Jordan's totient function

Let $k$ be a positive integer. In number theory, Jordan's totient function $J_{k}(n)$ of a positive integer $n$ is the number of $k$ -tuples of positive integers all less than or equal to $n$ that form a coprime $(k+1)$ -tuple together with $n$ . This is a generalisation of Euler's totient function, which is $J_{1}$ . The function is named after Camille Jordan.

Definition

Jordan's totient function is multiplicative and may be evaluated as

J_{k}(n)=n^{k}\prod _{{p|n}}\left(1-{\frac {1}{p^{k}}}\right).\,

Properties

$\sum _{{d|n}}J_{k}(d)=n^{k}.\,$

which may be written in the language of Dirichlet convolutions as^[1]

J_{k}(n)\star 1=n^{k}\,

and via Möbius inversion as

J_{k}(n)=\mu (n)\star n^{k}

Since the Dirichlet generating function of $\mu$ is $1/\zeta (s)$ and the Dirichlet generating function of $n^{k}$ is $\zeta (s-k)$ , the series for $J_{k}$ becomes

\sum _{{n\geq 1}}{\frac {J_{k}(n)}{n^{s}}}={\frac {\zeta (s-k)}{\zeta (s)}}

An average order of $J_{k}(n)$ is

{\frac {n^{k}}{\zeta (k+1)}}

The Dedekind psi function is

\psi (n)={\frac {J_{2}(n)}{J_{1}(n)}}

and by inspection of the definition (recognizing that each factor in the product over the primes is a cyclotomic polynomial of $p_{-k}$ ), the arithmetic functions defined by ${\frac {J_{k}(n)}{J_{1}(n)}}$ or ${\frac {J_{{2k}}(n)}{J_{k}(n)}}$ can also be shown to be integer-valued multiplicative functions.

$\sum_{\delta\mid n}\delta^sJ_r(\delta)J_s\left(\frac{n}{\delta}\right) = J_{r+s}(n)$ . ^[2]

Order of matrix groups

The general linear group of matrices of order $m$ over $\mathbf {Z} _{n}$ has order^[3]

|\operatorname {GL}(m,{\mathbf {Z}}_{n})|=n^{{{\frac {m(m-1)}{2}}}}\prod _{{k=1}}^{m}J_{k}(n).

The special linear group of matrices of order $m$ over $\mathbf {Z} _{n}$ has order

|\operatorname {SL}(m,{\mathbf {Z}}_{n})|=n^{{{\frac {m(m-1)}{2}}}}\prod _{{k=2}}^{m}J_{k}(n).

The symplectic group of matrices of order $m$ over $\mathbf {Z} _{n}$ has order

|\operatorname {Sp}(2m,{\mathbf {Z}}_{n})|=n^{{m^{2}}}\prod _{{k=1}}^{m}J_{{2k}}(n).

The first two formulas were discovered by Jordan.

Examples

Explicit lists in the OEIS are J₂ in A007434, J₃ in A059376, J₄ in A059377, J₅ in A059378, J₆ up to J₁₀ in A069091 up to A069095.

Multiplicative functions defined by ratios are J₂(n)/J₁(n) in A001615, J₃(n)/J₁(n) in A160889, J₄(n)/J₁(n) in A160891, J₅(n)/J₁(n) in A160893, J₆(n)/J₁(n) in A160895, J₇(n)/J₁(n) in A160897, J₈(n)/J₁(n) in A160908, J₉(n)/J₁(n) in A160953, J₁₀(n)/J₁(n) in A160957, J₁₁(n)/J₁(n) in A160960.

Examples of the ratios J_2k(n)/J_k(n) are J₄(n)/J₂(n) in A065958, J₆(n)/J₃(n) in A065959, and J₈(n)/J₄(n) in A065960.

Notes

↑ Sándor & Crstici (2004) p.106
↑ Holden et al in external links The formula is Gegenbauer's
↑ All of these formulas are from Andrici and Priticari in #External links

References

L. E. Dickson (1971) [1919]. History of the Theory of Numbers, Vol. I. Chelsea Publishing. p. 147. ISBN 0-8284-0086-5. JFM 47.0100.04.
M. Ram Murty (2001). Problems in Analytic Number Theory. Graduate Texts in Mathematics. 206. Springer-Verlag. p. 11. ISBN 0-387-95143-1. Zbl 0971.11001.
Sándor, Jozsef; Crstici, Borislav (2004). Handbook of number theory II. Dordrecht: Kluwer Academic. pp. 32–36. ISBN 1-4020-2546-7. Zbl 1079.11001.

External links

Andrica, Dorin; Piticari, Mihai (2004). "On some Extensions of Jordan's arithmetical Functions" (PDF). Acta universitatis Apulensis (7). MR 2157944.
Holden, Matthew; Orrison, Michael; Varble, Michael. "Yet another Generalization of Euler's Totient Function" (PDF).

Totient function

Euler's totient function $\phi (n)$ Jordan's totient function $J_{k}(n)$ Carmichael function $\lambda (n)$ Nontotient Noncototient Highly totient number Highly cototient number Sparsely totient number

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