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TILINGS

TILINGS. Daniel McNeil April 3, 2007 Math 371. What is a tiling?. A tiling, or tessellation, refers to a collection of figures that cover a plane with no gaps and no overlaps. Tessella is Latin term describing a piece of clay or stone used to make a mosaic. Tiling on the Euclidean Plane.

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TILINGS

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  1. TILINGS Daniel McNeil April 3, 2007 Math 371

  2. What is a tiling? • A tiling, or tessellation, refers to a collection of figures that cover a plane with no gaps and no overlaps. • Tessella is Latin term describing a piece of clay or stone used to make a mosaic

  3. Tiling on the Euclidean Plane

  4. Regular Tilings Are there any others?

  5. Semiregular Tilings (3,12,12) (3,6,3,6) (4,4,3,3,3) (4,6,12) (3,4,6,4) (3,3,3,3,6) (8,8,4) (3,3,4,3,4)

  6. Tilings and Patterns • Book written in 1986 by Branko Grünbaum and G.C. Shepherd. • Remains most extensive collection of work to date. • Took particular interest in periodic and aperiodic tilings.

  7. Periodic vs Aperiodic • Periodic tilings display translational symmetry in two non-parallel directions. • Aperiodic tilings do not display this translational symmetry.

  8. A Question to Consider Is there a polygon that tiles the plane but cannot do so periodically? From Old and New Unsolved Problems in Plane Geometry and Number Theory

  9. Penrose Tilings Roger Penrose

  10. Penrose Tilings • Discovered by Roger Penrose in 1973 • Most prevalent form of aperiodic tilings • No translational symmetry, so never repeats exactly, but does have identical parts • In 1984, Israeli engineer Dany Schectman discovered that aluminum manganese had a penrose crystal structure.

  11. The Golden Tiling • In a Penrose tiling, Nkite/Ndart = Φ • Given a region of diameter d, an identical region can always be found within d(Φ+½).

  12. Other Geometric Applications Topologically Equivalent Tilings Euler Characteristic a=average number of sides per polygon F=number of faces b=average number of sides meeting at a vertex V=number of vertices

  13. Hyperbolic Tilings

  14. Regular Tilings • In Euclidean we saw that the angle of a regular n-gon depends on n. • What about Hyperbolic geometry? • In Hyperbolic, the angle depends on both n and the length of each side. • 0<θ<(n-2)180o/n

  15. Regular Tilings • In Euclidean we could construct a regular tiling with 4 squares at each vertex. • Now in Hyperbolic we need 5 or more. • In general, we have regular hyperbolic tilings of k n-gons whenever 1/n+1/k<1/2 • Result: Infinitely many regular hyperbolic tilings

  16. 1/n+1/k = 1/4+1/6 = 10/24 < 1/2

  17. 4,5 4,7 4,8 4,10

  18. Semiregular Tilings • Just like in Euclidean, there are also semiregular tilings in Hyperbolic. • This example shows a square and 5 triangles at each vertex.

  19. Poincaré Upper Half Plane • The vertical distance between two points is ln(y2/y1). • Faces are all of equal non-Euclidean size. • Image can be transformed from Poincaré Disc to PUHP.

  20. Poincaré Disc vs PUHP

  21. Poincaré Disc vs PUHP

  22. Tilings in Art and Architecture

  23. Tilings in Nature

  24. Resources • Abelson, Harold and DiSessa, Andrea. 1981. Turtle Geometry. Cambridge: MIT Press • Baragar, Arthur. 2001 A Survey of Classical and Modern Geometries: With Computer Activities. New Jersey: Prentice Hall • Klee, Victor and Wagon Stan. 1991. Old and New Unsolved Problems in Plane Geometry and Number Geometry. New York: The Mathematical Association of America • Livio, Mario. 2002 The Golden Ratio. New York: Broadway Books • Stillwell, John. 2005. The Four Pillars of Geometry. New York: Springer • www.wikipedia.org • www.mathworld.wolfram.com

  25. THE END Questions?

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