Elliptic curve

An elliptic curve over a field ${\displaystyle K}$ is a one dimensional Abelian variety over ${\displaystyle K}$. Alternatively it is a smooth algebraic curve of genus one together with marked point - the identity element.

Curves of genus 1 as smooth plane cubics

If ${\displaystyle f(x,y,z)}$ is a homogenous cubic polynomial in three variables, such that at no point ${\displaystyle (x:y:z)\in \mathbb {P} ^{2}}$ all the three derivatives of f are simultaneously zero, then the Null set ${\displaystyle E:=\{(x:y:z)\in \mathbb {P} ^{2}|f(x,y,z)=0\}\subset \mathbb {P} ^{2}}$ 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 ${\displaystyle H}$ be the class of line in the Picard group ${\displaystyle Pic(P^{2})}$, then ${\displaystyle E}$ is rationally equivalent to ${\displaystyle 3H}$. Then by the adjunction formula we have ${\displaystyle \#K_{E}=(K_{\mathbb {P} ^{2}}+[E])[E]=(-3H+3H)3H=0}$.
• By the genus degree formula for plane curves we see that ${\displaystyle genus(E)=(3-1)(3-2)/2=1}$
• If we choose a point ${\displaystyle p\in E}$ and a line ${\displaystyle L\subset \mathbb {P} ^{2}}$ such that ${\displaystyle p\not \in L}$, we may project ${\displaystyle E}$ to ${\displaystyle L}$ by sending a point ${\displaystyle q\in E}$ to the intersection point ${\displaystyle {\overline {pq}}\cap L}$ (if ${\displaystyle p=q}$ take the line ${\displaystyle T_{p}(E)}$ instead of the line ${\displaystyle {\overline {pq}}}$). This is a double cover of a line with four ramification points. Hence by the Riemann-Hurwitz formula ${\displaystyle genus(E)-1=-2+4/2=0}$

On the other hand, if ${\displaystyle C}$ is a smooth algebraic curve of genus 1, and ${\displaystyle p,q,r}$ are points on ${\displaystyle C}$, then by the Riemann-Roch formula we have ${\displaystyle h^{0}(O_{C}(p+q+r))=3-(1-1)-h^{0}(-(p+q+r))=3.}$

Hence the complete linear system ${\displaystyle |O_{C}(p+q+r)|}$ is two dimensional, and the map from ${\displaystyle C}$ to the dual linear system is an embedding.

The group operation on a pointed smooth plane cubic

Let ${\displaystyle E}$ be as above, and ${\displaystyle O}$ point on ${\displaystyle E}$. If ${\displaystyle p}$ and ${\displaystyle q}$ are two points on ${\displaystyle E}$ we set ${\displaystyle p*q:={\overline {pq}}\cap E\setminus \{p,q\},}$ where if ${\displaystyle p=q}$ we take the line ${\displaystyle T_{p}(E)}$ instead, and the intersection is to be understood with multiplicities. The addition on he elliptic curve ${\displaystyle E}$ is defined as ${\displaystyle p+q:=O*(p*q)}$. Both the commutativity and the existence of inverse follow from the definition. The proof of the associativity of this operation is more delicate.

The Weierstrass form

The ${\displaystyle j}$ invariant

Elliptic curves over the complex numbers

Lattices in the complex numbers

modular forms

Theta functions

For the main article see Theta function

Weierstrass's ${\displaystyle \wp }$ 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

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