Hyperelliptic curve: Difference between revisions

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In [[algebraic geometry]] a hyperelliptic curve is an algebraic curve <math>C</math> which admits a double cover <math>f:C\to\mathbb{P}^1</math>. If such a double cover exists it is unique, and it is called the "hyperelliptic double cover". The involution induced on the curve <math>C</math> 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".
In [[algebraic geometry]] a hyperelliptic curve is an algebraic curve <math>C</math> fo genus geate then 1, which admits a double cover <math>f:C\to\mathbb{P}^1</math>. If such a double cover exists it is unique, and it is called the "hyperelliptic double cover". The involution induced on the curve <math>C</math> 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 ===
=== Weierstrass points ===
By the [[Riemann-Hurwitz formula]] the hyperelliptic double cover has exactly <math>2g+2</math> branch points. For each branch point <math>p</math> we have <math>h^0(2p)= 2</math>.  Hence these points are all Weierstrass points. Moreover, we see that for each of these points <math>h^0((2(k+1))p)\geq h^0(2kp)+1</math>, and thus the [[Weierstrass weight]] of each of these points is at least <math>\sum_{k=1}^g (2k-k)=g(g-1)/2</math>. However, by the second part of the [[Weierstrass gap theorem]], the total weight  of Weierstrass points is <math>g(g^2-1)</math>, and thus the Weierstrass points of <math>C</math> are exactly the branch points of the hyperelliptic double cover.
By the [[Riemann-Hurwitz formula]] the hyperelliptic double cover has exactly <math>2g+2</math> branch points. For each branch point <math>p</math> we have <math>h^0(2p)= 2</math>.  Hence these points are all Weierstrass points. Moreover, we see that for each of these points <math>h^0((2(k+1))p)\geq h^0(2kp)+1</math>, and thus the [[Weierstrass weight]] of each of these points is at least <math>\sum_{k=1}^g (2k-k)=g(g-1)/2</math>. However, by the second part of the [[Weierstrass gap theorem]], the total weight  of Weierstrass points is <math>g(g^2-1)</math>, and thus the Weierstrass points of <math>C</math> are exactly the branch points of the hyperelliptic double cover.


Given a set <math>B</math> of <math>2g+2</math> distinct points on <math>\mathbb{P}^1</math>, there is a uniqe double cover of <math>C\to\mathbb{P}^1</math> whose [[branch divisor]] is the set <math>B</math>. From an algebro-geometric point of view this on can construct the curve <math>C</math> by taking the <math>Proj</math> of the sheaf whose sections <math>g</math> over an open subset <math>U\subset\mathbb{P}^1</math> satisfy <math>g^2\in O_U(B)</math>.
=== The plane model ===
=== Curves of genus 2 ===
=== Curves of genus 2 ===
If the genus of <math>C</math> is 2, then the degree of the [[canonical class]] <math>K_C</math> is 2, and <math>h^0(K_C)=2</math>. Hence the [[canonical map]] is a double cover.
If the genus of <math>C</math> is 2, then the degree of the [[canonical class]] <math>K_C</math> is 2, and <math>h^0(K_C)=2</math>. Hence the [[canonical map]] is a double cover.
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== Moduli of hyperelliptic curves ==
== Moduli of hyperelliptic curves ==
Since for any set <math>B</math> of <math>2g+2</math> on <math>\mathbb{P}^1</math> there is a unique double cover <math>C\to\mathbb{P}^1</math> branch divisor <math>B</math>, the [[course moduli space]] of hyperelliptic curves of genus <math>g</math> is isomorphic to the moduli of <math>2g+2</math> points on  <math>\mathbb{P}^1</math>, up to projective transformations. However, as there are more then three points in <math>B</math>, there is a finite non-empty subset of <math>Aut(\mathbb{P}^1)=PGL_2</math> that send three of the points in <math>B</math> to <math>0,1,\infty</math>. Thus, the moduli of <math>2g+2</math> distinct points on <math>\mathbb{P}^1</math> up to projective transformations is a finite quotient of the space of distincit <math>2g-1</math> on <math>\mathbb{P}^1\setminus\{0,1,\infty\}</math>. Specifically this space is an [[affine space]] of dimension <math>2g-1</math>.


=== Binary forms ===
=== Binary forms ===

Revision as of 11:18, 24 February 2007

In algebraic geometry a hyperelliptic curve is an algebraic curve fo genus geate then 1, which admits a double cover . If such a double cover exists it is unique, and it is called the "hyperelliptic double cover". The involution induced on the curve 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 branch points. For each branch point we have . Hence these points are all Weierstrass points. Moreover, we see that for each of these points , and thus the Weierstrass weight of each of these points is at least . However, by the second part of the Weierstrass gap theorem, the total weight of Weierstrass points is , and thus the Weierstrass points of are exactly the branch points of the hyperelliptic double cover.

Given a set of distinct points on , there is a uniqe double cover of whose branch divisor is the set . From an algebro-geometric point of view this on can construct the curve by taking the of the sheaf whose sections over an open subset satisfy .

The plane model

Curves of genus 2

If the genus of is 2, then the degree of the canonical class is 2, and . Hence the canonical map is a double cover.

The canonical embedding

If is a rational point on a hyperelliptic curve, then for all we have . Hence we must have . However, by Riemann-Roch this implies that the divisor is rationally equivalent to the canonical class . Hence the canonical class of is times the hyperelliptic class of , and the canonical image of is a rational curve of degree .

Moduli of hyperelliptic curves

Since for any set of on there is a unique double cover branch divisor , the course moduli space of hyperelliptic curves of genus is isomorphic to the moduli of points on , up to projective transformations. However, as there are more then three points in , there is a finite non-empty subset of that send three of the points in to . Thus, the moduli of distinct points on up to projective transformations is a finite quotient of the space of distincit on . Specifically this space is an affine space of dimension .

Binary forms

Stable hyperelliptic curves