Elliptic curve: Difference between revisions

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An elliptic curve over the [[complex numbers]] is a [[Riemann surface]] of genus 1, or a two dimensional [[torus]] over the [[real numbers]]. The [[universal cover]] of this torus, as a [[complex manifold]], is the [[complex line]] <math>\mathbb{C}</math>. Hence the elliptic curve is isomorphic to a quotient of the complex numbers by some [[lattice]]; moreover two elliptic curves are isomorphic if and only the two corresponding lattices are isomorphic. Hence the [[moduli]] of elliptic curves  
An elliptic curve over the [[complex numbers]] is a [[Riemann surface]] of genus 1, or a two dimensional [[torus]] over the [[real numbers]]. The [[universal cover]] of this torus, as a [[complex manifold]], is the [[complex line]] <math>\mathbb{C}</math>. Hence the elliptic curve is isomorphic to a quotient of the complex numbers by some [[lattice]]; moreover two elliptic curves are isomorphic if and only the two corresponding lattices are isomorphic. Hence the [[moduli]] of elliptic curves  
over the complex numbers is identified with the moduli of lattices in <math>\mathbb{C}</math> up to [[homothety]]. For each homothety class there is a lattice such that one of the points of the lattice is 1, and the other is some point <math>\tau</math> in the [[upper half plane]] <math>\mathcal{H}</math>. Hence the moduli of lattices in <math>\mathbb{C}</math> is the quotient <math>\mathcal{H}/PSL_2(\mathbb{Z})</math>, where a group element
over the complex numbers is identified with the moduli of lattices in <math>\mathbb{C}</math> up to [[homothety]]. For each homothety class there is a lattice such that one of the points of the lattice is 1, and the other is some point <math>\tau</math> in the [[upper half plane]] <math>\mathcal{H}</math>. Hence the moduli of lattices in <math>\mathbb{C}</math> is the quotient <math>\mathcal{H}/PSL_2(\mathbb{Z})</math>, where a group element
<math>\left(\begin{matrix}a&b\\c&d\end{matrix}\right)\in SL_2(\mathbb{Z})</math> acts on the upper half plane via the [[mobius transformation]] <math>z\mapsto\frac{az+b}{cz+d}</math>. The standard [[fundamental domain]] for this action is the set: <math>\{\tau|-\frac{1}{2}\leqIm(\tau)\leq\frac{1}{2}}</math>.
<math>\left(\begin{matrix}a&b\\c&d\end{matrix}\right)\in SL_2(\mathbb{Z})</math> acts on the upper half plane via the [[mobius transformation]] <math>z\mapsto\frac{az+b}{cz+d}</math>. The standard [[fundamental domain]] for this action is the set: <math>\{\tau|-\frac{1}{2}\leq Im(\tau)\leq\frac{1}{2}}</math>.


=== modular forms ===
=== modular forms ===

Revision as of 03:54, 22 February 2007

An elliptic curve over a field is a one dimensional Abelian variety over . Alternatively it is a smooth algebraic curve of genus one together with marked point.

Curves of genus 1 as smooth plane cubics

If is a homogenous degree 3 (also called "cubic") polynomial in three variables, such that at no point all the three derivatives of f are simultaneously zero, then the Null set is a smooth curve of genus 1. Smoothness follows from the condition on derivatives, and the genus can be computed in various ways; e.g.:

  • Let be the class of line in the Picard group , then is rationally equivalent to . Then by the adjunction formula we have .
  • By the genus degree formula for plane curves we see that
  • If we choose a point and a line such that , we may project to by sending a point to the intersection point (if take the line instead of the line ). This is a double cover of a line with four ramification points. Hence by the Riemann-Hurwitz formula

On the other hand, if is a smooth algebraic curve of genus 1, and are points on , then by the Riemann-Roch formula we have . Choosing a basis to the three dimensional vector space such that is algebraic and , the map given by is an embedding.

The group operation on a pointed smooth plane cubic

Let be as above, and point on . If and are two points on we set where if we take the line instead, and the intersection is to be understood with multiplicities. The addition on the elliptic curve is defined as . Both the commutativity and the existence of inverse follow from the definition. The proof of the associativity of this operation is more delicate.

Weierstrass forms

If the cubic curve admits a flex - i.e. a line which is tri-tangent to at a point (this happens e.g. if the field is algebraically closed), then by a change of coordinates on the projective plane, which takes the line to the line and the point to the point we may assume that the only terms in the cubic polynomial which include , are .

If the characteritic of is not 2 or 3 then by another change of coordinates, the cubic polynomial can be changed to the form . In this case the discriminant of the cubic polynomial on the left hand side of the equation is given by . The invariant of the curve is defined to be . Two elliptic curves are isomorphic if and only if they have the same invariant.

Elliptic curves over the complex numbers

One dimensional complex tori and lattices in the complex numbers

An elliptic curve over the complex numbers is a Riemann surface of genus 1, or a two dimensional torus over the real numbers. The universal cover of this torus, as a complex manifold, is the complex line . Hence the elliptic curve is isomorphic to a quotient of the complex numbers by some lattice; moreover two elliptic curves are isomorphic if and only the two corresponding lattices are isomorphic. Hence the moduli of elliptic curves over the complex numbers is identified with the moduli of lattices in up to homothety. For each homothety class there is a lattice such that one of the points of the lattice is 1, and the other is some point in the upper half plane . Hence the moduli of lattices in is the quotient , where a group element acts on the upper half plane via the mobius transformation . The standard fundamental domain for this action is the set: Failed to parse (syntax error): {\displaystyle \{\tau|-\frac{1}{2}\leq Im(\tau)\leq\frac{1}{2}}} .

modular forms

For the main article see Modular forms Modular forms are functions on the upper half plane, such that for any we have for some which is called the "weight" of the form.

Theta functions

For the main article see Theta function

Weierstrass's function

Application: elliptic integrals

Elliptic curves over number fields

Mordel's theorem

Elliptic curves over finite fields

Application:cryptography

Selected References

Further reading

  • Joseph H. Silverman, John Tate; "Rational Points on Elliptic Curves". ISBN 0387978259.
  • Joseph H. Silverman "The Arithmetic of Elliptic Curves" ISBN 0387962034

Selected external links