0,3

a(n) is also the number of n X n symmetric permutation matrices.

a(n) is also the number of matchings in the complete graph K(n). - Ola Veshta (olaveshta(AT)my-deja.com), Mar 25 2001. Equivalently, this is the number of graphs on n labeled nodes with degrees at most 1. - D. E. Knuth, Mar 31 2008

a(n) is also the sum of the degrees of the irreducible representations of the symmetric group S_n - Avi Peretz (njk(AT)netvision.net.il), Apr 01 2001

a(n) is the number of partitions of a set of n distinguishable elements into sets of size 1 and 2. - Karol A. Penson (penson(AT)lptl.jussieu.fr), Apr 22 2003.

Number of tableaux on the edges of the star graph of order n, S_n (sometimes T_n) - Roberto E. Martinez II (remartin(AT)fas.harvard.edu), Jan 09 2002

The Hankel transform of this sequence is A000178 (superfactorials). Sequence is also binomial transform of the sequence 1, 0, 1, 0, 3, 0, 15, 0, 105, 0, 945, . . . (A001147 with interpolated zeros) . - Philippe DELEHAM (kolotoko(AT)wanadoo.fr), Jun 10 2005

Row sums of the exponential Riordan array (e^(x^2/2),x). - Paul Barry (pbarry(AT)wit.ie), Jan 12 2006

a(n) = number of nonnegative lattice paths of upsteps U = (1,1) and downsteps D = (1,-1) that start at the origin and end on the vertical line x = n in which each downstep (if any) is marked with an integer between 1 and the height of its initial vertex above the x-axis. For example, with the required integer immediately preceding each downstep, a(3) = 4 counts UUU, UU1D, UU2D, U1DU. - David Callan (callan(AT)stat.wisc.edu), Mar 07 2006

The descriptions in the Mathematica lines are due to w.meeussen (wouter.meeussen(AT)pandora.be).

P. Blasiak, K. A. Penson, A. I. Solomon, A. Horzela and G. E. H. Duchamp, Some useful combinatorial formulas for bosonic operators, J. Math. Phys. 46, 052110 (2005) (6 pages).

P. Blasiak, K. A. Penson, A. I. Solomon, A. Horzela and G. E. H. Duchamp, Combinatorial field theories via boson normal ordering, preprint, Apr 27 2004.

D. Castellanos, A generalization of Binet's formula and some of its consequences, Fib. Quart., 27 (1989), 424-438.

C.-O. Chow, Counting involutory, unimodal and alternating signed permutations, Discr. Math. 306 (2006), 2222-2228.

S. Chowla, The asymptotic behavior of solutions of difference equations, in Proceedings of the International Congress of Mathematicians (Cambridge, MA, 1950), Vol. I, 377, Amer. Math. Soc., Providence, RI, 1952.

S. Chowla, I. N. Herstein and W. K. Moore, On recursions connected with symmetric groups I, Canad. J. Math., 3 (1951), 328-334.

R. Donaghey, Binomial self-inverse sequences and tangent coefficients, J. Combin. Theory, Series A, 21 (1976), 155-163.

S. Dulucq and J.-G. Penaud, Cordes, arbres et permutations. Discrete Math. 117 (1993), no. 1-3, 89-105.

W. Fulton, Young Tableaux, Cambridge, 1997.

J. Gilder, Rooks inviolate revisited II, Math. Gaz., 70 (1986), 44-45.

H. Gupta, Enumeration of symmetric matrices, Duke Math. J., 35 (1968), 653-659.

L. C. Larson, The number of essentially different nonattacking rook arrangements, J. Recreat. Math., 7 (No. 3, 1974), circa pages 180-181.

L. Moser and M. Wyman, On solutions of x^d = 1 in symmetric groups, Canad. J. Math., 7 (1955), 159-168.

T. Mueller, Finite group actions and asymptotic expansion of e^P(z), Combinatorica, 17 (4) (1997), 523-554.

T. Muir, A Treatise on the Theory of Determinants. Dover, NY, 1960, p. 6.

J. Riordan, An Introduction to Combinatorial Analysis, Wiley, 1958, p. 86.

R. W. Robinson, Counting arrangements of bishops, pp. 198-214 of Combinatorial Mathematics IV (Adelaide 1975), Lect. Notes Math., 560 (1976). See D_n.

R. P. Stanley, Enumerative Combinatorics, Cambridge, Vol. 2, 1999; see Example 5.2.10.

T. D. Noe, Table of n, a(n) for n = 0..100

Joerg Arndt, Fxtbook

P. Blasiak, K. A. Penson, A. I. Solomon, A. Horzela and G. E. H. Duchamp, Combinatorial field theories via boson normal ordering

D. Barsky, Analyse p-adique et suites classiques de nombres, Sem. Loth. Comb. B05b (1981) 1-21.

C. Bebeacua, T. Mansour, A. Postnikov and S. Severini, On the x-rays of permutations

P. J. Cameron, Sequences realized by oligomorphic permutation groups, J. Integ. Seqs. Vol. 3 (2000), #00.1.5.

A. M. Goyt, Avoidance of partitions of a 3-element set

A. Horzela, P. Blasiak, G. E. H. Duchamp, K. A. Penson and A. I. Solomon, A product formula and combinatorial field theory

