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In [[mathematics]], and more particularly in [[analytic number theory]], '''Perron's formula''' is a formula due to [[Oskar Perron]] to calculate the sum of an arithmetical function, by means of an inverse [[Mellin transform]].
 
==Statement==
Let <math>\{a(n)\}</math> be an [[arithmetic function]], and let
 
:<math> g(s)=\sum_{n=1}^{\infty} \frac{a(n)}{n^{s}} </math>
be the corresponding [[Dirichlet series]]. Presume the Dirichlet series to be [[absolutely convergent]] for <math>\Re(s)>\sigma_a</math>. Then Perron's formula is
 
:<math> A(x) = {\sum_{n\le x}}^{\star} a(n)
=\frac{1}{2\pi i}\int_{c-i\infty}^{c+i\infty} g(z)\frac{x^{z}}{z}  dz.\; </math>
 
Here, the star on the summation indicates that the last term of the sum must be multiplied by 1/2 when ''x'' is an integer.  The formula requires <math>c>\sigma_a</math> and <math>x>0</math> real, but otherwise arbitrary.
 
==Proof==
An easy sketch of the proof comes from taking [[Abel's summation formula|Abel's sum formula]]
 
:<math> g(s)=\sum_{n=1}^{\infty} \frac{a(n)}{n^{s} }=s\int_{0}^{\infty}  A(x)x^{-(s+1) } dx. </math>  
 
This is nothing but a [[Laplace transform]] under the variable change <math>x=e^t.</math> Inverting it one gets Perron's formula.
 
==Examples==
Because of its general relationship to Dirichlet series, the formula is commonly applied to many number-theoretic sums. Thus, for example, one has the famous integral representation for the [[Riemann zeta function]]:
 
:<math>\zeta(s)=s\int_1^\infty \frac{\lfloor x\rfloor}{x^{s+1}}\,dx</math>
 
and a similar formula for [[Dirichlet L-function]]s:
 
:<math>L(s,\chi)=s\int_1^\infty \frac{A(x)}{x^{s+1}}\,dx</math>
 
where
 
:<math>A(x)=\sum_{n\le x} \chi(n)</math>
 
and <math>\chi(n)</math> is a [[Dirichlet character]]. Other examples appear in the articles on the [[Mertens function]] and the [[von Mangoldt function]].
 
== References ==
* Page 243 of {{Apostol IANT}}
* {{mathworld|urlname=PerronsFormula|title=Perron's formula}}
*{{cite book |last=Tenebaum |first=Gérald |year=1995 |title=Introduction to analytic and probabilistic number theory |publisher=Cambridge University Press |location=Cambridge |isbn=0-521-41261-7 }}
 
[[Category:Analytic number theory]]
[[Category:Calculus]]
[[Category:Integral transforms]]
[[Category:Summability methods]]

Revision as of 18:58, 2 June 2013

In mathematics, and more particularly in analytic number theory, Perron's formula is a formula due to Oskar Perron to calculate the sum of an arithmetical function, by means of an inverse Mellin transform.

Statement

Let be an arithmetic function, and let

be the corresponding Dirichlet series. Presume the Dirichlet series to be absolutely convergent for . Then Perron's formula is

Here, the star on the summation indicates that the last term of the sum must be multiplied by 1/2 when x is an integer. The formula requires and real, but otherwise arbitrary.

Proof

An easy sketch of the proof comes from taking Abel's sum formula

This is nothing but a Laplace transform under the variable change Inverting it one gets Perron's formula.

Examples

Because of its general relationship to Dirichlet series, the formula is commonly applied to many number-theoretic sums. Thus, for example, one has the famous integral representation for the Riemann zeta function:

and a similar formula for Dirichlet L-functions:

where

and is a Dirichlet character. Other examples appear in the articles on the Mertens function and the von Mangoldt function.

References

  • Page 243 of Template:Apostol IANT
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