Gauss sum
In algebraic number theory, a Gauss sum or Gaussian sum is a particular kind of finite sum of roots of unity, typically
where the sum is over elements r of some finite commutative ring R, ψ is a group homomorphism of the additive group R into the unit circle, and χ is a group homomorphism of the unit group R× into the unit circle, extended to non-unit r, where it takes the value 0. Gauss sums are the analogues for finite fields of the Gamma function.[1]
Such sums are ubiquitous in number theory. They occur, for example, in the functional equations of Dirichlet L-functions, where for a Dirichlet character χ the equation relating L(s, χ) and L(1 − s, χ) (where χ is the complex conjugate of χ) involves a factor[clarification needed]
History
[edit]The case originally considered by Carl Friedrich Gauss was the quadratic Gauss sum, for R the field of residues modulo a prime number p, and χ the Legendre symbol. In this case Gauss proved that G(χ) = p1⁄2 or ip1⁄2 for p congruent to 1 or 3 modulo 4 respectively (the quadratic Gauss sum can also be evaluated by Fourier analysis as well as by contour integration).
An alternate form for this Gauss sum is
- .
Quadratic Gauss sums are closely connected with the theory of theta functions.
The general theory of Gauss sums was developed in the early 19th century, with the use of Jacobi sums and their prime decomposition in cyclotomic fields. Gauss sums over a residue ring of integers mod N are linear combinations of closely related sums called Gaussian periods.
The absolute value of Gauss sums is usually found as an application of Plancherel's theorem on finite groups. In the case where R is a field of p elements and χ is nontrivial, the absolute value is p1⁄2. The determination of the exact value of general Gauss sums, following the result of Gauss on the quadratic case, is a long-standing issue. For some cases see Kummer sum.
Properties of Gauss sums of Dirichlet characters
[edit]The Gauss sum of a Dirichlet character modulo N is
If χ is also primitive, then
in particular, it is nonzero. More generally, if N0 is the conductor of χ and χ0 is the primitive Dirichlet character modulo N0 that induces χ, then the Gauss sum of χ is related to that of χ0 by
where μ is the Möbius function. Consequently, G(χ) is non-zero precisely when N/N0 is squarefree and relatively prime to N0.[2]
Other relations between G(χ) and Gauss sums of other characters include
where χ is the complex conjugate Dirichlet character, and if χ′ is a Dirichlet character modulo N′ such that N and N′ are relatively prime, then
The relation among G(χχ′), G(χ), and G(χ′) when χ and χ′ are of the same modulus (and χχ′ is primitive) is measured by the Jacobi sum J(χ, χ′). Specifically,
Further properties
[edit]- Gauss sums can be used to prove quadratic reciprocity, cubic reciprocity, and quartic reciprocity.
- Gauss sums can be used to calculate the number of solutions of polynomial equations over finite fields, and thus can be used to calculate certain zeta functions.
See also
[edit]- Quadratic Gauss sum
- Elliptic Gauss sum
- Jacobi sum
- Kummer sum
- Kloosterman sum
- Gaussian period
- Hasse–Davenport relation
- Chowla–Mordell theorem
- Stickelberger's theorem
References
[edit]- Apostol, Tom M. (1976), Introduction to analytic number theory, Undergraduate Texts in Mathematics, New York-Heidelberg: Springer-Verlag, ISBN 978-0-387-90163-3, MR 0434929, Zbl 0335.10001
- Berndt, B. C.; Evans, R. J.; Williams, K. S. (1998). Gauss and Jacobi Sums. Canadian Mathematical Society Series of Monographs and Advanced Texts. Wiley. ISBN 0-471-12807-4. Zbl 0906.11001.
- Ireland, Kenneth; Rosen, Michael (1990). A Classical Introduction to Modern Number Theory. Graduate Texts in Mathematics. Vol. 84 (2nd ed.). Springer-Verlag. ISBN 0-387-97329-X. Zbl 0712.11001.
- Section 3.4 of Iwaniec, Henryk; Kowalski, Emmanuel (2004), Analytic number theory, American Mathematical Society Colloquium Publications, vol. 53, Providence, RI: American Mathematical Society, ISBN 978-0-8218-3633-0, MR 2061214, Zbl 1059.11001