Hyperelliptic curve

In algebraic geometry a hyperelliptic curve is an algebraic curve ${\displaystyle C}$ fo genus geate then 1, which admits a double cover ${\displaystyle f:C\to \mathbb {P} ^{1}}$. If such a double cover exists it is unique, and it is called the "hyperelliptic double cover". The involution induced on the curve ${\displaystyle C}$ by the interchanging between the two "sheets" of the double cover is called the "hyperelliptic involution". The divisor class of a fiber of the hyperelliptic double cover is called the "hyperelliptic class".

Weierstrass points

By the Riemann-Hurwitz formula the hyperelliptic double cover has exactly ${\displaystyle 2g+2}$ branch points. For each branch point ${\displaystyle p}$ we have ${\displaystyle h^{0}(2p)=2}$. Hence these points are all Weierstrass points. Moreover, we see that for each of these points ${\displaystyle h^{0}((2(k+1))p)\geq h^{0}(2kp)+1}$, and thus the Weierstrass weight of each of these points is at least ${\displaystyle \sum _{k=1}^{g}(2k-k)=g(g-1)/2}$. However, by the second part of the Weierstrass gap theorem, the total weight of Weierstrass points is ${\displaystyle g(g^{2}-1)}$, and thus the Weierstrass points of ${\displaystyle C}$ are exactly the branch points of the hyperelliptic double cover.

Given a set ${\displaystyle B}$ of ${\displaystyle 2g+2}$ distinct points on ${\displaystyle \mathbb {P} ^{1}}$, there is a uniqe double cover of ${\displaystyle C\to \mathbb {P} ^{1}}$ whose branch divisor is the set ${\displaystyle B}$. From an algebro-geometric point of view this on can construct the curve ${\displaystyle C}$ by taking the ${\displaystyle Proj}$ of the sheaf whose sections ${\displaystyle g}$ over an open subset ${\displaystyle U\subset \mathbb {P} ^{1}}$ satisfy ${\displaystyle g^{2}\in O_{U}(B)}$.

The plane model

Curves of genus 2

If the genus of ${\displaystyle C}$ is 2, then the degree of the canonical class ${\displaystyle K_{C}}$ is 2, and ${\displaystyle h^{0}(K_{C})=2}$. Hence the canonical map is a double cover.

The canonical embedding

If ${\displaystyle p}$ is a rational point on a hyperelliptic curve, then for all ${\displaystyle k}$ we have ${\displaystyle h^{0}((2(k+1))p)\geq h^{0}(2kp)+1}$. Hence we must have ${\displaystyle h^{0}((2g-2)p)\geq g}$. However, by Riemann-Roch this implies that the divisor ${\displaystyle (2g-2)p}$ is rationally equivalent to the canonical class ${\displaystyle K_{C}}$. Hence the canonical class of ${\displaystyle C}$ is ${\displaystyle g-1}$ times the hyperelliptic class of ${\displaystyle C}$, and the canonical image of ${\displaystyle C}$ is a rational curve of degree ${\displaystyle g-1}$.

Moduli of hyperelliptic curves

Since for any set ${\displaystyle B}$ of ${\displaystyle 2g+2}$ on ${\displaystyle \mathbb {P} ^{1}}$ there is a unique double cover ${\displaystyle C\to \mathbb {P} ^{1}}$ branch divisor ${\displaystyle B}$, the course moduli space of hyperelliptic curves of genus ${\displaystyle g}$ is isomorphic to the moduli of ${\displaystyle 2g+2}$ points on ${\displaystyle \mathbb {P} ^{1}}$, up to projective transformations. However, as there are more then three points in ${\displaystyle B}$, there is a finite non-empty subset of ${\displaystyle Aut(\mathbb {P} ^{1})=PGL_{2}}$ that send three of the points in ${\displaystyle B}$ to ${\displaystyle 0,1,\infty }$. Thus, the moduli of ${\displaystyle 2g+2}$ distinct points on ${\displaystyle \mathbb {P} ^{1}}$ up to projective transformations is a finite quotient of the space of distincit ${\displaystyle 2g-1}$ on ${\displaystyle \mathbb {P} ^{1}\setminus \{0,1,\infty \}}$. Specifically this space is an affine space of dimension ${\displaystyle 2g-1}$.

Binary forms

Stable hyperelliptic curves