Post on 22-Dec-2015
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 1
Slicing up hyperbolic tetrahedra: from the infinite to the finite
Yana Mohanty
University of California, San Diego
mohanty@math.ucsd.edu
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 2
Outline of method
Motivation
Scissors congruence problemsStudy of hyperbolic 3-manifolds
Spherical 2-D geometry
Hyperbolic 2-D geometry
Hyperbolic 3-D geometry
Hyperbolic tetrahedra
Problem statement: Construct a finite tetrahadron out of ideal tetrahedra
Overview
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 3
Spherical geometry
•Triangles are “plump”
•Any 2-dimensional map distorts angles and/or lengths
•“Lines” are great circles
•Each pair of lines intersects in two points
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 4
The Mercator projection: a conformal map
of the sphere
Angles shown arethe true angles!(conformal)
Areas near polesare greatly distorted
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 5
Hyperbolic geometry:
•Triangles are “skinny”
•Any 2-dimensional map distorts angles and/or lengths.
the “opposite” of spherical geometry
A piece of a hyperbolic surface in space
•Given a point P and a line L there are many lines through P that do not intersect L.
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 6
The Poincare model of the hyperbolic plane
•Preserves angles (conformal)
•Distorts lengths
Escher’s Circle Limit I
lines
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 7
Hyperbolic space
PLANES
LINES
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 8
The Poincare and upper half-space models (obtained by inversion)
z>0
metric:
2
2222
z
dzdydxds
dd
1Inversion:
metric:
2222
2222
)](1[4
zyx
dzdydxds
;1222 zyx
z=0
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 9
H3: The upper halfspace model
(obtained by inversion)
metric:
2
2222
z
dzdydxds
z=0
z>0
“point at infinity”
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 10
Lines and planes in the half-plane model of hyperbolic space
PLANES
lines
Contains point at infinity
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 11
Ideal tetrahedron in H3 (Poincare model)
Convex hull of 4 points at the sphere at infinity
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 12
Ideal tetrahedron in H3
(half-space model)
A
B
C
B
CA
View from above
Determined by triangle ABC
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 13
Hyperbolic tetrahedra
ideal: 2 parameters ¾-ideal: 3 parameters finite: 6 parameters
1 or 2 ideal vertices also possible
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 14
Problem statement:
How do you make
out of finitely many of these?
The rules:•an ideal tetrahedron may count as + or –•use finitely many planar cuts
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 15
What is this needed for: part IStudy of hyperbolic 3-manifolds
2-Manifold: An object which is homeomorphic to a plane near every one of its points.
can be stretched into without tearing
A 2 manifold may NOTcontain
Can’t be stretched into a plane near this point
Example of a Euclidean 2-manifold
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 16
Euclidean 3-manifold
Example: 3-Torus
Glue together opposite faces
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 17
Hyperbolic 3-manifold
Example: the Seifert-Weber space
Glue together opposite faces
Image by Matthias Weber
Drawing from Jeff Weeks’Shape of Space
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 18
A strange and amazing fact:
The volume of a hyperbolic 3-manifold is a topological invariant
(There is a continuous 1-1 map from X to Y with a continuous inverse)
Homeomorphic
3-manifold X 3-manifold Y
X and Y have the same volume
Volume computation generally requires triangulating, that is, cutting up the manifold into tetrahedra.
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 19
Triangulating a hyperbolic 2-manifold
glue
In hyperbolic space triangulation involves finite tetrahedra (6-parameters)
Better: express in terms of ideal tetrahedra (2-parameters)
Drawing by Tadao Ito
Finite hyperbolic octagon 2-holed torus
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 20
What is this needed for: part II
Solving scissors congruence problems in hyperbolic space:
Given 2 polyhedra of equal volume, can one be cut up into a finite number of pieces that can be reassembled into the other one?
Example in Euclidean space:
“Hill’s tetrahedron”
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 21
An expression for volume that also gives a canonical decompositon?
Exists for ideal tetrahedra:
V
where duu
0
sin2log)( is the Lobachevsky function.
finite!
volume=
volume=
volume=(hidden)
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 22
Geometric
•Mentioned as unknown by W. Neumann in 1998 survey article on 3-manifolds.
•Indications of construction given by Sah in 1981, but these were not well known.
Construction of a 3/4-ideal tetrahedron out of ideal tetrahedra:
extends “volume formula as a decomposition” ideato tetrahedra with finite vertex 1
Algebraic
Proved in 1982 by Dupont and Sah using homology.
History:
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 23
Make a a certain type of ¾-ideal tetrahedron first
Main idea behind proof
+ -=
a
b
c
d
a
d
c
p
b
c
d
pp
rotated{a,b,c,p}
Inspiration for choosing ideal tetrahedra: another proof of Dupont and Sah
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 24
Remainder of the proof
Making a finite tetrahedron out of ¾-ideal tetrahedra
A
BC
D
Step 1: finite out of 1-ideal
AB
C
DE
E
Step 2: 1-ideal out of ¾-ideal
AB
C
E
A’
B’C’
ABCE=A’B’C’E-A’B’BE-B’C’CE-C’A’AE
ABCD=ABCE-ABDE
finite 1-ideal1-ideal idea
l¾-ideal
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 25
Summary
•Introduced hyperbolic tetrahedra
• Comparison of spherical and hyperbolic geometries
• Examples of conformal modelsSpherical: Mercator projectionHyperbolic: Poincare ball
Yana Mohanty, University of California, San Diego, mohanty@math.ucsd.edu p. 26
Summary, continued
•Main ingredient: constructing a certain ¾-ideal tetrahedron out of ideal tetrahedra. Idea comes from a proof by Dupont and Sah.
•Constructing a finite tetrahedron out of ideal ones is helpful for studying-hyperbolic 3-manifolds volume is an invariant, so construction is helpful in the 3-dimensional equivalent of
-scissors congruences want volume formula that is also a decomposition