INRIA Algorithms Project, Encyclopedia of Combinatorial Structures 17

INRIA Algorithms Project, Encyclopedia of Combinatorial Structures 22

W. Lang, On generalizations of Stirling number triangles, J. Integer Seqs., Vol. 3 (2000), #00.2.4.

J. W. Layman, The Hankel Transform and Some of its Properties, J. Integer Sequences, 4 (2001), #01.1.5.

E. Lucas, Th\'{e}orie des Nombres. Gauthier-Villars, Paris, 1891, Vol. 1, p. 221.

A. I. Solomon, P. Blasiak, G. Duchamp, A. Horzela and K. A. Penson, Combinatorial physics, normal order and model Feynman graphs.

R. P. Stanley, A combinatorial miscellany

Eric Weisstein's World of Mathematics, Link to a section of The World of Mathematics.

Eric Weisstein's World of Mathematics, Link to a section of The World of Mathematics.

Index entries for "core" sequences

Index entries for sequences related to Young tableaux.

Index entries for related partition-counting sequences

a(n) = a(n-1)+A013989(n-2) = A013989(n)/(n+1).

E.g.f.: exp(x*(2+x)/2). a(n) = a(n-1) + (n-1)*a(n-2), n>0. a(n)=Sum_{k=0..[ n/2 ]} n!/((n-2*k)!*2^k*k!).

a(m+n) = Sum_{k>=0} k!*binomial(m, k)*binomial(n, k)*a(m-k)*a(n-k) . - DELEHAM Philippe (kolotoko(AT)wanadoo.fr), Mar 05 2004

The e.g.f. y(x) satisfies y^2 = y''y' - (y')^2.

a(n) ~ c*(n/e)^(n/2)exp(n^(1/2)) where c=2^(-1/2)exp(-1/4). [Chowla]

Special values of Hermite polynomials. In Maple notation a(n)=HermiteH(n, 1/(sqrt(2)*I))/(-sqrt(2)*I)^n, n=0, 1..., from K. A. Penson (penson(AT)lptl.jussieu.fr), May 16, 2002.

a(n)=sum{k=0..n, A001498((n+k)/2, (n-k)/2)(1+(-1)^(n-k))/2}; - Paul Barry (pbarry(AT)wit.ie), Jan 12 2006

For asymptotics see the Robinson paper.

a[n]=Sum[A0099174[n,m],{m,0,n}]. - Roger Bagula (rlbagulatftn(AT)yahoo.com), Oct 06 2006

O.g.f.: A(x) = 1/(1-x-1*x^2/(1-x-2*x^2/(1-x-3*x^2/(1-... -x-n*x^2/(1- ...))))) (continued fraction). - Paul D. Hanna (pauldhanna(AT)juno.com), Jan 17 2006

Sequence starts 1, 1, 2, 4, 10, ... because possibilities are: {}, {A}, {AB, BA}, {ABC, ACB, BAC, CBA}, {ABCD, ABDC, ACBD, ADCB, BACD, BADC, CBAD, CDAB, DBCA, DCBA} - Henry Bottomley (se16(AT)btinternet.com), Jan 16 2001

A000085 := proc(n) option remember; if n=0 then 1 elif n=1 then 1 else A000085(n-1)+(n-1)*A000085(n-2); fi; end;

with(combstruct):ZL3:=[S, {S=Set(Cycle(Z, card<3))}, labeled]:seq(count(ZL3, size=n), n=0..25); - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com), Sep 24 2007

with (combstruct):a:=proc(m) [ZL, {ZL=Set(Cycle(Z, m>=card))}, labeled]; end: A:=a(2):seq(count(A, size=n), n=0..25); - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com), Jun 11 2008

Sum[ (2k)!/k!/2^k Binomial[ n, 2k ], {k, 0, n/2} ]//FullSimplify

HypergeometricU[ -(n/2), 1/2, -(1/2) ] / (-(1/2))^(-(-n/2))

NumberOfTableaux[M[Star[n]]]

p[0, x] = 1; p[1, x] = x; p[k_, x_] := p[k, x] = x*p[k - 1, x] + (k - 1)*p[k - 2, x]; Table[Sum[CoefficientList[p[n, x], x][[m]], {m, 1, n + 1}], {n, 0, 15}] - Roger Bagula (rlbagulatftn(AT)yahoo.com), Oct 06 2006

(PARI) a(n)=if(n<0, 0, n!*polcoeff(exp(x+x^2/2+x*O(x^n)), n))

Cf. A001470, A047884, A049403, A099174, A136281-A136283.

See also A005425 for another version of the switchboard problem.

Equals 2 * A001475(n-1) for n>1.

First column of array A099020.

A069943(n+1)/A069944(n+1) = a(n)/A000142(n) in lowest terms.

Row sums of array A117506 (M_4 numbers).

Sequence in context: A007123 A007578 A007580 this_sequence A047653 A052854 A096807

Adjacent sequences: A000082 A000083 A000084 this_sequence A000086 A000087 A000088

nonn,core,easy,nice

njas and J. H. Conway (conway(AT)math.princeton.edu)