Artin-Schreier polynomial: Difference between revisions
imported>Richard Pinch m (typo) |
imported>Richard Pinch (kernel of A) |
||
Line 5: | Line 5: | ||
:<math>A_\alpha(X) = X^p - X - \alpha \,</math> | :<math>A_\alpha(X) = X^p - X - \alpha \,</math> | ||
for α in ''F''. The function <math>A : X \mapsto X^p - X</math> is ''p''-to-one since <math>A(x) = A(x+1)</math>. It is in fact <math>\mathbf{F}_p</math>-linear on ''F'' as a [[vector space]]. | for α in ''F''. The function <math>A : X \mapsto X^p - X</math> is ''p''-to-one since <math>A(x) = A(x+1)</math>. It is in fact <math>\mathbf{F}_p</math>-linear on ''F'' as a [[vector space]], with kernel the one-dimensional subspace generated by <math>1_F</math>, that is, <math>\mathbf{F}_p</math> itself. | ||
Suppose that ''F'' is finite of characteristic ''p''. The Frobenius map is an automorphism and so its [[inverse function|inverse]], the ''p''-th root map is defined everywhere, and ''p''-th roots do not generate any non-trivial extensions. | Suppose that ''F'' is finite of characteristic ''p''. The Frobenius map is an automorphism and so its [[inverse function|inverse]], the ''p''-th root map is defined everywhere, and ''p''-th roots do not generate any non-trivial extensions. | ||
If ''F'' is finite, then ''A'' is exactly ''p''-to-1 and the image of ''A'' is a <math>\mathbf{F}_p</math>-subspace of codimension 1. There is always some element α of ''F'' not in the image of ''A'', and so the corresponding Artin-Schreier polynomial has no root in ''F'': it is an [[irreducible polynomial]] and the [[quotient ring]] <math>F[X]/\langle A_\alpha(X) \rangle</math> is a field which is a degree ''p'' extension of ''F''. Since finite fields of the same order are unique up to isomorphism, we may say that this is "the" degree ''p'' extension of ''F''. As before, both roots of the equation lie in the extension, which is thus a ''[[splitting field]]'' for the equation and hence a [[Galois extension]]: in this case the roots are of the form <math>\beta,~\beta+1, \ldots,\beta+(p-1)</math>. | If ''F'' is finite, then ''A'' is exactly ''p''-to-1 and the image of ''A'' is a <math>\mathbf{F}_p</math>-subspace of codimension 1. There is always some element α of ''F'' not in the image of ''A'', and so the corresponding Artin-Schreier polynomial has no root in ''F'': it is an [[irreducible polynomial]] and the [[quotient ring]] <math>F[X]/\langle A_\alpha(X) \rangle</math> is a field which is a degree ''p'' extension of ''F''. Since finite fields of the same order are unique up to isomorphism, we may say that this is "the" degree ''p'' extension of ''F''. As before, both roots of the equation lie in the extension, which is thus a ''[[splitting field]]'' for the equation and hence a [[Galois extension]]: in this case the roots are of the form <math>\beta,~\beta+1, \ldots,\beta+(p-1)</math>. |
Revision as of 14:59, 5 December 2008
In field theory, an Artin-Schreier polynomial is a polynomial whose roots are used to generate field extensions of prime degree p in characteristic p.
An Artin-Schreier polynomial over field F is of the form
for α in F. The function is p-to-one since . It is in fact -linear on F as a vector space, with kernel the one-dimensional subspace generated by , that is, itself.
Suppose that F is finite of characteristic p. The Frobenius map is an automorphism and so its inverse, the p-th root map is defined everywhere, and p-th roots do not generate any non-trivial extensions.
If F is finite, then A is exactly p-to-1 and the image of A is a -subspace of codimension 1. There is always some element α of F not in the image of A, and so the corresponding Artin-Schreier polynomial has no root in F: it is an irreducible polynomial and the quotient ring is a field which is a degree p extension of F. Since finite fields of the same order are unique up to isomorphism, we may say that this is "the" degree p extension of F. As before, both roots of the equation lie in the extension, which is thus a splitting field for the equation and hence a Galois extension: in this case the roots are of the form .