Artin–Schreier curve

In mathematics, an Artin–Schreier curve is a plane curve defined over an algebraically closed field of characteristic by an equation

for some rational function 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

for some polynomials and .

Definition

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More generally, an Artin-Schreier curve defined over an algebraically closed field of characteristic   is a branched covering

 

of the projective line of degree  . Such a cover is necessarily cyclic, that is, the Galois group of the corresponding algebraic function field extension is the cyclic group  . In other words,   is an Artin–Schreier extension.

The fundamental theorem of Artin–Schreier theory implies that such a curve defined over a field   has an affine model

 

for some rational function   that is not equal to   for any other rational function  . In other words, if for   we define the rational function  , then we require that  .

Ramification

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Let   be an Artin–Schreier curve. Rational function   over an algebraically closed field   has partial fraction decomposition

 

for some finite set   of elements of   and corresponding non-constant polynomials   defined over  , and (possibly constant) polynomial  . After a change of coordinates,   can be chosen so that the above polynomials have degrees coprime to  , and the same either holds for   or it is zero. If that is the case, we define

 

Then the set   is precisely the set of branch points of the covering  .

For example, Artin–Schreier curve  , where   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   lies a single ramification point   with corresponding different exponent (not to confused with the ramification index) equal to

 

Genus

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Since   does not divide  , ramification indices   are not divisible by   either. Therefore, the Riemann–Roch theorem may be used to compute that the genus of an Artin–Schreier curve is given by

 

For example, for a hyperelliptic curve defined over a field of characteristic   by equation   with   decomposed as above,

 

Generalizations

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Artin–Schreier curves are a particular case of plane curves defined over an algebraically closed field   of characteristic   by an equation

 

for some separable polynomial   and rational function  . Mapping   yields a covering map from the curve   to the projective line  . Separability of defining polynomial   ensures separability of the corresponding function field extension  . If  , a change of variables can be found so that   and  . 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

 

each of degree  , starting with the projective line.

See also

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References

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  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.