Circular arc structures

The most important guiding principle in computational methods for freeform architecture is the balance between cost efficiency on the one hand, and adherence to the design intent on the other. Key issues are the simplicity of supporting and connecting elements as well as repetition of costly parts. This paper proposes so-called circular arc structures as a means to faithfully realize freeform designs without giving up smooth appearance. In contrast to non-smooth meshes with straight edges where geometric complexity is concentrated in the nodes, we stay with smooth surfaces and rather distribute complexity in a uniform way by allowing edges in the shape of circular arcs. We are able to achieve the simplest possible shape of nodes without interfering with known panel optimization algorithms. We study remarkable special cases of circular arc structures which possess simple supporting elements or repetitive edges, we present the first global approximation method for principal patches, and we show an extension to volumetric structures for truly three-dimensional designs.

[1]  R. Bishop There is More than One Way to Frame a Curve , 1975 .

[2]  Manfredo P. do Carmo,et al.  Differential geometry of curves and surfaces , 1976 .

[3]  M. J. Pratt,et al.  Cyclides in computer aided geometric design , 1990, Comput. Aided Geom. Des..

[4]  Thomas E. Cecil Lie sphere geometry , 1992 .

[5]  D. Walton,et al.  Approximating smooth planar curves by arc splines , 1995 .

[6]  Carl Tim Kelley,et al.  Iterative methods for optimization , 1999, Frontiers in applied mathematics.

[7]  Marc Alexa,et al.  As-rigid-as-possible shape interpolation , 2000, SIGGRAPH.

[8]  Stefan Leopoldseder Algorithms on cone spline surfaces and spatial osculating arc splines , 2001, Comput. Aided Geom. Des..

[9]  Josef Hoschek,et al.  Handbook of Computer Aided Geometric Design , 2002 .

[10]  W. Degen Chapter 23 – Cyclides , 2002 .

[11]  U. Hertrich-Jeromin Introduction to Möbius differential geometry , 2003 .

[12]  Johannes Wallner,et al.  Geometric modeling with conical meshes and developable surfaces , 2006, SIGGRAPH 2006.

[13]  H. Pottmann,et al.  Geometry of multi-layer freeform structures for architecture , 2007, SIGGRAPH 2007.

[14]  Johannes Wallner,et al.  Freeform surfaces from single curved panels , 2008, SIGGRAPH 2008.

[15]  A. Bobenko,et al.  Discrete Differential Geometry: Integrable Structure , 2008 .

[16]  Johannes Wallner,et al.  Packing circles and spheres on surfaces , 2009, SIGGRAPH 2009.

[17]  Wei Zeng,et al.  Generalized Koebe's method for conformal mapping multiply connected domains , 2009, Symposium on Solid and Physical Modeling.

[18]  Martin Aigner,et al.  Circular spline fitting using an evolution process , 2009, J. Comput. Appl. Math..

[19]  Martin Kilian,et al.  Paneling architectural freeform surfaces , 2010, SIGGRAPH 2010.

[20]  M. Kilian,et al.  Geodesic patterns , 2010, ACM Transactions on Graphics.

[21]  Scott Schaefer,et al.  Triangle surfaces with discrete equivalence classes , 2010, SIGGRAPH 2010.

[22]  Chi-Wing Fu,et al.  K-set tilable surfaces , 2010, SIGGRAPH 2010.

[23]  Jonathan Balzer,et al.  Statics-Sensitive Layout of Planar Quadrilateral Meshes , 2010, AAG.

[24]  Alexander I. Bobenko,et al.  Curvature line parametrized surfaces and orthogonal coordinate systems: discretization with Dupin cyclides , 2011, Geometriae Dedicata.