%I #29 Sep 12 2019 21:36:47
%S 4,6,4,15,72,266,1044,3780,14056,51132,188604,693845,2572920,9566046,
%T 35758628,134134080,505159200,1908539864,7233104844,27486455049,
%U 104713295712,399817073946,1529746919604
%N Number of identity bracelets of n beads of 4 colors.
%C For n>2 also number of asymmetric bracelets with n beads of four colors. - _Herbert Kociemba_, Nov 29 2016
%H Andrew Howroyd, <a href="/A032241/b032241.txt">Table of n, a(n) for n = 1..200</a>
%H C. G. Bower, <a href="/transforms2.html">Transforms (2)</a>
%H F. Ruskey, <a href="http://combos.org/necklace">Necklaces, Lyndon words, De Bruijn sequences, etc.</a>
%H F. Ruskey, <a href="/A000011/a000011.pdf">Necklaces, Lyndon words, De Bruijn sequences, etc.</a> [Cached copy, with permission, pdf format only]
%H <a href="/index/Br#bracelets">Index entries for sequences related to bracelets</a>
%F "DHK" (bracelet, identity, unlabeled) transform of 4, 0, 0, 0...
%F From _Herbert Kociemba_, Nov 29 2016: (Start)
%F More generally, gf(k) is the g.f. for the number of asymmetric bracelets with n beads of k colors.
%F gf(k): Sum_{n>=1} mu(n)*( -log(1-k*x^n)/n - Sum_{i=0..2} binomial(k,i)x^(n*i)/(1-k*x^(2*n)) )/2. (End)
%t m = 4; (* asymmetric bracelets of n beads of m colors *) Table[Sum[MoebiusMu[d] (m^(n/d)/n - If[OddQ[n/d], m^((n/d + 1)/2), ((m + 1) m^(n/(2 d))/2)]), {d, Divisors[n]}]/2, {n, 3, 20}] (* _Robert A. Russell_, Mar 18 2013 *)
%t mx=40;gf[x_,k_]:=Sum[MoebiusMu[n]*(-Log[1-k*x^n]/n-Sum[Binomial[k,i]x^(n i),{i,0,2}]/(1-k x^(2n)))/2,{n,mx}];ReplacePart[Rest[CoefficientList[Series[gf[x,4],{x,0,mx}],x]],{1->4,2->6}] (* _Herbert Kociemba_, Nov 29 2016 *)
%o (PARI) a(n)={if(n<3, binomial(4, n), sumdiv(n, d, moebius(n/d)*(4^d/n - if(d%2, 4^((d+1)/2), 5*4^(d/2)/2)))/2)} \\ _Andrew Howroyd_, Sep 12 2019
%Y Column k=4 of A309528 for n >= 3.
%K nonn
%O 1,1
%A _Christian G. Bower_