A198518 -id:A198518 - cp's OEIS frontend

A001678 Number of series-reduced planted trees with n nodes.

0, 0, 1, 0, 1, 1, 2, 3, 6, 10, 19, 35, 67, 127, 248, 482, 952, 1885, 3765, 7546, 15221, 30802, 62620, 127702, 261335, 536278, 1103600, 2276499, 4706985, 9752585, 20247033, 42110393, 87733197, 183074638, 382599946, 800701320, 1677922740, 3520581954

Offset: 0

N. J. A. Sloane

The initial term is 0 by convention, though a good case can be made that it should be 1 instead.
Series-reduced trees contain no node with valency 2; see A000014 for the unrooted series-reduced trees. - Joerg Arndt, Mar 03 2015
For n>=2, a(n+1) is the number of unordered rooted trees (see A000081) with n nodes where nodes cannot have out-degree 1, see example. Imposing the condition only at non-root nodes gives A198518. - Joerg Arndt, Jun 28 2014
For n>=3, a(n+1) is the number of unordered rooted trees with n nodes where all limbs are of length >= 2. Limbs are the paths from the leafs (towards the root) to the nearest branching point (with the root considered to be a branching point). - Joerg Arndt, Mar 03 2015
A rooted tree is lone-child-avoiding if no vertex has exactly one child, and topologically series-reduced if no vertex has degree 2. This sequence counts unlabeled lone-child-avoiding rooted trees with n - 1 vertices. Topologically series-reduced rooted trees are counted by A001679, which is essentially the same as A059123. - Gus Wiseman, Jan 20 2020

			--------------- Examples (i=internal,e=external): ---------------------------
|.n=2.|..n=4..|..n=5..|...n=6.............|....n=7..........................|
|.....|.......|.......|.............e...e.|................e.e.e......e...e.|
|.....|.e...e.|.e.e.e.|.e.e.e.e...e...i...|.e.e.e.e.e...e....i....e.e...i...|
|..e..|...i...|...i...|....i........i.....|.....i..........i..........i.....|
|..e..|...e...|...e...|....e........e.....|.....e..........e..........e.....|
-----------------------------------------------------------------------------
G.f. = x^2 + x^4 + x^5 + 2*x^6 + 3*x^7 + 6*x^8 + 10*x^9 + 19*x^10 + ...
From _Joerg Arndt_, Jun 28 2014: (Start)
The a(8) = 6 rooted trees with 7 nodes as described in the comment are:
:           level sequence       out-degrees (dots for zeros)
:     1:  [ 0 1 2 3 3 2 1 ]    [ 2 2 2 . . . . ]
:  O--o--o--o
:        .--o
:     .--o
:  .--o
:
:     2:  [ 0 1 2 2 2 2 1 ]    [ 2 4 . . . . . ]
:  O--o--o
:     .--o
:     .--o
:     .--o
:  .--o
:
:     3:  [ 0 1 2 2 2 1 1 ]    [ 3 3 . . . . . ]
:  O--o--o
:     .--o
:     .--o
:  .--o
:  .--o
:
:     4:  [ 0 1 2 2 1 2 2 ]    [ 2 2 . . 2 . . ]
:  O--o--o
:     .--o
:  .--o--o
:     .--o
:
:     5:  [ 0 1 2 2 1 1 1 ]    [ 4 2 . . . . . ]
:  O--o--o
:     .--o
:  .--o
:  .--o
:  .--o
:
:     6:  [ 0 1 1 1 1 1 1 ]    [ 6 . . . . . . ]
:  O--o
:  .--o
:  .--o
:  .--o
:  .--o
:  .--o
:
(End)
From _Gus Wiseman_, Jan 20 2020: (Start)
The a(2) = 1 through a(9) = 10 unlabeled lone-child-avoiding rooted trees with n - 1 nodes (empty n = 3 column shown as dot) are:
  o   .   (oo)  (ooo)  (oooo)   (ooooo)   (oooooo)    (ooooooo)
                       (o(oo))  (o(ooo))  (o(oooo))   (o(ooooo))
                                (oo(oo))  (oo(ooo))   (oo(oooo))
                                          (ooo(oo))   (ooo(ooo))
                                          ((oo)(oo))  (oooo(oo))
                                          (o(o(oo)))  ((oo)(ooo))
                                                      (o(o(ooo)))
                                                      (o(oo)(oo))
                                                      (o(oo(oo)))
                                                      (oo(o(oo)))
(End)

