OEIS/Infinite Products: Difference between revisions
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imported>Gfis →Infinite Products in your CAS: Maple2 |
imported>Gfis Transforms |
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=== OEIS collection of transforms === | |||
* [https://oeis.org/wiki/Sequence_transforms Sequence transforms]: [https://oeis.org/transforms.txt Maple], [https://oeis.org/seqtranslib.txt Mathematica] | |||
weighout b from a in 1+SUM b_n x^n = PI (1+x^n)^a_n | |||
weighouti a from b in 1+SUM b_n x^n = PI (1+x^n)^a_n | |||
weighini a from b in 1+SUM b_n x^n = PI (1+x^a_n) | |||
weigh2out b from a in 1+SUM b_n x^n = PI (x^-n+1+x^n)^a_n | |||
weigh2outi a from b in 1+SUM b_n x^n = PI (x^-n+1+x^n)^a_n | |||
weigh2in b from a in 1+SUM b_n x^n = PI (x^-a_n+1+x^a_n) | |||
weigh2ini a from b in 1+SUM b_n x^n = PI (x^-a_n+1+x^a_n) | |||
=== Programs === | === Programs === | ||
[https://oeis.org/A046042 A046042] Number of partitions of n into fourth powers. | [https://oeis.org/A046042 A046042] Number of partitions of n into fourth powers. |
Revision as of 18:19, 31 December 2020
OEIS collection of transforms
weighout b from a in 1+SUM b_n x^n = PI (1+x^n)^a_n weighouti a from b in 1+SUM b_n x^n = PI (1+x^n)^a_n weighini a from b in 1+SUM b_n x^n = PI (1+x^a_n) weigh2out b from a in 1+SUM b_n x^n = PI (x^-n+1+x^n)^a_n weigh2outi a from b in 1+SUM b_n x^n = PI (x^-n+1+x^n)^a_n weigh2in b from a in 1+SUM b_n x^n = PI (x^-a_n+1+x^a_n) weigh2ini a from b in 1+SUM b_n x^n = PI (x^-a_n+1+x^a_n)
Programs
A046042 Number of partitions of n into fourth powers.
(Maple) g := -1 + 1/product(1 - x^(j^4), j=1..10): gser := series(g, x=0, 105): seq(coeff(gser, x, n), n=1..102); (Maple, A303350) seq(coeff(series(mul((1+4*x^k)^(1/2), k = 1..n), x, n+1), x, n), n=0..40); (Mathematica) g = -1 + 1/Product[1 - x^(j^4), {j, 1, 10}]; gser = Series[g, {x, 0, 105}]; Table[Coefficient[gser, x, n], {n, 1, 102}] (PARI, A322199) {a(n) = polcoeff( 1/prod(m=1, n, 1 - (2^m+1)*x^m +x*O(x^n)), n)} for(n=0, 30, print1(a(n), ","))
Generalized Euler transform
- defined by Seiichi Manyama in A266964
Product_{k>0} (1 - g(k)*x^k)^(- f(k)) = a(0) + a(1)*x + a(2)*x^2 + ...
- If we set g(n) = 1, we get the usual Euler transform.
- If we set f(n) = - h(n) and g(n) = -1, we get the weighout transform (cf. A026007).
- If we set f(n) = - n (A001478) and g(n) = n (A000027), we get A266964.
- With the default f(n) = g(n) = A000012 (all 1's), we get A000041 (number of partitions of n).
Interesting sequences
- A000081 Euler transform of itself, shifted by 1