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Reference
B.G. Thomas: Counterchange Patterns and Polyhedra. In: Bridges 2009. Pages 177–182
DOI
Abstract
Recent research has examined the difficulties encountered when attempting to apply two-dimensional repeating designs to wrap around the surface of polyhedra. The study was concerned with symmetry in pattern but did not consider symmetries that involve a color change. A pattern is said to have color symmetry when it exhibits, as a minimum, one symmetry that is color-changing. Counterchange designs are produced when the color-changing symmetries of a pattern involve only two colors. This paper discusses the problems involved in the application of counterchange patterns to polyhedra, focusing particular attention on the icosahedron.
Extended Abstract
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Used References
[1] B.G. Thomas and M.A. Hann, Patterned Polyhedra: Tiling the Platonic Solids, in R. Sarhangi and J. Barrallo (eds.) Bridges Donostia: Mathematical Connections in Art, Music, and Science, pp.195-202. 2007.
[2] B.G. Thomas and M.A. Hann, Patterns in the Plane and Beyond: Symmetry in Two and Three Dimensions. Monograph no. 37 in the Ars Textrina series, The University of Leeds International Textiles Archive (ULITA). 2007.
[3] B.G. Thomas and M.A. Hann, Patterning by Projection: Tiling the Dodecahedron and other Solids, in R. Sarhangi and C. Séquin (eds.) Bridges Leeuwarden: Mathematical Connections in Art, Music, and Science, pp.101-108. 2008.
[4] D.K. Washburn and D.W. Crowe, Symmetries of Culture: Theory and Practice of Plane Pattern Analysis. Seattle, University of Washington Press, chapter 3. 1988.
[5] I. Hargittai and M. Hargittai, Symmetry: A Unifying Concept, Bolinas, California, Shelter Publications, p.116. 1994.
[6] E.H. Gombrich, The Sense of Order, Oxford, Phaidon Press Ltd. 1979.
[7] H.J. Woods, The Geometrical Basis of Pattern Design. Part 4: Counterchange Symmetry in Plane Patterns, Journal of the Textile Institute, Transactions, 27, T305-T320. 1936.
[8] M.A. Hann and G.M. Thomson, The Geometry of Regular Repeating Patterns, The Textile Institute, Manchester. 1992.
[9] D. Schattschneider, Visions of Symmetry. Notebooks, Periodic Drawings and Related Works of M.C. Escher, New York, Freeman, p.100. 1990.
[10] R.L.E. Schwarzenberger, Color Symmetry, Bulletin of the London Mathematical Society, 16, pp. 209-240. 1984.
[11] D. Schattschneider, In Black and White: How to Create Perfectly Colored Symmetric Patterns, Comp. & Maths. with Appls. 12B, 3/4, pp.673-695. 1986.
[12] H.S.M. Coxeter, Colored Symmetry, in H.S.M. Coxeter et al. (eds.) M.C. Escher: Art and Science, Amsterdam and New York, Elsevier, pp.15-33. 1986.
[13] N.V. Belov and T.N. Tarkhova, Dichromatic Plane Groups, in A.V. Shubnikov and N.V. Belov (eds.) Colored Symmetry, New York, Pergamon. 1964.
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Full Text
http://archive.bridgesmathart.org/2009/bridges2009-177.pdf