Partial isometry: Difference between revisions

Revision as of 16:08, 23 January 2014

In mathematics, the Bell series is a formal power series used to study properties of arithmetical functions. Bell series were introduced and developed by Eric Temple Bell.

Given an arithmetic function $f$ and a prime $p$ , define the formal power series $f_{p}(x)$ , called the Bell series of $f$ modulo $p$ as:

f_{p}(x)=\sum _{n=0}^{\infty }f(p^{n})x^{n}.

Two multiplicative functions can be shown to be identical if all of their Bell series are equal; this is sometimes called the uniqueness theorem. Given multiplicative functions $f$ and $g$ , one has $f=g$ if and only if:

f_{p}(x)=g_{p}(x)

for all primes

p

.

Two series may be multiplied (sometimes called the multiplication theorem): For any two arithmetic functions $f$ and $g$ , let $h=f*g$ be their Dirichlet convolution. Then for every prime $p$ , one has:

h_{p}(x)=f_{p}(x)g_{p}(x).\,

In particular, this makes it trivial to find the Bell series of a Dirichlet inverse.

If $f$ is completely multiplicative, then:

f_{p}(x)={\frac {1}{1-f(p)x}}.

Examples

The following is a table of the Bell series of well-known arithmetic functions.

The Möbius function $\mu$ has $\mu _{p}(x)=1-x.$
Euler's Totient $\varphi$ has $\varphi _{p}(x)={\frac {1-x}{1-px}}.$
The multiplicative identity of the Dirichlet convolution $\delta$ has $\delta _{p}(x)=1.$
The Liouville function $\lambda$ has $\lambda _{p}(x)={\frac {1}{1+x}}.$
The power function Id_k has $({\textrm {Id}}_{k})_{p}(x)={\frac {1}{1-p^{k}x}}.$ Here, Id_k is the completely multiplicative function $\operatorname {Id} _{k}(n)=n^{k}$ .
The divisor function $\sigma _{k}$ has $(\sigma _{k})_{p}(x)={\frac {1}{1-(1+p^{k})x+p^{k}x^{2}}}.$

References

Template:Apostol IANT

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+In [[mathematics]], the '''Bell series''' is a [[formal power series]] used to study properties of arithmetical functions. Bell series were introduced and developed by [[Eric Temple Bell]].
+Given an [[arithmetic function]] <math>f</math> and a [[Prime number|prime]] <math>p</math>, define the formal power series <math>f_p(x)</math>, called the Bell series of <math>f</math> modulo <math>p</math>  as:
+:<math>f_p(x)=\sum_{n=0}^\infty f(p^n)x^n.</math>
+Two multiplicative functions can be shown to be identical if all of their Bell series are equal; this is sometimes called the ''uniqueness theorem''. Given [[multiplicative function]]s <math>f</math> and <math>g</math>, one has <math>f=g</math> [[if and only if]]:
+:<math>f_p(x)=g_p(x)</math> for all primes <math>p</math>.
+Two series may be multiplied (sometimes called the ''multiplication theorem''): For any two [[arithmetic function]]s <math>f</math> and <math>g</math>, let <math>h=f*g</math> be their [[Dirichlet convolution]].  Then for every prime <math>p</math>, one has:
+:<math>h_p(x)=f_p(x) g_p(x).\,</math>
+In particular, this makes it trivial to find the Bell series of a [[Dirichlet convolution|Dirichlet inverse]].
+If <math>f</math> is [[completely multiplicative]], then:
+:<math>f_p(x)=\frac{1}{1-f(p)x}.</math>
+==Examples==
+The following is a table of the Bell series of well-known arithmetic functions.
+* The [[Möbius function]] <math>\mu</math> has <math>\mu_p(x)=1-x.</math>
+* [[Eulers phi function|Euler's Totient]] <math>\varphi</math> has <math>\varphi_p(x)=\frac{1-x}{1-px}.</math>
+* The multiplicative identity of the [[Dirichlet convolution]] <math>\delta</math> has <math>\delta_p(x)=1.</math>
+* The [[Liouville function]] <math>\lambda</math> has <math>\lambda_p(x)=\frac{1}{1+x}.</math>
+* The power function Id<sub>k</sub> has <math>(\textrm{Id}_k)_p(x)=\frac{1}{1-p^kx}.</math>  Here, Id<sub>k</sub> is the completely multiplicative function  <math>\operatorname{Id}_k(n)=n^k</math>.
+* The [[divisor function]] <math>\sigma_k</math> has <math>(\sigma_k)_p(x)=\frac{1}{1-(1+p^k) x+p^kx^2}.</math>
+==See also==
+* [[Bell numbers]]
+==References==
+* {{Apostol IANT}}
+[[Category:Arithmetic functions]]
+[[Category:Mathematical series]]

Partial isometry: Difference between revisions

Revision as of 16:08, 23 January 2014

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