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Slicing Bagels: Plane Sections of Real and Complex Tori Bruce Cohen Lowell High School, SFUSD [email protected] http://www.cgl.ucsf.edu/home/bic David Sklar San Francisco State University [email protected] Asilomar - December 2004 Part I - Slicing a Real Circular Torus Equations for the torus in R3 The Spiric Sections of Perseus Ovals of Cassini and The Lemniscate of Bernoulli Other Slices The Villarceau Circles A Characterization of the torus Part II - Slicing a Complex Torus Elliptic curves and number theory Some graphs of y 2 x( x 2 1) c Hints of toric sections Two closures: Algebraic and Geometric Algebraic closure, C2, R4, and the graph of y 2 x( x 2 1) Geometric closure, Projective spaces P1(R), P2(R), P1(C), and P2(C) The graphs of y 2 x( x 2 1), y 2 x( x 2 n 2 ), and y 2 x( x 2 12 )( x 2 22 ) Bibliography ( x2 g 2 ) Elliptic curves and number theory Roughly, an elliptic curve over a field F is the graph of an equation of the form y 2 p( x ) where p(x) is a cubic polynomial with three distinct roots and coefficients in F. The fields of most interest are the rational numbers, finite fields, the real numbers, and the complex numbers. In 1985, after mathematicians had been working on Fermat’s Last Theorem for about 350 years, Gerhard Frey suggested that if we assumed Fermat’s Last Theorem was false, the existence of an elliptic curve y 2 x( x a n )( x bn ) where a, b and c are distinct integers such that a n bn c n with integer exponent n > 2, might lead to a contradiction. Within a year it was shown that Fermat’s last theorem would follow from a widely believed conjecture in the arithmetic theory of elliptic curves. Less than 10 years later Andrew Wiles proved a form of the Taniyama conjecture sufficient to prove Fermat’s Last Theorem. Elliptic curves and number theory The strategy of placing a centuries old number theory problem in the context of the arithmetic theory of elliptic curves has led to the complete or partial solution of at least three major problems in the last thirty years. The Congruent Number Problem – Tunnell 1983 The Gauss Class Number Problem – Goldfeld 1976, Gross & Zagier 1986 Fermat’s Last Theorem – Frey 1985, Ribet 1986, Wiles 1995, Taylor 1995 Although a significant discussion of the theory of elliptic curves and why they are so nice is beyond the scope of this talk I would like to try to show you that, when looked at in the right way, the graph of an elliptic curve is a beautiful and familiar geometric object. We’ll do this by studying the graph of the equation y 2 x( x 2 1). Graphs of y 2 x( x 2 1) c : Hints of Toric Sections y y x y 2 x( x 2 1) x y 2 x( x 2 1) 0.3 y y x y 2 x( x 2 1) 0.385 x y 2 x( x 2 1) 1 If we close up the algebra to include the complex numbers and the geometry to include points at infinity, we can argue that the graph of y 2 x( x2 1) is a torus. Geometric Closure: an Introduction to Projective Geometry Part I – Real Projective Geometry One-Dimension - the Real Projective Line P1(R) The real projective line P1(R) is the set R The real (affine) line R is the ordinary real number line 0 0 It is topologically equivalent to the open interval (-1, 1) by the map x x (1 x ) 1 0 It is topologically equivalent to a closed interval with the endpoints identified P 1 0 P and topologically equivalent to a punctured and topologically equivalent to a circle circle by stereographic projection by stereographic projection P 0 0 Geometric Closure: an Introduction to