User:Virginia-American/Sandbox/divisor convolution

Divisor sum convolutions edit

The sequence $c_{n}=\sum _{i=0}^{n}a_{i}b_{n-i}$ is called the discrete convolution or the Cauchy product of the sequences a_n and b_n. For integers $e$ and $f$ define the convolution sum $S_{e,f}(n)=\sum _{i=1}^{n-1}\sigma _{e}(i)\sigma _{f}(n-i)$ . Note that $S_{e,f}(n)=S_{f,e}(n)$

For odd integers $e<=f,\;\;e+f=2,4,6,8,12$ , the sum $S_{e,f}(n)$ can be evaluated in terms of $\sigma _{e+f+1},\sigma _{e+f-1},\cdots ,\sigma _{3},\sigma ,$ . Namely:

\sum _{i=1}^{n-1}\sigma (i)\sigma (n-i)={\frac {5}{12}}\sigma _{3}(n)+\left({\frac {1}{12}}-{\frac {1}{2}}n\right)\sigma (n).

\sum _{i=1}^{n-1}\sigma (i)\sigma _{3}(n-i)={\frac {7}{80}}\sigma _{5}(n)+\left({\frac {1}{24}}-{\frac {1}{8}}n\right)\sigma _{3}(n)-{\frac {1}{240}}\sigma (n).

\sum _{i=1}^{n-1}\sigma (i)\sigma _{5}(n-i)={\frac {5}{126}}\sigma _{7}(n)+\left({\frac {1}{24}}-{\frac {1}{12}}n\right)\sigma _{5}(n)+{\frac {1}{504}}\sigma (n).

\sum _{i=1}^{n-1}\sigma _{3}(i)\sigma _{3}(n-i)={\frac {1}{120}}\sigma _{7}(n)-{\frac {1}{120}}\sigma _{3}(n).

\sum _{i=1}^{n-1}\sigma (i)\sigma _{7}(n-i)={\frac {11}{480}}\sigma _{9}(n)+\left({\frac {1}{24}}-{\frac {1}{16}}n\right)\sigma _{7}(n)-{\frac {1}{480}}\sigma (n).

\sum _{i=1}^{n-1}\sigma _{3}(i)\sigma _{5}(n-i)={\frac {11}{5040}}\sigma _{9}(n)-{\frac {1}{240}}\sigma _{5}(n)+{\frac {1}{504}}\sigma _{3}(n).

\sum _{i=1}^{n-1}\sigma (i)\sigma _{11}(n-i)={\frac {691}{65520}}\sigma _{13}(n)+\left({\frac {1}{24}}-{\frac {1}{24}}n\right)\sigma _{11}(n)-{\frac {691}{65520}}\sigma (n).

\sum _{i=1}^{n-1}\sigma _{3}(i)\sigma _{9}(n-i)={\frac {1}{2640}}\sigma _{13}(n)-{\frac {1}{240}}\sigma _{9}(n)+{\frac {1}{264}}\sigma _{3}(n).

\sum _{i=1}^{n-1}\sigma _{5}(i)\sigma _{7}(n-i)={\frac {1}{10080}}\sigma _{13}(n)+{\frac {1}{504}}\sigma _{7}(n)-{\frac {1}{480}}\sigma _{5}(n).

These are the only $S_{e,f}(n)$ that can be evaluated in terms of divisor sums and polynomials in $n$ . For odd integers $e<=f,\;\;e+f=10,14,16,18,20,24$ , evaluating the sum requires the Ramanujam function $\tau (n)$ . For example:

\sum _{i=1}^{n-1}\sigma _{5}(i)\sigma _{5}(n-i)={\frac {65}{174132}}\sigma _{11}(n)+{\frac {1}{252}}\sigma _{5}(n)-{\frac {3}{691}}\tau (n).