D. G. Cantor, personal communication.
J. L. Gross and J. Yellen, eds., Handbook of Graph Theory, CRC Press, 2004; p. 525.
F. Harary and E. M. Palmer, Graphical Enumeration, Academic Press, NY, 1973, p. 62.
N. J. A. Sloane, A Handbook of Integer Sequences, Academic Press, 1973 (includes this sequence).
N. J. A. Sloane and Simon Plouffe, The Encyclopedia of Integer Sequences, Academic Press, 1995 (includes this sequence).

Alois P. Heinz, Table of n, a(n) for n = 0..1000 (first 501 terms from Christian G. Bower)
David Callan, A sign-reversing involution to count labeled lone-child-avoiding trees, arXiv:1406.7784 [math.CO], (30-June-2014).
F. Harary and E. M. Palmer, Probability that a point of a tree is fixed, Math. Proc. Camb. Phil. Soc. 85 (1979) 407-415.
F. Harary and G. Prins, The number of homeomorphically irreducible trees and other species, Acta Math., 101 (1959), 141-162.
F. Harary, R. W. Robinson and A. J. Schwenk, Twenty-step algorithm for determining the asymptotic number of trees of various species, J. Austral. Math. Soc., Series A, 20 (1975), 483-503.
F. Harary, R. W. Robinson and A. J. Schwenk, Corrigenda: Twenty-step algorithm for determining the asymptotic number of trees of various species, J. Austral. Math. Soc., Series A 41 (1986), p. 325.
INRIA Algorithms Project, Encyclopedia of Combinatorial Structures 404
Marko Riedel, Generating functions of unordered rooted trees with n nodes where nodes cannot have out-degree 1, classified by the number of leaves, using the Polya Enumeration Theorem and the exponential formula.
Eric Weisstein's World of Mathematics, Series-reduced tree.
Gus Wiseman, Sequences counting series-reduced and lone-child-avoiding trees by number of vertices.
Index entries for sequences related to rooted trees
Index entries for sequences related to trees

Cf. A000014, A007827, A246403, A005202.
Unlabeled rooted trees are counted by A000081.
Topologically series-reduced rooted trees are counted by A001679.
Labeled lone-child-avoiding rooted trees are counted by A060356.
Labeled lone-child-avoiding unrooted trees are counted by A108919.
Matula-Goebel numbers of lone-child-avoiding rooted trees are A291636.
Singleton-reduced rooted trees are counted by A330951.
Cf. A000669, A004111, A106179, A198518, A254382, A331488, A331578.

with (powseries): with (combstruct): n := 30: sys := {B = Prod(C,Z), S = Set(B,1 <= card), C = Union(Z,S)}: A001678 := 1,0,1,seq(count([S, sys, unlabeled],size=i),i=1..n); # Ulrich Schimke (ulrschimke(AT)aol.com)
# second Maple program:
with(numtheory):
b:= proc(n) option remember; `if`(n=0, 1, add(add(
       d*a(d+1), d=divisors(j))*b(n-j), j=1..n)/n)
    end:
a:= proc(n) option remember; `if`(n<2, 0,
      `if`(n=2, 1, b(n-2)-a(n-1)))
    end:
seq(a(n), n=0..50);  # Alois P. Heinz, Jul 02 2014

