Artin–Schreier curve

In mathematics, an Artin–Schreier curve is a plane curve defined over an algebraically closed field of characteristic ${\displaystyle p}$ by an equation

${\displaystyle y^{p}-y=f(x)}$

for some rational function ${\displaystyle f}$ over that field.

One of the most important examples of such curves is hyperelliptic curves in characteristic 2, whose Jacobian varieties have been suggested for use in cryptography.^[1] It is common to write these curves in the form

${\displaystyle y^{2}+h(x)y=f(x)}$

for some polynomials ${\displaystyle f}$ and ${\displaystyle h}$.

Definition

More generally, an Artin-Schreier curve defined over an algebraically closed field of characteristic ${\displaystyle p}$  is a branched covering

${\displaystyle C\to \mathbb {P} ^{1}}$ 

of the projective line of degree ${\displaystyle p}$ . Such a cover is necessarily cyclic, that is, the Galois group of the corresponding algebraic function field extension is the cyclic group ${\displaystyle \mathbb {Z} /p\mathbb {Z} }$ . In other words, ${\displaystyle k(C)/k(x)}$  is an Artin–Schreier extension.

The fundamental theorem of Artin–Schreier theory implies that such a curve defined over a field ${\displaystyle k}$  has an affine model

${\displaystyle y^{p}-y=f(x),}$ 

for some rational function ${\displaystyle f\in k(x)}$  that is not equal for ${\displaystyle z^{p}-z}$  for any other rational function ${\displaystyle z}$ . In other words, if we define polynomial ${\displaystyle g(z)=z^{p}-z}$ , then we require that ${\displaystyle f\in k(x)\backslash g(k(x))}$ .

Ramification

Let ${\displaystyle C:y^{p}-y=f(x)}$  be an Artin–Schreier curve. Rational function ${\displaystyle f}$  over an algebraically closed field ${\displaystyle k}$  has partial fraction decomposition

${\displaystyle f(x)=f_{\infty }(x)+\sum _{\alpha \in B'}f_{\alpha }\left({\frac {1}{x-\alpha }}\right)}$ 

for some finite set ${\displaystyle B'}$  of elements of ${\displaystyle k}$  and corresponding non-constant polynomials ${\displaystyle f_{\alpha }}$  defined over ${\displaystyle k}$ , and (possibly constant) polynomial ${\displaystyle f_{\infty }}$ . After a change of coordinates, ${\displaystyle f}$  can be chosen so that the above polynomials have degrees coprime to ${\displaystyle p}$ , and the same either holds for ${\displaystyle f_{\infty }}$  or it is zero. If that is the case, we define

${\displaystyle B={\begin{cases}B'&{\text{ if }}f_{\infty }=0,\\B'\cup \{\infty \}&{\text{ otherwise.}}\end{cases}}}$ 

Then the set ${\displaystyle B\subset \mathbb {P} ^{1}(k)}$  is precisely the set of branch points of the covering ${\displaystyle C\to \mathbb {P} ^{1}}$ .

For example, Artin–Schreier curve ${\displaystyle y^{p}-y=f(x)}$ , where ${\displaystyle f}$  is a polynomial, is ramified at a single point over the projective line.

Since the degree of the cover is a prime number, over each branching point ${\displaystyle \alpha \in B}$  lies a single ramification point ${\displaystyle P_{\alpha }}$  with corresponding different (not to confused with the ramification index) equal to

${\displaystyle e(P_{\alpha })=(p-1){\big (}\deg(f_{\alpha })+1{\big )}+1.}$ 

Genus

Since ${\displaystyle p}$  does not divide ${\displaystyle \deg(f_{\alpha })}$ , ramification indices ${\displaystyle e(P_{\alpha })}$  are not divisible by ${\displaystyle p}$  either. Therefore, the Riemann–Roch theorem may be used to compute that the genus of an Artin–Schreier curve is given by

${\displaystyle g={\frac {p-1}{2}}\left(\sum _{\alpha \in B}{\big (}\deg(f_{\alpha })+1{\big )}-2\right).}$ 

For example, for a hyperelliptic curve defined over a field of characteristic ${\displaystyle p=2}$  by equation ${\displaystyle y^{2}-y=f(x)}$  with ${\displaystyle f}$  decomposed as above,

${\displaystyle g=\sum _{\alpha \in B}{\frac {\deg(f_{\alpha })+1}{2}}-1.}$ 

Generalizations

Artin–Schreier curves are a particular case of plane curves defined over an algebraically closed field ${\displaystyle k}$  of characteristic ${\displaystyle p}$  by an equation

${\displaystyle g(y^{p})=f(x)}$ 

for some separable polynomial ${\displaystyle g\in k[x]}$  and rational function ${\displaystyle f\in k(x)\backslash g(k(x))}$ . Mapping ${\displaystyle (x,y)\mapsto x}$  yields a covering map from the curve ${\displaystyle C}$  to the projective line ${\displaystyle \mathbb {P} ^{1}}$ . Separability of defining polynomial ${\displaystyle g}$  ensures separability of the corresponding function field extension ${\displaystyle k(C)/k(x)}$ . If ${\displaystyle g(y^{p})=a_{m}y^{p^{m}}+a_{m-1}y^{p^{m-1}}+\cdots +a_{1}y^{p}+a_{0}}$ , a change of variables can be found so that ${\displaystyle a_{m}=a_{1}=1}$  and ${\displaystyle a_{0}=0}$ . It has been shown ^[2] that such curves can be built via a sequence of Artin-Schreier extension, that is, there exists a sequence of cyclic coverings of curves

${\displaystyle C\to C_{m-1}\to \cdots \to C_{0}=\mathbb {P} ^{1},}$ 

each of degree ${\displaystyle p}$ , starting with the projective line.

See also

• Artin–Schreier theory
• Hyperelliptic curve
• Superelliptic curve

References

1. Koblitz, Neal (1989). "Hyperelliptic cryptosystems". Journal of Cryptology. 1 (3): 139–150. doi:10.1007/BF02252872.
2. Sullivan, Francis J. (1975). "p-Torsion in the class group of curves with too many automorphisms". Archiv der Mathematik. 26 (1): 253–261. doi:10.1007/BF01229737.

• Farnell, Shawn; Pries, Rachel (2014). "Families of Artin-Schreier curves with Cartier-Manin matrix of constant rank". Linear Algebra and its Applications. 439 (7): 2158–2166. arXiv:1202.4183. doi:10.1016/j.laa.2013.06.012.