A methodology for updating 3D solid models of complex monumental structures based on local point-based meshes

Structural changes introduced during the life of monuments contribute to produce complex geometrical configurations that cannot be properly represented in standard solid modeling systems designed for current engineering applications such as finite element analysis (FEA). Likewise, point-based 3D meshes - laser-scanner or photogrammetric -, although capable of constructing detailed representation of surfaces, cannot be used for direct application in structural analysis because they do not produce complete and unambiguous solid models. To tackle this issue, we merged these two approaches into a unified methodology capable of updating a 3D solid model, representing the entire monument as reconstructed in its presumed original configuration, with information from a 3D mesh model containing a detailed geometrical description of the recent structural state of a specific sector of the same monument. The methodology is based on a series of functions that operate in the Mesh and Solid Modeling Space. The mesh model is aligned via 3D registration and, subsequently, segmented for its conversion to a solid model. Finally, this solid updates the solid representation of the entire monument via Boolean operations. We test the procedure on the Main Platform of the Huaca de la Luna, Trujillo, Peru, one of the most important massive earthen structures of the Moche civilization. Solid models are defined in AutoCAD while 3D meshes are constructed via the photogrammetric program Agisoft PhotoScan. The results indicate that the proposed methodology is effective at transferring complex geometrical and topological features from the mesh to the solid modeling space. The updated solid model can be represented and visualized in any standard CAD software, and utilized for FEA and augmented reality applications.

[1]  Guo Cao,et al.  Curvature estimation for meshes based on vertex normal triangles , 2011, Comput. Aided Des..

[2]  Elliot Gindis Chapter 27 – Surfaces and Meshes , 2013 .

[3]  Philip F. Brune,et al.  Roman Concrete Vaulting in the Great Hall of Trajan’s Markets: Structural Evaluation , 2012 .

[4]  Elliot Gindis Surfaces and Meshes , 2015 .

[5]  H. Woo,et al.  Updating 3D triangular mesh models based on locally added point clouds , 2006 .

[6]  Naif Haddad,et al.  From ground surveying to 3D laser scanner: A review of techniques used for spatial documentation of historic sites , 2011 .

[7]  Vadim Shapiro,et al.  Solid Modeling , 2002, Handbook of Computer Aided Geometric Design.

[8]  George Pavlidis,et al.  Multi-image 3D reconstruction data evaluation , 2014 .

[9]  Mohamed A. Deriche,et al.  3D registration using a new implementation of the ICP algorithm based on a comprehensive lookup matrix: Application to medical imaging , 2007, Pattern Recognit. Lett..

[10]  Massimo Bergamasco,et al.  Beyond virtual museums: experiencing immersive virtual reality in real museums , 2010 .

[11]  Stephen J. Redmond,et al.  A method for initialising the K-means clustering algorithm using kd-trees , 2007, Pattern Recognit. Lett..

[12]  T. Lauwagie,et al.  Geometry-Based Updating of 3D Solid Finite Element Models , 2011 .

[13]  Helena Rua,et al.  Living the past: 3D models, virtual reality and game engines as tools for supporting archaeology and the reconstruction of cultural heritage – the case-study of the Roman villa of Casal de Freiria , 2011 .

[14]  K. Wenzel,et al.  A comparison of dense matching algorithms for scaled surface reconstruction using stereo camera rigs , 2013 .

[15]  Sara Casciati,et al.  Dynamic FE analysis of South Memnon Colossus including 3D soil–foundation–structure interaction , 2004 .

[16]  Michael M. Kazhdan,et al.  Poisson surface reconstruction , 2006, SGP '06.

[17]  Roberto Scopigno,et al.  Archeological excavation monitoring using dense stereo matching techniques , 2012 .

[18]  Marco Callieri,et al.  Innovative uses of 3D digital technologies to assist the restoration of a fragmented terracotta statue , 2013 .