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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 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
Regular Tilings Are there any others?
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)
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.
Periodic vs Aperiodic • Periodic tilings display translational symmetry in two non-parallel directions. • Aperiodic tilings do not display this translational symmetry.
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
Penrose Tilings Roger Penrose
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.
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).
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
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
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
4,5 4,7 4,8 4,10
Semiregular Tilings • Just like in Euclidean, there are also semiregular tilings in Hyperbolic. • This example shows a square and 5 triangles at each vertex.
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.
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
THE END Questions?