Qingquan Wu scite author profile

Let K be a function field over a perfect constant field of positive characteristic p, and L the compositum of n (degree p) Artin-Schreier extensions of K. Then much of the behavior of the degree p n extension L/K is determined by the behavior of the degree p intermediate extensions M/K. For example, we prove that a place of K totally ramifies/is inert/splits completely in L if and only if it totally ramifies/is inert/splits completely in every M . Examples are provided to show that all possible decompositions are in fact possible; in particular, a place can be inert in a non-cyclic Galois function field extension, which is impossible in the case of a number field. Moreover, we give an explicit closed form description of all the different exponents in L/K in terms of those in all the M/K. Results of a similar nature are given for the genus, the regulator, the ideal class number and the divisor class number. In addition, for the case n = 2, we provide an explicit description of the ramification group filtration of L/K.

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An Explicit Treatment of Cubic Function Fields with Applications

Landquist¹,

Rozenhart²,

Scheidler³

et al. 2010

Can. j. math.

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Abstract. We give an explicit treatment of cubic function fields of characteristic at least five. This includes an efficient technique for converting such a field into standard form, formulae for the field discriminant and the genus, simple necessary and sufficient criteria for non-singularity of the defining curve, and a characterization of all triangular integral bases. Our main result is a description of the signature of any rational place in a cubic extension that involves only the defining curve and the order of the base field. All these quantities only require simple polynomial arithmetic as well as a few square-free polynomial factorizations and, in some cases, square and cube root extraction modulo an irreducible polynomial. We also illustrate why and how signature computation plays an important role in computing the class number of the function field. This in turn has applications to the study of zeros of zeta functions of function fields.

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Explicit construction of integral bases of radical function fields

Wu¹

2010

J. Théor. Nombres Bordeaux

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A New Method for Finding Approximate Repetitions in DNA Sequences

Wang

et al. 2006

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Qingquan Wu

Finding LPRs in DNA Sequence Based on a New Index — SUA

The Ramification Groups and Different of a Compositum of Artin–schreier Extensions

An Explicit Treatment of Cubic Function Fields with Applications

Explicit construction of integral bases of radical function fields

A New Method for Finding Approximate Repetitions in DNA Sequences

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Qingquan Wu

Finding LPRs in DNA Sequence Based on a New Index &#8212; SUA

The Ramification Groups and Different of a Compositum of Artin–schreier Extensions

An Explicit Treatment of Cubic Function Fields with Applications

Explicit construction of integral bases of radical function fields

A New Method for Finding Approximate Repetitions in DNA Sequences

Contact Info

Product

Resources

About

Finding LPRs in DNA Sequence Based on a New Index — SUA