Dirichlet character: Difference between revisions
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In [[number theory]], a [[Dirichlet character]] is a [[multiplicative function]] on the [[positive integer]]s which is derived from a [[character (group theory)|character]] on the [[multiplicative group]] taken [[modular arithmetic|modulo]] a given integer. | In [[number theory]], a [[Dirichlet character]] is a [[multiplicative function]] on the [[positive integer]]s which is derived from a [[character (group theory)|character]] on the [[multiplicative group]] taken [[modular arithmetic|modulo]] a given integer. | ||
Let ''N'' be a positive integer and write ('''Z'''/''N'')* for the multiplicative group of integers modulo ''N''. Let χ be a [[group homomorphism]] from ('''Z'''/''N'')* to the [[unit circle]]. Since the multiplicative group is finite of order φ(''N''), where φ is the Euler [[totient function]], the values of χ are all [[root of unity|roots of unity]]. We extend χ to a function on the positive integers by defining χ(''n'') to be χ(''n'' mod ''N'') when ''n'' is [[coprime]] to ''N'', and to be zero when ''n'' has a factor in common with ''N''. This extended function is the ''Dirichlet character''. | Let ''N'' be a positive integer and write ('''Z'''/''N'')* for the multiplicative group of integers modulo ''N''. Let χ be a [[group homomorphism]] from ('''Z'''/''N'')* to the [[unit circle]]. Since the multiplicative group is finite of order φ(''N''), where φ is the Euler [[totient function]], the values of χ are all [[root of unity|roots of unity]]. We extend χ to a function on the positive integers by defining χ(''n'') to be χ(''n'' mod ''N'') when ''n'' is [[coprime]] to ''N'', and to be zero when ''n'' has a factor in common with ''N''. This extended function is the ''Dirichlet character''. As a function on the positive integers it is a [[totally multiplicative function]] with period ''n''. | ||
The ''principal character'' χ<sub>0</sub> is derived from the trivial character which is 1 one ''n'' coprime to ''N'' and zero otherwise. | The ''principal character'' χ<sub>0</sub> is derived from the trivial character which is 1 one ''n'' coprime to ''N'' and zero otherwise. | ||
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We say that a Dirichlet character χ<sub>1</sub> with modulus ''N''<sub>1</sub> "induces" χ with modulus ''N'' if ''N''<sub>1</sub> divides ''N'' and χ(''n'') agrees with χ<sub>1</sub>(''n'') whenever they are both non-zero. A ''primitive'' character is one which is not induced from any character with smaller modulus. The ''conductor'' of a character is the modulus of the associated primitive character. | We say that a Dirichlet character χ<sub>1</sub> with modulus ''N''<sub>1</sub> "induces" χ with modulus ''N'' if ''N''<sub>1</sub> divides ''N'' and χ(''n'') agrees with χ<sub>1</sub>(''n'') whenever they are both non-zero. A ''primitive'' character is one which is not induced from any character with smaller modulus. The ''conductor'' of a character is the modulus of the associated primitive character. | ||
The ''Dirichlet L-function'' associated to χ is the [[Dirichlet series]] | ==Dirichlet L-function== | ||
The '''Dirichlet L-function''' associated to χ is the [[Dirichlet series]] | |||
:<math>L(s,\chi) = \sum_{n=1}^\infty \chi(n) n^{-s} \,</math> | :<math>L(s,\chi) = \sum_{n=1}^\infty \chi(n) n^{-s} \,</math> | ||
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:<math>L(s,\chi) = \prod_p (1-\chi(p)p^{-s})^{-1} .\,</math> | :<math>L(s,\chi) = \prod_p (1-\chi(p)p^{-s})^{-1} .\,</math> | ||
If χ is principal then ''L''(''s'',χ) is the [[Riemann zeta function]] with finitely many [[Euler factor]]s removed, and hence has a [[pole (complex analysis)|pole]] of order 1 at ''s''=1. Otherwise ''L''(''s'',χ) has a half-plane of convergence to the right of ''s''=0. In all cases, ''L''(''s'',χ) has an [[analytic continuation]] to the [[complex plane]] with a [[functional equation]]. | |||
Latest revision as of 06:03, 15 June 2009
In number theory, a Dirichlet character is a multiplicative function on the positive integers which is derived from a character on the multiplicative group taken modulo a given integer.
Let N be a positive integer and write (Z/N)* for the multiplicative group of integers modulo N. Let χ be a group homomorphism from (Z/N)* to the unit circle. Since the multiplicative group is finite of order φ(N), where φ is the Euler totient function, the values of χ are all roots of unity. We extend χ to a function on the positive integers by defining χ(n) to be χ(n mod N) when n is coprime to N, and to be zero when n has a factor in common with N. This extended function is the Dirichlet character. As a function on the positive integers it is a totally multiplicative function with period n.
The principal character χ0 is derived from the trivial character which is 1 one n coprime to N and zero otherwise.
We say that a Dirichlet character χ1 with modulus N1 "induces" χ with modulus N if N1 divides N and χ(n) agrees with χ1(n) whenever they are both non-zero. A primitive character is one which is not induced from any character with smaller modulus. The conductor of a character is the modulus of the associated primitive character.
Dirichlet L-function
The Dirichlet L-function associated to χ is the Dirichlet series
with an Euler product
If χ is principal then L(s,χ) is the Riemann zeta function with finitely many Euler factors removed, and hence has a pole of order 1 at s=1. Otherwise L(s,χ) has a half-plane of convergence to the right of s=0. In all cases, L(s,χ) has an analytic continuation to the complex plane with a functional equation.