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| Crocheting
the Hyperbolic Plane [IFF-L2] Thursday, May 27, 2004 @ 7:30pm |
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| Daina Taimina and David Henderson are mathematicians at Cornell University. They are co-authors of Experiencing Geometry a classic text on euclidean and non-euclidean space. In 1997 Daina worked out how “hyperbolic” space could be modeled by crochet. Since then, she and David have used her woolen models to further explore this peculiar topology. Here, David and Daina will talk about crocheting the hyperbolic plane, the geometry of lettuce, and the architecture of the universe. //Fluted and crenelated, the leaf of a lettuce curves away from itself. From the modest beginning of the stubby stalk where it abuts the stem, to the flared and scalloped edge, the space literally expands, each point seeking to maximize its domain. Lettuces, cabbages and certain types of kelp all embody hyperbolic geometry - the geometric opposite of the sphere. Used to model the World Wide Web and the structure of the human brain, hyperbolic space deviates from rectilinear norms. In “flat” or Euclidean space parallel lines remain equidistant, but on curved surfaces a more complex topology reigns. Think of the surface of the earth: here, lines of Longitude are “parallel” at the equator yet intersect at the poles. In hyperbolic space, parallel lines curve away from each other - the further one travels from any point the more room there is. For Isaac Newton and his followers, physical space was Euclidean -
endless, formless and flat. But in 1919 measurements of starlight bending
around the sun showed that space is intrinsically curved. In one recent
model proposed by physicists, our universe is shaped like soccer ball;
in another it resembles a trumpet. The WMAP satellite currently taking
pictures of the distant cosmos may at last determine which, if any,
of the proposed models describes the global geometry
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