There are many other similar formulas. For example:

\sum _{\begin{aligned}r+s+t=n\\r,\;s,\;t>0\end{aligned}}\sigma (r)\sigma (s)\sigma (t)={\frac {7}{192}}\sigma _{5}(n)+\left({\frac {5}{96}}-{\frac {5}{12}}n\right)\sigma _{3}(n)-\left({\frac {1}{192}}-{\frac {1}{16}}n+{\frac {1}{8}}n^{2}\right)\sigma (n).

See Eisenstein series for a discussion of the series and functional identities involved in these formulas.^[1]

\sigma _{3}(n)={\frac {1}{5}}\left\{6n\sigma _{1}(n)-\sigma _{1}(n)+12\sum _{0<k<n}\sigma _{1}(k)\sigma _{1}(n-k)\right\}.

^[2]

\sigma _{5}(n)={\frac {1}{21}}\left\{10(3n-1)\sigma _{3}(n)+\sigma _{1}(n)+240\sum _{0<k<n}\sigma _{1}(k)\sigma _{3}(n-k)\right\}.

^[3]

{\begin{aligned}\sigma _{7}(n)&={\frac {1}{20}}\left\{21(2n-1)\sigma _{5}(n)-\sigma _{1}(n)+504\sum _{0<k<n}\sigma _{1}(k)\sigma _{5}(n-k)\right\}\\&=\sigma _{3}(n)+120\sum _{0<k<n}\sigma _{3}(k)\sigma _{3}(n-k).\end{aligned}}

^[3]^[4]

{\begin{aligned}\sigma _{9}(n)&={\frac {1}{11}}\left\{10(3n-2)\sigma _{7}(n)+\sigma _{1}(n)+480\sum _{0<k<n}\sigma _{1}(k)\sigma _{7}(n-k)\right\}\\&={\frac {1}{11}}\left\{21\sigma _{5}(n)-10\sigma _{3}(n)+5040\sum _{0<k<n}\sigma _{3}(k)\sigma _{5}(n-k)\right\}.\end{aligned}}

^[2]^[5]

\tau (n)={\frac {65}{756}}\sigma _{11}(n)+{\frac {691}{756}}\sigma _{5}(n)-{\frac {691}{3}}\sum _{0<k<n}\sigma _{5}(k)\sigma _{5}(n-k),

where τ(n) is Ramanujan's function. ^[6]^[7]

Since σ_k(n) (for natural number k) and τ(n) are integers, the above formulas can be used to prove congruences^[8] for the functions. See Ramanujan tau function for some examples.

Extend the domain of the partition function by setting p(0) = 1.

p(n)={\frac {1}{n}}\sum _{1\leq k\leq n}\sigma (k)p(n-k).

^[9] This recurrence can be used to compute p(n).

^ The paper by Huard, Ou, Spearman, and Williams in the external links also has proofs.
^ ^a ^b Ramanujan, On Certain Arithmetical Functions, Table IV; Papers, p. 146
^ ^a ^b Koblitz, ex. III.2.8
^ Koblitz, ex. III.2.3
^ Koblitz, ex. III.2.2
^ Koblitz, ex. III.2.4
^ Apostol, Modular Functions ..., Ex. 6.10
^ Apostol, Modular Functions..., Ch. 6 Ex. 10
^ G.H. Hardy, S. Ramannujan, Asymptotic Formulæ in Combinatory Analysis, § 1.3; in Ramannujan, Papers p. 279

[1] The paper by Huard, Ou, Spearman, and Williams in the external links also has proofs.

[Ramanujan,_p._146-2] Ramanujan, On Certain Arithmetical Functions, Table IV; Papers, p. 146

[Koblitz,_ex._III.2.8-3] Koblitz, ex. III.2.8

[4] Koblitz, ex. III.2.3

[5] Koblitz, ex. III.2.2

[6] Koblitz, ex. III.2.4

[7] Apostol, Modular Functions ..., Ex. 6.10

[8] Apostol, Modular Functions..., Ch. 6 Ex. 10

[9] G.H. Hardy, S. Ramannujan, Asymptotic Formulæ in Combinatory Analysis, § 1.3; in Ramannujan, Papers p. 279

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