Projective Geometry Part I – Real Projective Geometry Two-Dimensions - the Real Projective Plane P2(R) The real (affine) plane R2 is the ordinary x, y -plane y x It is topologically equivalent to the open unit disk by the map (x , y ) (1 x , y x2 y2 1 x2 y2 ) The real projective plane P2(R) is the set R 2 L. It is R2 together with a “line at infinity”, L . Every line in R2 intersects L , parallel lines meet at the same point on L , and nonparallel lines intersect L at distinct points. Every line in P2(R) is a P1(R). It is topologically equivalent to a closed disk with antipodal points on the boundary circle identified. y y x x Two distinct lines intersect at one and only one point. A Projective View of the Conics y y x y x x Parabola Ellipse y y x Hyperbola x A Projective View of the Conics Ellipse Parabola Hyperbola Graphs of y 2 x( x 2 1) c : Hints of Toric Sections y y x x topological view including point at infinity y 2 x( x 2 1) y y 2 x( x 2 1) 0.3 y x y 2 x( x 2 1) 0.385 x y 2 x( x 2 1) 1 If we close up the algebra, by extending to the complex numbers, and the geometry, by including points at infinity we can argue that the graph of y 2 x( x 2 1) is a torus. Graph of y 2 x( x 2 1) with x and y complex Algebraic closure Let x x1 ix2 and y y1 iy2 Then y 2 x( x 2 1) becomes ( y1 iy2 )2 ( x1 ix2 )[( x1 ix2 ) 2 1] Expanding and collecting terms we have ( y12 y2 2 ) i (2 y1 y2 ) ( x13 x1 3x1 x2 2 ) i ( x2 3 x2 3x12 x2 ) Equating real and imaginery parts we have y12 y2 2 x13 x1 3x1 x2 2 and 2 y1 y2 x2 3 x2 3x12 x2 y12 y2 2 x13 x1 3x1 x2 2 2 y1 y2 x2 3 x2 3x12 x2 is a system of two equations in four real unknowns whose graph is a 2-dimensional surface in real 4-dimensional space It's not so easy to graph a 2-surface in 4-space, but we can look at intersections of the graph with some convenient planes. Graph of y 2 x( x 2 1) with x and y complex Algebraic closure y12 y2 2 x13 x1 3x1 x2 2 Some comments on why the graph of the system 2 y1 y2 x2 3 x2 3x12 x2 is a surface. Letting x1 s and x2 t, then solving for y1 and y2 in terms of s and t , we would essentially have x1 s, x2 t , y1 y1 ( s, t ) and y2 y2 ( s, t ) These are parametric equations for a surface in x1 , x2 , y1 , y2 space (a nice mapping of a 2-D s, t plane into 4-D x1, x2 , y1, y2 space.) The situation is a little more complicated in that the algebra leads to several solutions for y1 ( s, t ) and y2 ( s, t ) which can be pieced together to get the whole graph. Graph of y 2 x( x 2 1) with x and y complex Algebraic closure y12 y2 2 x13 x1 3x1 x2 2 2 y1 y2 x2 3 x2 3x12 x2 for x2 0, y2 0 (the x1 , y1 - plane) y 2 x( x 2 1) becomes y12 x1 ( x12 1) y1 for x2 0, y1 0 (the x1, y2 - plane) y 2 x( x 2 1) becomes y2 2 x1 ( x12 1) ( x1 )[( x1 )2 1] y2 x1 x1 Graph of y 2 x( x 2 1) with x and y complex Recall, the graph of y 2 x( x 2 1) in C2 is equivalent to the graph of the system y12 y2 2 x13 x1 3x1 x2 2 4 in R . Now lets look at the intersection of 3 2 y2 2 y1 y2 x2 x2 3x1 x2 the graph with the 3-space x2 0. The system of equations becomes y1 x1 y12 y2 2 x13 x1 2 y1 y2 0 so y2 0 or y1 0 and the intersection (a curve) lies in only the x1, y1 - plane or the x1, y2 - plane. for y2 0, y12 x1 ( x12 1) for y1 0, y2 2 x1 ( x12 1) y2 y1 x1 x1 Graph of y 2 x( x 2 1) with x and y complex The intersection of the graph with the 3-space x2 0 is a curve whose branches lie only the x1 ,y1 - plane or the x1,y2 - plane so we can put together this picture. y1 y2 x1 x1 y 2 x ( x 2 1) in R 4 intersecting the 3-space x2 =0 y2 