b[n_] := b[n] = If[n == 0, 1, Sum[Sum[d*a[d+1], {d, Divisors[j]}]*b[n-j], {j, 1, n}]/n]; a[n_] := a[n] = If[n < 2, 0, If[n == 2, 1, b[n-2] - a[n-1]]]; Table[a[n], {n, 0, 50}] (* Jean-François Alcover, Sep 24 2014, after Alois P. Heinz *)
terms = 38; A[] = 0; Do[A[x] = (x^2/(1+x))*Exp[Sum[A[x^k]/(k*x^k), {k, 1, j}]] + O[x]^j // Normal, {j, 1, terms}]; CoefficientList[A[x], x] (* Jean-François Alcover, Jan 12 2018 *)
urt[n_]:=Join@@Table[Union[Sort/@Tuples[urt/@ptn]],{ptn,IntegerPartitions[n-1]}];
Table[If[n<=1,0,Length[Select[urt[n-1],FreeQ[#,{}]&]]],{n,0,10}] (* _Gus Wiseman, Jan 20 2020 *)

(a(n) = if( n<4, n==2, T(n-2, n-3))); /* where */ {T(n, k) = if( n<1 || k<1, (n==0) && (k>=0), sum(j=1, k, sum(i=1, n\j, T(n-i*j, min(n-i*j, j-1)) * binomial( a(j+1) + i-1, i))))}; /* Michael Somos, Jun 04 2002 */

{a(n) = local(A); if( n<3, n==2, A = x / (1 - x^2) + O(x^n); for(k=3, n-2, A /= (1 - x^k + O(x^n))^polcoeff(A, k)); polcoeff(A, n-1))}; /* Michael Somos, Oct 06 2003 */

G.f.: A(x) satisfies A(x) = (x^2/(1+x))*exp( Sum_{k>=1} A(x^k)/(k*x^k) ) [Harary and E. M. Palmer, 1973, p. 62, Eq. (3.3.8)].
G.f.: A(x) = Sum_{n>=2} a(n) * x^n = x^2 / ((1 + x) * Product_{k>0} (1 - x^k)^a(k+1)). - Michael Somos, Oct 06 2003
a(n) ~ c * d^n / n^(3/2), where d = A246403 = 2.189461985660850563... and c = 0.1924225474701550354144525345664845514828912790855223729854471406053655209... - Vaclav Kotesovec, Jun 26 2014
a(n) = Sum_{i=2..n-2} A106179(i, n-1-i) for n >= 3. - Andrew Howroyd, Mar 29 2021

Additional comments from Michael Somos, Jun 05 2002

A291636 Matula-Goebel numbers of lone-child-avoiding rooted trees.

Original entry on oeis.org

1, 4, 8, 14, 16, 28, 32, 38, 49, 56, 64, 76, 86, 98, 106, 112, 128, 133, 152, 172, 196, 212, 214, 224, 256, 262, 266, 301, 304, 326, 343, 344, 361, 371, 392, 424, 428, 448, 454, 512, 524, 526, 532, 602, 608, 622, 652, 686, 688, 722, 742, 749, 766, 784, 817

Offset: 1

Gus Wiseman, Aug 28 2017

nonn

We say that a rooted tree is lone-child-avoiding if no vertex has exactly one child.
The Matula-Goebel number of a rooted tree is the product of primes indexed by the Matula-Goebel numbers of its branches. This gives a bijective correspondence between positive integers and unlabeled rooted trees.
An alternative definition: n is in the sequence iff n is 1 or the product of two or more not necessarily distinct prime numbers whose prime indices already belong to the sequence. For example, 14 is in the sequence because 14 = prime(1) * prime(4) and 1 and 4 both already belong to the sequence.

