1. Spherical Geometry
Patrick Showers
Michelle Zrebiec

2. Why is this important …
One application of Spherical Geometry is that pilots and ship captains need to navigate the earth to reach their destination.
For example, did you know that the shortest flying distance from Florida to the Philippine Islands is a path across Alaska?
The Philippines are South of Florida – so why is flying North to Alaska a short-cut?
The answer is that Florida, Alaska, and the Philippines are collinear locations in Spherical Geometry (they lie on a "Great Circle")

3. The Basics!
Sphere
A set of points in three dimensional space equidistant from the center.
Radius
Distance from the center to the points on the sphere
Diameter
Twice the radius

4. Points on Sphere Points are only on the surface of a sphere
Points are the same concept we are used to studying in absolute and Euclidean geometry
Special pairs of points:
Called antipodal or polar
those points that correspond to opposite ends of a diameter of the sphere. Example: N & S poles

5. What are lines?
Shortest path on the sphere between two points on the sphere’s surface
Known as great circles or arcs
A great circle is a circle on a sphere which divides the sphere in 2 equal hemispheres; it contains a diameter of the sphere and hence the center as well

6. Planes intersecting with Sphere
3 cases involving planes and spheres
The plane misses the sphere
The plane hits the sphere at 1 point
Known as a tangent plane
The plane and the sphere meet in a circle

7. Planes Intersecting Sphere
The circle of intersection will be largest when the plane passes through the center of the sphere
Paradoxically, larger radius means less distance traveled on the surface (closest to Euclidean distance) 7

8. Lines - Arcs
In absolute geometry, an axiom states any two points determine a unique line
This is NOT true in Spherical Geometry
To see this, think about the North and South poles of the Earth.
Is there more than one great circle that runs trough them?
Is this true for any 2 points? When are two points contained in infinitely many arcs and when is there a unique arc containing two points?
Are there conditions guaranteeing uniqueness of segments connecting two points? 8

9. Plane of the Sphere
There is only ONE plane that exists in spherical geometry
The plane is the surface of the sphere 9

10. Distance
Given two points A and B on the sphere, the distance AB* between them is length of the shortest arc-segment which connects them.
Because of the way we defined spherical ‘lines’, this arc- segment must be an arc of a great circle.
Joining our points A and B to the center of the sphere, to create a 'wedge' shape. We can measure the angle at the center - call it θ.
The length of our arc is then rθ. 10

11. Distance in Picture FormB
The length of our arc is then rθ. 11

12. Betweenness A-B-C holds if and only if
A,B, & C are distinct points of a great circle
AB* + BC* = AC*
Activity: What does betweenness look like on a sphere? 12

13. Angles
Imagine two great circles on the sphere. Choose one of the two points where they intersect. The angle between the two arcs is then defined to be the angle between the two planes containing the great circles. 13

14. Additional Angle Definition
Imagine a flat, transparent plane which just touches the sphere at the point we wish to measure our angle. Looking at the plane from directly above, arcs on the sphere coincide with lines on the plane. The angle between our spherical lines is then the angle between the corresponding lines on the plane 14

15. Triangles
A spherical triangle consists of three vertices, and three arc-segments which join them.
Note that the lines do not have to be the shorter arcs.
Also, if any two points are antipodal, we must specify which great circle to be the arc joining them (as there are an infinite number of great circles containing both points). 15

16. Question …
Does the sum of the angles of a triangle equal 180 in spherical geometry?? 16

17. Answer …. The angle sum will never be 180°
Always 180° < A + B + C < 540° B A C 17

18. Girard’s Theorem for Triangular Area
Consider a (small) spherical triangle with vertices A, B, and C noncollinear
Note that A, B, and C are the intersections of arcs a, b, and c so that we have polar points A’,B’, and C’ also
A and A’ are the endpoints of two two lunes, call them Lα and Lα’ Similarly for points B, B’ and C, C’. 18

19. Girard’s Theorem Con’t
A(Lα U Lα’) + A(Lβ U Lβ’) + A(Lγ U Lγ’)
= A(sphere) + 2A(ΔABC) +2A(ΔA’B’C’)
since Lβ and Lγ each overcount the area of ΔABC. (Similarly for ΔA’B’C’ with lunes Lβ’ and Lγ’)
2(2α+2β+2γ) = 4π + 4A(ΔABC)
α+β+γ = π + A(ΔABC) and thus
A(ΔABC) = α+β+γ - π (Girard’s Theorem) 19

20. Spherical Excess
Given a spherical ΔABC with angles α, β, and γ, the quantity α+β+γ-π is called the spherical excess of ΔABC.
Girard’s theorem tells us that area of a spherical polygon is intimately linked with the spherical excess. 20

21. Spherical Trigonometry21

22. Theorem AAA Congruence Criterion
If two triangles have three angles of one congruent, respectively, to the three angles of the other, the triangles are congruent 22

23. References http://noneuclidean.tripod.com/applications.html
The book