Topological view in projective C2 (roughly C2 with points at infinity) y1 x1 P 1 0 1 Geometric Closure: an Introduction to Projective Geometry Part II – Complex Projective Geometry One-Dimension - the Complex Projective Line or Riemann Sphere P1(C) (Note: 1-D over the complex numbers, but, 2-D over the real numbers) The complex (affine) line C is the ordinary complex plane where (x, y) corresponds to the number z = x + iy. The complex projective line P1(C) is the set C the complex plane with one number adjoined. y x It is topologically a punctured sphere by stereographic projection It is topologically a sphere by stereographic projection with the north pole corresponding to . It is often called the Riemann Sphere. Geometric Closure: an Introduction to Projective Geometry Part II – Complex Projective Geometry Two-Dimensions - the Complex Projective Plane P2(C) (Note: 2-D over the complex numbers, but, 4-D over the real numbers) The complex (affine) “plane” C2 or better complex 2-space is a lot like R4. A line in C2 is the graph of an equation of the form ax by c, where a, b and c are complex constants and x and y are complex variables. (Note: not every plane in R4 corresponds to a complex line) Complex projective 2-space P2(C) is the set C2 L. It is C2 together with a complex “line at infinity”, L. Every line in R2 intersects L, parallel lines meet at the same point on L, and nonparallel lines intersect L at distinct points. Every line in P2(C) is a P1(C), a Riemann sphere, including the “line at infinity”. Basically P2(C) is C2 closed up nicely by a Riemann Sphere at infinity. Two distinct lines intersect at one and only one point. Graph of y 2 x( x 2 1) with x and y complex The intersection of the graph with the 3-space x2 0 is a curve whose branches lie only the x1 ,y1 - plane or the x1,y2 - plane so we can put together this picture. y1 y2 x1 x1 y 2 x ( x 2 1) in R 4 intersecting the 3-space x2 =0 y2 Topological view in projective C2 (roughly C2 with points at infinity) y1 x1 P 1 0 1 Graph of y 2 x( x 2 1) with x and y complex y2 y1 P x1 y 2 x ( x 2 1) in R 4 intersecting the 3-space x2 =0 intersecting the 3-space x2 = > 0 P 1 0 1 1 0 1 A Generalization: the Graph of y 2 x( x 2 12 )( x 2 22 ) ( x2 g 2 ) y2 y1 x1 The graph of y 2 x( x 2 12 )( x 2 22 )( x 2 32 )( x 2 42 )( x 2 52 ) intersected with the 3-space x2 0 A Generalization: the Graph of y 2 x( x 2 12 )( x 2 22 ) ( x2 g 2 ) y 2 x( x 2 12 )( x 2 22 )( x 2 32 )( x 2 42 )( x 2 52 ) A depiction of the toric graphs of the elliptic curves y 2 x( x 2 n 2 ) by A. T. Fomenko This drawing is the frontispiece of Neal Koblitz's book Introduction to Elliptic Curves and Modular Forms Bibliography 1. E. Brieskorn & H. Knorrer, Plane Algebraic Curves, Birkhauser Verlag, Basel, 1986 2. M. Berger, Geometry I and Geometry II, Springer-Verlag, New York 1987 3. D. Hilbert & H. Cohn-Vossen, Geometry and the Imagination, Chelsea Publishing Company, New York, 1952 4. N. Koblitz, Introduction to Elliptic Curves and Modular Forms, Springer-Verlag, New York 1984 5. K. Kendig, Elementary Algebraic Geometry, Springer-Verlag, New York 1977 6. Z. A. Melzak, Invitation to Geometry, John Wiley & Sons, New York, 1983 7. Z. A. Melzak, Companion to Concrete Mathematics, John Wiley & Sons, New York, 1973 8. T. Needham, Visual Complex Analysis, Oxford University Press, Oxford 1997 9. J. Stillwell, Mathematics and Its History, Springer-Verlag, New York 1989 10. M. Villarceau, "Théorème sur le tore." Nouv. Ann. Math. 7, 345-347, 1848.