			The sequence of all lone-child-avoiding rooted trees together with their Matula-Goebel numbers begins:
    1: o
    4: (oo)
    8: (ooo)
   14: (o(oo))
   16: (oooo)
   28: (oo(oo))
   32: (ooooo)
   38: (o(ooo))
   49: ((oo)(oo))
   56: (ooo(oo))
   64: (oooooo)
   76: (oo(ooo))
   86: (o(o(oo)))
   98: (o(oo)(oo))
  106: (o(oooo))
  112: (oooo(oo))
  128: (ooooooo)
  133: ((oo)(ooo))
  152: (ooo(ooo))
  172: (oo(o(oo)))

David Callan, A sign-reversing involution to count labeled lone-child-avoiding trees, arXiv:1406.7784 [math.CO], (30-June-2014).
Gus Wiseman, Sequences counting series-reduced and lone-child-avoiding trees by number of vertices.
Index entries for sequences related to Matula-Goebel numbers

These trees are counted by A001678.
The case with more than two branches is A331490.
Unlabeled rooted trees are counted by A000081.
Topologically series-reduced rooted trees are counted by A001679.
Labeled lone-child-avoiding rooted trees are counted by A060356.
Labeled lone-child-avoiding unrooted trees are counted by A108919.
MG numbers of singleton-reduced rooted trees are A330943.
MG numbers of topologically series-reduced rooted trees are A331489.
Cf. A007097, A061775, A109082, A109129, A111299, A196050, A198518, A276625, A291441, A291442, A331488.

nn=2000;
primeMS[n_]:=If[n===1,{},Flatten[Cases[FactorInteger[n],{p_,k_}:>Table[PrimePi[p],{k}]]]];
srQ[n_]:=Or[n===1,With[{m=primeMS[n]},And[Length[m]>1,And@@srQ/@m]]];
Select[Range[nn],srQ]

Updated with corrected terminology by Gus Wiseman, Jan 20 2020

A331934 Number of semi-lone-child-avoiding rooted trees with n unlabeled vertices.

Original entry on oeis.org

1, 1, 1, 2, 4, 7, 15, 29, 62, 129, 279, 602, 1326, 2928, 6544, 14692, 33233, 75512, 172506, 395633, 911108, 2105261, 4880535, 11346694, 26451357, 61813588, 144781303, 339820852, 799168292, 1882845298, 4443543279, 10503486112, 24864797324, 58944602767, 139918663784

Offset: 1

Gus Wiseman, Feb 03 2020

nonn

A rooted tree is semi-lone-child-avoiding if there are no vertices with exactly one child unless the child is an endpoint/leaf.

			The a(1) = 1 through a(7) = 15 trees:
  o  (o)  (oo)  (ooo)   (oooo)    (ooooo)    (oooooo)
                (o(o))  (o(oo))   (o(ooo))   (o(oooo))
                        (oo(o))   (oo(oo))   (oo(ooo))
                        ((o)(o))  (ooo(o))   (ooo(oo))
                                  ((o)(oo))  (oooo(o))
                                  (o(o)(o))  ((o)(ooo))
                                  (o(o(o)))  ((oo)(oo))
                                             (o(o)(oo))
                                             (o(o(oo)))
                                             (o(oo(o)))
                                             (oo(o)(o))
                                             (oo(o(o)))
                                             ((o)(o)(o))
                                             ((o)(o(o)))
                                             (o((o)(o)))

Andrew Howroyd, Table of n, a(n) for n = 1..1000
David Callan, A sign-reversing involution to count labeled lone-child-avoiding trees, arXiv:1406.7784 [math.CO], (30-June-2014).
Gus Wiseman, Sequences counting series-reduced and lone-child-avoiding trees by number of vertices.

The same trees counted by leaves are A050381.
The locally disjoint version is A331872.
Matula-Goebel numbers of these trees are A331935.
Lone-child-avoiding rooted trees are A001678.
Cf. A000081, A000669, A198518, A289501, A291636, A306200, A320268, A330465, A330951, A331873, A331874, A331933, A331966.

sse[n_]:=Switch[n,1,{{}},2,{{{}}},_,Join@@Function[c,Union[Sort/@Tuples[sse/@c]]]/@Rest[IntegerPartitions[n-1]]];
Table[Length[sse[n]],{n,10}]

EulerT(v)={Vec(exp(x*Ser(dirmul(v,vector(#v,n,1/n))))-1, -#v)}
seq(n)={my(v=[1,1]); for(n=2, n-1, v=concat(v, EulerT(v)[n] - v[n])); v} \\ Andrew Howroyd, Feb 09 2020

Product_{k > 0} 1/(1 - x^k)^a(k) = A(x) + A(x)/x - x where A(x) = Sum_{k > 0} x^k a(k).

