%I A000140 M1665 N0655
%S A000140 1,1,2,6,22,101,573,3836,29228,250749,2409581,25598186,296643390,
%T A000140 3727542188,50626553988,738680521142,11501573822788,190418421447330,
%U A000140 3344822488498265,62119523114983224,1214967840930909302
%N A000140 Kendall-Mann numbers: the maximum number of permutations on n letters
having the same number of inversions (that is when the number of
inversions is floor((n choose 2)/2)).
%C A000140 Comments from Mitch Harris, Sep 18 2005: "The maximal number of inversions
in a permutation of n letters occurs uniquely in the reverse permutation,
where every pair is an inversion and the number of inversions here
is (n choose 2).
%C A000140 "What is really being described is the distribution of inversions and
so the function is from inversions to permutations. Finding the max
eliminates the quantified variable of inversion. So the function
(and therefore sequence) is from the index n (the number of letters
on which the permutations act) to the size of the set of permutations
all having the same number of inversions.
%C A000140 "For example, on 3 letters, inversion numbers 0, 1, 2 and 3 partition
the permutations into {123}, {132, 213}, {231, 312}, {321} respectively
and the largest of these is of size 2."
%C A000140 Comments from Ryen Lapham and Anant Godbole (zrcl9(AT)imail.etsu.edu),
Dec 12 2006: (Start) "Also, the number of permutations on {1,2,....,
n} for which the number A of monotone increasing subsequences of
length 2 and the number D of monotone decreasing 2-subsequences are
as close to each other as possible, i.e. 0 or 1. We call such permutations
2-balanced.
%C A000140 "If 4|n(n-1) then (with A and D as above) the feasible values of A-D
are {n choose 2}, {n choose 2}-2,....,2,0,-2,.....-{n choose 2},
whereas if 4 does not divide n(n-1), A-D may equal {n choose 2},
{n choose 2}-2,....,1,-1,.....-{n choose 2}. Let a_n(i) equal the
number of permutations with A-D the i-th highest feasible value.
%C A000140 "The sequence in question gives the number of permutations for which
A-D=0 or A-D=1, i.e. it equals A_n(j) where j=floor(({n choose 2}+2)/
2). Here is the recursion: a_n(i)=a_n(i-1)+a_{n-1}(i) for 1 <= i
<= n and a_n(n+k)=a_n(n+k-1)+a_{n-1}(n+k)-a_n(k) for k>= 1." (End)
%D A000140 N. J. A. Sloane and Simon Plouffe, The Encyclopedia of Integer Sequences,
Academic Press, 1995 (includes this sequence).
%D A000140 N. J. A. Sloane, A Handbook of Integer Sequences, Academic Press, 1973
(includes this sequence).
%D A000140 F. N. David, M. G. Kendall and D. E. Barton, Symmetric Function and Allied
Tables, Cambridge, 1966, p. 241.
%D A000140 D. Foata, Distributions eule'riennes et mahoniennes sur le group des
permutations, pp. 27-49 of M. Aigner, editor, Higher Combinatorics,
Reidel, Dordrecht, Holland, 1977.
%D A000140 A. Waksman, On the complexity of inversions, IEEE Trans. Computers, 19
(1970), 1225-1226.
%H A000140 N. J. A. Sloane, <a href="b000140.txt">Table of n, a(n) for n = 1..61</
a>
%H A000140 <a href="Sindx_Cor.html#core">Index entries for "core" sequences</a>
%F A000140 Largest coefficient of (1)(x+1)(x^2+x+1)...(x^n+...+x+1) (David W. Wilson).
%p A000140 f := 1: for n from 0 to 40 do f := f*add(x^i, i=0..n): s := series(f,
x, n*(n+1)/2+1): m := max(coeff(s, x, j) $ j=0..n*(n+1)/2): printf(`%d,
`,m) od: # from James A. Sellers Dec 07 2000 [offset is off by 1
- N. J. A. Sloane (njas(AT)research.att.com), May 23 2006]
%Y A000140 Row maxima of A008302.
%Y A000140 Sequence in context: A012268 A009655 A002772 this_sequence A079263 A129815
A103941
%Y A000140 Adjacent sequences: A000137 A000138 A000139 this_sequence A000141 A000142
A000143
%K A000140 nonn,easy,core,nice
%O A000140 1,3
%A A000140 N. J. A. Sloane (njas(AT)research.att.com).
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