Browse > Article
http://dx.doi.org/10.13161/kibim.2021.11.4.042

Paneling of Curved NURBS Surface through Marching Geodesic - Application on Compound Surface -  

Hong, Ji-Hak (충남대학교 건축학과)
Sung, Woo-Jae (충남대학교 건축학과)
Publication Information
Journal of KIBIM / v.11, no.4, 2021 , pp. 42-52 More about this Journal
Abstract
Paneling building facades is one of the essential procedures in building construction. Traditionally, it has been an easy task of simply projecting paneling patterns drawn in drawing boards onto 3d building facades. However, as many organic or curved building shapes are designed and constructed in modern architectural practices, the traditional one-to-one projection is becoming obsolete for the building types of the kind. That is primarily because of the geometrical discrepancies between 2d drawing boards and 3d curved building surfaces. In addition, curved compound surfaces are often utilized to accommodate the complicated spatial programs, building codes, and zoning regulations or to achieve harmonious geometrical relationships with neighboring buildings in highly developed urban contexts. The use of the compound surface apparently makes the traditional paneling pattern projection more challenging. Various mapping technics have been introduced to deal with the inabilities of the projection methods for curved facades. The mapping methods translate geometries on a 2d surface into a 3d building façade at the same topological locations rather than relying on Euclidean or Affine projection. However, due to the intrinsic differences of the planar 2d and curved 3d surfaces, the mapping often comes with noticeable distortions of the paneling patterns. Thus, this paper proposes a practical method of drawing paneling patterns directly on a curved compound surface utilizing Geodesic, which is faithful to any curved surface, to minimize unnecessary distortions.
Keywords
Curved Surface Paneling; Geodesic; Compound Surface; Grasshopper; Non-linear Shape;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Wallner, J., Pottmann, H. (2011). Geometric computing for freeform architecture.. Journal of Mathematics in Industry. 1(1), pp. 1-19.   DOI
2 Farin, G. (2014). Curves and surfaces for computer-aided geometric design: a practical guide, Elsevier, pp. 353-362.
3 Kimmel, R., Kiryati, N. (1995). Finding shortest paths on surfaces by fast global approximation and precise local refinement.. International Society for Optics and Photonics. 2356, pp. 198-209.
4 Les, P. (1996). The NURBS book, Springer, pp. 81-116.
5 Minh, H., Forbes, A. (2012). New Method for free-form surface fitting in precision metrology, https://www.researchgate.net/publication/287552808 (Dec. 30, 2021).
6 Robert McNeel Associates (2015), Continuity Descriptions, http://docs.mcneel.com/rhino/5/help/en-us/popup_moreinformation/continuity_descriptions.htm (Dec. 30, 2021)
7 Bose, P., Maheshwari, A., Shu, C., Wuhrer, S. (2009). A survey of geodesic paths on 3D surfaces. Computational Geometry. 44, pp. 486-498.   DOI
8 Schot, S. (1978). Aberrancy: Geometry of the third derivative. Mathematics Magazine. 51(5), pp. 259-275.   DOI
9 Adriaenssens, S., Gramazio, F., Kohler, M., Menges, A.,Pauly, M. (2016). Advances in Architectural Geometry, vdf, pp. 40-61.
10 Alacam, S., Guzelci, O. (2016). Computational interpretations of 2D Muqarnas projections in 3D form finding. ASCAAD2016, https://www.researchgate.net/publication/310374670 (Dec. 30, 2021).
11 Chen, H., Pottmann, H. (1999). Approximation by ruled surfaces. Journal of Computational and Applied Mathematics. 102(1), pp. 143-156.   DOI
12 Eigensatz, M., Kilian, M., Schiftner, A., Mitra, N., Pottmann, H., Pauly, M. (2010). Paneling architectural freeform surfaces.. Association for Computing Machinery. 45, pp. 1-10.
13 Floater, M., Hormann, K. (2005). Surface parameterization: a tutorial and survey, https://www.researchgate.net/publication/226655623 (Dec. 30, 2021).
14 Gravesen, J. (1996). De Casteljau's algorithm revisited, Mathematical Methods for Curves and Surfaces II. Vanderbilt University Press, pp. 221-228.
15 Kimmel, R., Sethian, J. (1998). Computing geodesic paths on manifolds. Proceedings of the national academy of Sciences. 95(15), pp. 8431-8435.   DOI
16 Pottmann, H., Huang, Q., Deng, B., Schiftner, A., Kilian, M., Guibas, L., Wallner, J. (2010). Geodesic patterns. ACM Trans. Graph.. 29(4), pp. 10.