%I #20 Oct 09 2019 02:48:46
%S 0,0,0,0,0,0,0,1,8,47,277,1775,12616,102445,957357,10174566,119235347,
%T 1482297912,18884450721,240477821389,3012879828566,36800049400028,
%U 436068618826236,5001537857507095,55482177298724426,595303034603214108,6181562837200509792,62170512250565592346
%N Number of binary [ n,8 ] codes without 0 columns.
%C To find the g.f., modify the Sage program below (cf. function f). It is very complicated to write it here. - _Petros Hadjicostas_, Oct 07 2019
%H Discrete algorithms at the University of Bayreuth, <a href="http://www.algorithm.uni-bayreuth.de/en/research/SYMMETRICA/">Symmetrica</a>.
%H Harald Fripertinger, <a href="http://www.mathe2.uni-bayreuth.de/frib/codes/tables.html">Isometry Classes of Codes</a>.
%H Harald Fripertinger, <a href="http://www.mathe2.uni-bayreuth.de/frib/codes/tables_4.html">Snk2: Number of the isometry classes of all binary (n,k)-codes without zero-columns</a>. [See column k=8.]
%H H. Fripertinger and A. Kerber, <a href="https://doi.org/10.1007/3-540-60114-7_15">Isometry classes of indecomposable linear codes</a>. In: G. Cohen, M. Giusti, T. Mora (eds), Applied Algebra, Algebraic Algorithms and Error-Correcting Codes, 11th International Symposium, AAECC 1995, Lect. Notes Comp. Sci. 948 (1995), pp. 194-204. [Here a(n) = S_{n,8,2}.]
%H Petr Lisonek, <a href="https://doi.org/10.1016/j.jcta.2006.06.013">Combinatorial families enumerated by quasi-polynomials</a>, J. Combin. Theory Ser. A 114(4) (2007), 619-630. [See Section 5.]
%H David Slepian, <a href="https://archive.org/details/bstj39-5-1219">Some further theory of group codes</a>, Bell System Tech. J. 39(5) (1960), 1219-1252.
%H David Slepian, <a href="https://doi.org/10.1002/j.1538-7305.1960.tb03958.x">Some further theory of group codes</a>, Bell System Tech. J. 39(5) (1960), 1219-1252.
%H Wikipedia, <a href="https://en.wikipedia.org/wiki/Cycle_index">Cycle index</a>.
%H Wikipedia, <a href="https://en.wikipedia.org/wiki/Projective_linear_group">Projective linear group</a>.
%o (Sage) # Fripertinger's method to find the g.f. of column k >= 2 of A034253 (for small k):
%o def A034253col(k, length):
%o G1 = PSL(k, GF(2))
%o G2 = PSL(k-1, GF(2))
%o D1 = G1.cycle_index()
%o D2 = G2.cycle_index()
%o f1 = sum(i[1]*prod(1/(1-x^j) for j in i[0]) for i in D1)
%o f2 = sum(i[1]*prod(1/(1-x^j) for j in i[0]) for i in D2)
%o f = f1 - f2
%o return f.taylor(x, 0, length).list()
%o # For instance the Taylor expansion for column k = 8 (current sequence) gives
%o print(A034253col(8, 30)) # _Petros Hadjicostas_, Oct 07 2019
%Y Cf. A034254, A034344, A034345, A034346, A034347, A034348, A253186.
%Y Column k=8 of A034253 and first differences of A034362.
%K nonn
%O 1,9
%A _N. J. A. Sloane_.
%E More terms from _Petros Hadjicostas_, Oct 07 2019