Euler transform is b(1) = 1, b(n > 1) = a(n) + a(n + 1).

Terms a(25) and beyond from Andrew Howroyd, Feb 09 2020

A001679 Number of series-reduced rooted trees with n nodes.

Original entry on oeis.org

1, 1, 1, 0, 2, 2, 4, 6, 12, 20, 39, 71, 137, 261, 511, 995, 1974, 3915, 7841, 15749, 31835, 64540, 131453, 268498, 550324, 1130899, 2330381, 4813031, 9963288, 20665781, 42947715, 89410092, 186447559, 389397778, 814447067, 1705775653, 3577169927

Offset: 0

N. J. A. Sloane

nonn

Also known as homeomorphically irreducible rooted trees, or rooted trees without nodes of degree 2.

A rooted tree is lone-child-avoiding if no vertex has exactly one child, and topologically series-reduced if no vertex has degree 2. This sequence counts unlabeled topologically series-reduced rooted trees with n vertices. Lone-child-avoiding rooted trees with n - 1 vertices are counted by A001678. - Gus Wiseman, Jan 21 2020

			G.f. = 1 + x + x^2 + 2*x^4 + 2*x^5 + 4*x^6 + 6*x^7 + 12*x^8 + 20*x^9 + ...
From _Gus Wiseman_, Jan 21 2020: (Start)
The a(1) = 1 through a(8) = 12 unlabeled topologically series-reduced rooted trees with n nodes (empty n = 3 column shown as dot) are:
  o  (o)  .  (ooo)   (oooo)   (ooooo)    (oooooo)    (ooooooo)
             ((oo))  ((ooo))  ((oooo))   ((ooooo))   ((oooooo))
                              (oo(oo))   (oo(ooo))   (oo(oooo))
                              ((o(oo)))  (ooo(oo))   (ooo(ooo))
                                         ((o(ooo)))  (oooo(oo))
                                         ((oo(oo)))  ((o(oooo)))
                                                     ((oo(ooo)))
                                                     ((ooo(oo)))
                                                     (o(oo)(oo))
                                                     (oo(o(oo)))
                                                     (((oo)(oo)))
                                                     ((o(o(oo))))
(End)

D. G. Cantor, personal communication.
F. Harary and E. M. Palmer, Graphical Enumeration, Academic Press, NY, 1973, p. 62, Eq. (3.3.9).
N. J. A. Sloane, A Handbook of Integer Sequences, Academic Press, 1973 (includes this sequence).
N. J. A. Sloane and Simon Plouffe, The Encyclopedia of Integer Sequences, Academic Press, 1995 (includes this sequence).

N. J. A. Sloane, Alois P. Heinz and Vaclav Kotesovec, Table of n, a(n) for n = 0..1000
P. J. Cameron, Some treelike objects, Quart. J. Math. Oxford, 38 (1987), 155-183. MR0891613 (89a:05009). See p. 155. - _N. J. A. Sloane_, Apr 18 2014
F. Harary, G. Prins, The number of homeomorphically irreducible trees and other species, Acta Math. 101 (1959) 141-162, W(x,y) equation (9a).
N. J. A. Sloane, Illustration of initial terms
Eric Weisstein's World of Mathematics, Series-Reduced Tree.
Gus Wiseman, Sequences counting series-reduced and lone-child-avoiding trees by number of vertices.
Index entries for sequences related to rooted trees
Index entries for sequences related to trees

Apart from initial term, same as A059123.
Cf. A000055 (trees by nodes), A000014 (homeomorphically irreducible trees by nodes), A000669 (homeomorphically irreducible planted trees by leaves), A000081 (rooted trees by nodes).
Cf. A246403.
The labeled version is A060313, with unrooted case A005512.
Matula-Goebel numbers of these trees are given by A331489.
Lone-child-avoiding rooted trees are counted by A001678(n + 1).
Cf. A004111, A060356, A198518, A254382, A291636, A330951, A331488, A331578.

