Kloosterman sum
In mathematics, a Kloosterman sum is a particular kind of exponential sum. They are named for the Dutch mathematician Hendrik Kloosterman, who introduced them in 1926 when he adapted the Hardy–Littlewood circle method to tackle a problem involving positive definite diagonal quadratic forms in four as opposed to five or more variables, which he had dealt with in his dissertation in 1924.
Let be natural numbers. Then
Here x* is the inverse of modulo.
Context
The Kloosterman sums are a finite ring analogue of Bessel functions. They occur in the Fourier expansion of modular forms.There are applications to mean values involving the Riemann zeta function, primes in short intervals, primes in arithmetic progressions, the spectral theory of automorphic functions and related topics.
Properties of the Kloosterman sums
- If or then the Kloosterman sum reduces to the Ramanujan sum.
- depends only on the residue class of and modulo. Furthermore and if.
- Let with and coprime. Choose and such that and. Then
- The value of is always an algebraic real number. In fact is an element of the subfield which is the compositum of the fields
- The Selberg identity:
- For an odd prime, there are no known simple formula for, and the Sato–Tate conjecture suggests that none exist. The lifting formulas below, however, are often as good as an explicit evaluation. If one also has the important transformation:
- Let with prime and assume. Then:
Estimates
Here is the number of positive divisors of. Because of the multiplicative properties of Kloosterman sums these estimates may be reduced to the case where is a prime number. A fundamental technique of Weil reduces the estimate
when ab ≠ 0 to his results on local zeta-functions. Geometrically the sum is taken along a 'hyperbola' XY = ab and we consider this as defining an algebraic curve over the finite field with elements. This curve has a ramified Artin–Schreier covering, and Weil showed that the local zeta-function of has a factorization; this is the Artin L-function theory for the case of global fields that are function fields, for which Weil gives a 1938 paper of J. Weissinger as reference. The non-polar factors are of type, where is a Kloosterman sum. The estimate then follows from Weil's basic work of 1940.
This technique in fact shows much more generally that complete exponential sums 'along' algebraic varieties have good estimates, depending on the Weil conjectures in dimension > 1. It has been pushed much further by Pierre Deligne, Gérard Laumon, and Nicholas Katz.
Short Kloosterman sums
Short Kloosterman sums are defined as trigonometric sums of the formwhere runs through a set of numbers, coprime to, the number of elements in which is essentially smaller than, and the symbol denotes the congruence class, inverse to modulo :
Up to the early 1990s, estimates for sums of this type were known mainly in the case where the number of summands was greater than. Such estimates were due to H. D. Kloosterman, I. M. Vinogradov, H. Salie,
L. Carlitz, S. Uchiyama and A. Weil. The only exceptions were the special modules of the form, where is a fixed prime and the exponent increases to infinity.
In the 1990s Anatolii Alexeevitch Karatsuba developed a new method of estimating short Kloosterman sums. Karatsuba's method makes it possible to estimate Kloosterman's sums, the number of summands in which does not exceed, and in some cases even, where is an arbitrarily small fixed number. The last paper of A.A. Karatsuba on this subject was published after his death.
Various aspects of the method of Karatsuba found applications in solving the following problems of analytic number theory:
- finding asymptotics of the sums of fractional parts of the form:
- finding the lower bound for the number of solutions of the inequalities of the form:
- the precision of approximation of an arbitrary real number in the segment by fractional parts of the form:
- a more precise constant in the Brun–Titchmarsh theorem :
- a lower bound for the greatest prime divisor of the product of numbers of the form:.;
- proving that there are infinitely many primes of the form:.;
- combinatorial properties of the set of numbers :
Lifting of Kloosterman sums
Then for all integers a, b coprime to we have
Here is the number of prime factors of counting multiplicity. The sum on the right can be reinterpreted as a sum over algebraic integers in the field This formula is due to Yangbo Ye, inspired by Don Zagier and extending the work of Hervé Jacquet and Ye on the relative trace formula for. Indeed, much more general exponential sums can be lifted.
Kuznetsov trace formula
The Kuznetsov or relative trace formula connects Kloosterman sums at a deep level with the spectral theory of automorphic forms. Originally this could have been stated as follows. Let be a sufficiently "well behaved" function. Then one calls identities of the following type Kuznetsov trace formula:The integral transform part is some integral transform of g and the spectral part is a sum of Fourier coefficients, taken over spaces of holomorphic and non-holomorphic modular forms twisted with some integral transform of g. The Kuznetsov trace formula was found by Kuznetsov while studying the growth of weight zero automorphic functions. Using estimates on Kloosterman sums he was able to derive estimates for Fourier coefficients of modular forms in cases where Pierre Deligne's proof of the Weil conjectures was not applicable.
It was later translated by Jacquet to a representation theoretic framework. Let be a reductive group over a number field F and be a subgroup. While the usual trace formula studies the harmonic analysis on G, the relative trace formula a tool for studying the harmonic analysis on the symmetric space. For an overview and numerous applications see the references.
History
Weil's estimate can now be studied in W. M. Schmidt, Equations over finite fields: an elementary approach, 2nd ed.. The underlying ideas here are due to S. Stepanov and draw inspiration from Axel Thue's work in Diophantine approximation.There are many connections between Kloosterman sums and modular forms. In fact the sums first appeared in a 1912 paper of Henri Poincaré on modular forms. Hans Salié introduced a form of Kloosterman sum that is twisted by a Dirichlet character: Such Salié sums have an elementary evaluation.
After the discovery of important formulae connecting Kloosterman sums with non-holomorphic modular forms by Kuznetsov in 1979, which contained some 'savings on average' over the square root estimate, there were further developments by Iwaniec and Deshouillers in a seminal paper in Inventiones Mathematicae. Subsequent applications to analytic number theory were worked out by a number of authors, particularly Bombieri, Fouvry, Friedlander and Iwaniec.
The field remains somewhat inaccessible. A detailed introduction to the spectral theory needed to understand the Kuznetsov formulae is given in R. C. Baker, Kloosterman Sums and Maass Forms, vol. I. Also relevant for students and researchers interested in the field is.