Hasse–Davenport relation

The Hasse–Davenport relations, introduced by Davenport and Hasse (1935), are two related identities for Gauss sums, one called the Hasse–Davenport lifting relation, and the other called the Hasse–Davenport product relation. The Hasse–Davenport lifting relation is an equality in number theory relating Gauss sums over different fields. Weil (1949) used it to calculate the zeta function of a Fermat hypersurface over a finite field, which motivated the Weil conjectures.

Gauss sums are analogues of the gamma function over finite fields, and the Hasse–Davenport product relation is the analogue of Gauss's multiplication formula

\Gamma(z) \; \Gamma\left(z + \frac{1}{k}\right) \; \Gamma\left(z + \frac{2}{k}\right) \cdots \Gamma\left(z + \frac{k-1}{k}\right) = (2 \pi)^{ \frac{k-1}{2}} \; k^{1/2 - kz} \; \Gamma(kz). \,\!

In fact the Hasse–Davenport product relation follows from the analogous multiplication formula for p-adic gamma functions together with the Gross–Koblitz formula of Gross & Koblitz (1979).

Hasse–Davenport lifting relation

Let F be a finite field with q elements, and F_s be the field such that [F_s:F] = s, that is, s is the dimension of the vector space F_s over F.

Let $\alpha$ be an element of $F_s$ .

Let $\chi$ be a multiplicative character from F to the complex numbers.

Let $N_{F_s/F}(\alpha)$ be the norm from $F_s$ to $F$ defined by

N_{F_s/F}(\alpha):=\alpha\cdot\alpha^q\cdots\alpha^{q^{s-1}}.\,

Let $\chi'$ be the multiplicative character on $F_s$ which is the composition of $\chi$ with the norm from F_s to F, that is

\chi'(\alpha):=\chi(N_{F_s/F}(\alpha))

Let ψ be some nontrivial additive character of F, and let $\psi'$ be the additive character on $F_s$ which is the composition of $\psi$ with the trace from F_s to F, that is

\psi'(\alpha):=\psi(Tr_{F_s/F}(\alpha))

Let

\tau(\chi,\psi)=\sum_{x\in F}\chi(x)\psi(x)

be the Gauss sum over F, and let $\tau(\chi',\psi')$ be the Gauss sum over $F_s$ .

Then the Hasse–Davenport lifting relation states that

(-1)^s\cdot \tau(\chi,\psi)^s=-\tau(\chi',\psi').

Hasse–Davenport product relation

The Hasse–Davenport product relation states that

\prod_{a\bmod m} \tau(\chi\rho^a,\psi) = -\chi^{-m}(m)\tau(\chi^m,\psi)\prod_{a\bmod m} \tau(\rho^a,\psi)

where ρ is a multiplicative character of exact order m dividing q–1 and χ is any multiplicative character and ψ is a non-trivial additive character.

References

Davenport, Harold; Hasse, Helmut (1935), "Die Nullstellen der Kongruenzzetafunktionen in gewissen zyklischen Fällen. (On the zeros of the congruence zeta-functions in some cyclic cases)", Journal für Reine und Angewandte Mathematik (in German) 172: 151–182, ISSN 0075-4102, Zbl 0010.33803
Gross, Benedict H.; Koblitz, Neal (1979), "Gauss sums and the p-adic Γ-function", Annals of Mathematics. Second Series 109 (3): 569–581, doi:10.2307/1971226, ISSN 0003-486X, MR 534763
Ireland, Kenneth; Rosen, Michael (1990). A Classical Introduction to Modern Number Theory. Springer. pp. 158–162. ISBN 0-387-97329-X.
Weil, André (1949), "Numbers of solutions of equations in finite fields", Bulletin of the American Mathematical Society 55 (5): 497–508, doi:10.1090/S0002-9904-1949-09219-4, ISSN 0002-9904, MR 0029393 Reprinted in Oeuvres Scientifiques/Collected Papers by André Weil ISBN 0-387-90330-5

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