Abstract

Churches are part of heritage structures that take an important role in Europe's cultural identity. As such, these structures must be protected to prevent catastrophic collapse and any damage must be reported timely to establish planning to maintenance and restoration. This can be achievable when the churches are monitored periodically with regular intervals. However, this monitoring strategy has not been available in most of the Europe’s churches for a number of reasons, complexity of the structures and limited budget are just two of them. Laser scanning has been widely used in capturing rich three-dimensional (3D) topographic data of visible surfaces of a structure with high accuracy. This paper presents a methodology to determine the shape and possible deviation from verticality of the church’s tower for monitoring deformation using a terrestrial laser scanner. The 500-year old wooden tower of St. Bavo Church in Haarlem, Netherlands is selected as a case study. First, point clouds of the tower captured from different views are registered into the same coordinate system. Second, a RANSAC method is employed to extract point clouds of a whole façades of the tower. Next, a point and surface-based method is proposed to compute the deformation of the surface from its data points. The results indicate that there is slightly different deformation between the tower facades in the same story and in neighbour stories. Moreover, the maximum total relative deformation at Story 7 of the tower by 0.63m.

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References

[1] Truong-Hong, L., Laefer, D.F., Hinks, T., Carr, H. Combining an angle criterion with voxelization and the flying voxel method in reconstructing building models from LiDAR data. Computer-Aided Civil and Infrastructure Engineering, 28 (2012) 112-129.

[2] Teza, G., Galgaro, A., Moro, F. Contactless recognition of concrete surface damage from laser scanning and curvature computation. NDT & E International, 42 (2009) 240-249.

[3] Gyetvai, N., Truong-Hong, L., Laefer, D.F. Laser scan-based structural assessment of wrought iron bridges: Guinness Bridge, Ireland. Proceedings of the Institution of Civil Engineers - Engineering History and Heritage, 171 (2018) 76-89.

[4] Arias, P., Riveiro, B., Armesto, J., Solla, M. Terrestrial laser scanning and non parametric methods in masonry arches inspection. in: Comission V Symposium. ISPRS, Newscalte upon Tyne, UK 2010 pp 39-44.

[5] Cabaleiro, M., Lindenbergh, R., Gard, W.F., Arias, P., van de Kuilen, J.W.G. Algorithm for automatic detection and analysis of cracks in timber beams from LiDAR data. Construction and Building Materials, 130 (2017) 41-53.

[6] Haddad, N.A. From ground surveying to 3D laser scanner: A review of techniques used for spatial documentation of historic sites. Journal of King Saud University - Engineering Sciences, 23 (2011) 109-118.

[7] González-Aguilera, D., Gómez-Lahoz, J., Muñoz-Nieto, Á., Herrero-Pascual, J. Monitoring the health of an emblematic monument from terrestrial laser scanner. Nondestructive Testing and Evaluation, 23 (2008) 301-315.

[8] Pesci, A., Casula, G., Boschi, E. Laser scanning the Garisenda and Asinelli towers in Bologna (Italy): Detailed deformation patterns of two ancient leaning buildings. Journal of Cultural Heritage, 12 (2011) 117-127.

[9] Bonali, E., Pesci, A., Casula, G., Boschi, E. Deformation of Ancient Buildings inferred by Terrestrial Laser Scanning methodology: the Cantalovo church case study (Northern Italy)*. Archaeometry, 56 (2014) 703-716.

[10] Bertacchini, E., Boni, E., Capra, A., Castagnetti, C., Dubbini, M. Terrestrial Laser Scanner for Surveying and Monitoring Middle Age T owers. in: XXIV FIG International Congress 2010-Facing the Challenges-Building the Capacity. FIG Federation International des Geometres, 2010 pp 1-13.

[11] Bhadrakom, B., Chaiyasarn, K. As-built 3D modeling based on structure from motion for deformation assessment of historical buildings. Int. J. Geomate, 11 (2016) 2378-2384.

[12] Muszynski, Z., Milczarek, W. Application of Terrestrial Laser Scanning to Study the Geometry of Slender Objects. IOP Conference Series: Earth and Environmental Science, 95 (2017) 042069.

[13] Dunk, T.H.v.d. Haarlem als Hollands Jeruzalem: De oorsprong van de toren van de Grote of St.-Bavokerk. Hilversum Verloren, (2016).

[14] Leica Geosystems. Leica ScanStation P40. in., 2020 pp.

[15] Leica Geosystems. Leica Cyclone 3D Point Cloud Processing Software. in., 2020 pp.

[16] Rabbani, T., Van Den Heuvel, F. Efficient hough transform for automatic detection of cylinders in point clouds. Isprs Wg Iii/3, Iii/4, 3 (2005) 60-65.

[17] Truong-Hong, L., Laefer, D.F. Octree-based, automatic building façade generation from LiDAR data. Computer-Aided Design, 53 (2014) 46-61.

[18] Schnabel, R., Wahl, R., Klein, R. Efficient RANSAC for point‐cloud shape detection. in. Wiley Online Library, pp 214-226.

[19] CloudCompare. CloudCompare. in., 2020 pp.

[20] Dillencourt, M.B., Samet, H., Tamminen, M. A general approach to connected-component labeling for arbitrary image representations. J. ACM, 39 (1992) 253–280.

[21] Laefer, D.F., Truong-Hong, L. Toward automatic generation of 3D steel structures for building information modelling. Automation in Construction, 74 (2017) 66-77.

[22] Thijssen, W. Who has the crookedest? in: de Volkshrant. Netherlands 2011 pp.

[23] Pellegrinelli, A., Furini, A., Russo, P. Earthquakes and ancient leaning towers: Geodetic monitoring of the bell tower of San Benedetto Church in Ferrara (Italy). Journal of cultural heritage, 15 (2014) 687-691