future Approaches in the Palace of Westminster.” Studies in Conservation 63 (sup1): 81–86.
   Web of Science ®Google Scholar
• Garcia-Leon, J., A.M. Felicisimo, and J.J. Martinez. 2003. “First Experiments with Convergent Multi-Images Photogrammetry with Automatic Cor-Relation applied to Differential Rectification of Architectural Facades.” In CIPA 19 International Symposium, Antalya, Turkey, 196–201.
   Google Scholar
• Howe, E. 2012. “Passive Conservation by Means of Relative Humidity Controlled Continuous Heating at St Boltoph’s Church, Hardham: a Report on the Condition monitoring.” unpublished report for English Heritage and the Conservation of Wall Painting Department, Courtauld Institute of Art, London.
   Google Scholar
• Kontogianni, G., R. Chliverou, A. Koutsoudis, G. Pavlidis, and A. Georgopoulos. 2017. “Investigating the Effect of Focus Stacking on sfm-mvs Algorithms.” The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences 42: 385.
   Google Scholar
• Lague, D., N. Brodu, and J. Leroux. 2013. “Accurate 3D Comparison of Complex Topography with Terrestrial Laser Scanner: Application to the Rangitikei Canyon (N-Z).” ISPRS Journal of Photogrammetry and Remote Sensing 82: 10–26.
   Web of Science ®Google Scholar
• Matteini, M. 2008. “Monitoring Decay Processes, Their Causes and the Durability of Conservation Treatments.” In situ Monitoring of Monumental Surfaces: Proceedings of the International workshop SMW08, 27–29 October 2008, edited by P. Tiano and C. Pardini, 7–12. Florence: ICVBC-CNR.
   Google Scholar
• Matthews, N. A. 2008. Aerial and Close-Range Photogrammetric Technology: Providing Resource Documentation, Interpretation, and Preservation. Technical Note 428. Denver, Colorado: U.S. Department of the Interior, Bureau of Land Management, National Operations Center.
   Google Scholar
• Micheletti, N., J. H. Chandler, and S. N. Lane. 2015. “Structure from Motion (SFM) photogrammetry.” In Geomorphological Techniques (Online Edition). London: British Society for Geomorphology.
   Google Scholar
• Neyer, F., E. Nocerino, and A. Grün. 2018. “Monitoring Coral Growth–the Dichotomy Between Underwater Photogrammetry and Geodetic Control network.” ISPRS-International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XLII-2: 759–766.
   Google Scholar
• Nocerino, E., F. Menna, and F. Remondino. 2014. “Accuracy of Typical Photogrammetric Networks in Cultural Heritage 3D Modeling Projects.” International Archives of the Photogrammetry, Remote Sensing & Spatial Information Sciences 45: 465–472.
   Google Scholar
• Nadal-Romero, E., J. Revuelto, P. Errea, and J. I. López-Moreno. 2015. “The Application of Terrestrial Laser Scanner and SfM Photogrammetry in Measuring Erosion and Deposition Processes in two Opposite Slopes in a Humid Badlands Area (Central Spanish Pyrenees).” Soil 1 (2): 561.
   Web of Science ®Google Scholar
• Pandey, S. C., and S. Cather. 2015. “Close-range 3D Imaging for Documenting and Monitoring Dynamic Deterioration Processes in Wall paintings.” In ICOM CIDOC 2015: Documenting Diversity–Collections, Catalogues & Context. Nueva Deli, India. Paris: ICOM.
   Google Scholar
• Park, D. 1984. “The Lewes Group of Wall Paintings in Sussex.” In Anglo-Norman Studies VI, Proceedings of the Battle Conference 1983, edited by R. A. Brown, 200–235. Woodbridge: Boydell & Brewer.
   Google Scholar
• Robson, S., S. Bucklow, N. Woodhouse, and H. Papadaki. 2004. “Periodic Photogrammetric Monitoring and Surface Reconstruction of a Historical Wood Panel Painting for Restoration purposes.” International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences 35 (5): 395–400.
   Google Scholar
• Salonia, P., A. Marcolongo, and S. Scolastico. 2010. “Experimentation of a Three-Focal Photogrammetric Survey System as Non-Invasive Technique for Analysis and Monitoring of Painting Surfaces Decay condition.” In Lasers in the Conservation of Artworks VIII, edited by R. Radvan, J. F. Asmus, M. Castillejo, P. Pouli, and A. Nevin, 185. London: CRC Press.
   Google Scholar
• Stylianidis, E., A. Georgopoulos, and F. Remondino. 2016. “Basics of Image-Based Modelling Techniques in Cultural Heritage 3D Recording.” In 3D Recording, Documentation and Management of Cultural Heritage, edited by E. Stylianidis, and F. Remondino, 253–304. Dunbeath: Whittles Publishing.
   Google Scholar
• Tiano, P., D. Tapete, M. Matteini, and F. Ceccaroni. 2008. “The Microphotogrammetry: a new Diagnostic Tool for on Site Monitoring of Monu- Mental Surfaces.” In Situ Monitoring of Monumental Surfaces, Proceedings of the International Workshop SMW08, Florence, Italy, October 27–29. 97–106.
   Google Scholar
• Verhoeven, G. (2016). “Basics of Photography for Cultural Heritage Imaging.” In 3D Recording, Documentation and Management of Cultural Heritage, edited by E. Stylianidis, and F. Remondino, 127–251. Dunbeath: Whittles Publishing.
   Google Scholar
• Wackrow, R., and J. H. Chandler. 2008. “A Convergent Image Configuration for DEM Extraction that Minimises the Systematic Effects Caused by an Inaccurate Lens Model.” The Photogrammetric Record 23 (121): 6–18.
   Web of Science ®Google Scholar
• Wong, L. 2003. “Documentation: Objectives, Levels and the Recording Process.” Conserving the Painted Past: Developing Approaches to Wall Painting Conservation (Post-prints of an English Heritage Conference, 1999), edited by R. Gowing and A. 46–54. London: English Heritage.
   Google Scholar
• Zehnder, K. 2007. “Long-term Monitoring of Wall Paintings Affected by Soluble Salts.” Environmental Geology 52 (2): 353–367.
   Web of Science ®Google Scholar
• Zhang, Q., W. Feng, L. Wan, F. P. Tian, and P. Tan. 2018. “Active Recurrence of Lighting Condition for Fine-Grained Change Detection.” Proceedings of the 27th International Joint Conference on Artificial Intelligence, July 13. 4972–4978.
   Google Scholar