with(powseries): with(combstruct): n := 30: Order := n+3: sys := {B = Prod(C,Z), S = Set(B,1 <= card), C = Union(Z,S)}:
G001678 := (convert(gfseries(sys,unlabeled,x)[S(x)], polynom)) * x^2: G0temp := G001678 + x^2:
G001679 := G0temp / x + G0temp - (G0temp^2+eval(G0temp,x=x^2))/(2*x): A001679 := 0,seq(coeff(G001679,x^i),i=1..n); # Ulrich Schimke (ulrschimke(AT)aol.com)
# adapted for Maple 16 or higher version by Vaclav Kotesovec, Jun 26 2014

terms = 37; (* F = G001678 *) F[] = 0; Do[F[x] = (x^2/(1 + x))*Exp[Sum[ F[x^k]/(k*x^k), {k, 1, j}]] + O[x]^j // Normal, {j, 1, terms + 1}];
G[x_] = 1 + ((1 + x)/x)*F[x] - (F[x]^2 + F[x^2])/(2*x) + O[x]^terms;
CoefficientList[G[x], x] (* Jean-François Alcover, Jan 12 2018 *)
urt[n_]:=Join@@Table[Union[Sort/@Tuples[urt/@ptn]],{ptn,IntegerPartitions[n-1]}];
Table[Length[Select[urt[n],Length[#]!=2&&FreeQ[Z@@#,{}]&]],{n,15}] (* _Gus Wiseman, Jan 21 2020 *)

{a(n) = local(A); if( n<3, n>0, A = x / (1 - x^2) + x * O(x^n); for(k=3, n-1, A /= (1 - x^k + x * O(x^n))^polcoeff(A, k)); polcoeff( (1 + x)*A - x*(A^2 + subst(A, x, x^2)) / 2, n))};

G.f. = 1 + ((1+x)*f(x) - (f(x)^2+f(x^2))/2)/x where f(x) is g.f. for A001678 (homeomorphically irreducible planted trees by nodes).
a(n) ~ c * d^n / n^(3/2), where d = A246403 = 2.18946198566085056388702757711... and c = 0.4213018528699249210965028... . - Vaclav Kotesovec, Jun 26 2014
For n > 1, this sequence counts lone-child-avoiding rooted trees with n nodes and more than two branches, plus lone-child-avoiding rooted trees with n - 1 nodes. So for n > 1, a(n) = A331488(n) + A001678(n). - Gus Wiseman, Jan 21 2020

Additional comments from Michael Somos, Oct 10 2003

A254382 Number of rooted labeled trees on n nodes such that every nonroot node is the child of a branching node or of the root.

Original entry on oeis.org

0, 1, 2, 3, 16, 85, 696, 6349, 72080, 918873, 13484080, 219335281, 3962458248, 78203547877, 1680235050872, 38958029188485, 970681471597216, 25847378934429361, 732794687650764000, 22032916968153975769, 700360446794528578520

Offset: 0

Geoffrey Critzer, Jan 29 2015

nonn

Here, a branching node is a node with at least two children.
In other words, a(n) is the number of labeled rooted trees on n nodes such that the path from every node towards the root reaches a branching node (or the root) in one step.
Also labeled rooted trees that are lone-child-avoiding except possibly for the root. The unlabeled version is A198518. - Gus Wiseman, Jan 22 2020

			a(5) = 85:
...0................0...............0-o...
...|.............../ \............ /|\....
...o..............o   o...........o o o...
../|\............/ \   ...................
.o o o..........o   o   ..................
These trees have 20 + 60 + 5 = 85 labelings.
From _Gus Wiseman_, Jan 22 2020: (Start)
The a(1) = 1 through a(4) = 16 trees (in the format root[branches]) are:
  1  1[2]  1[2,3]  1[2,3,4]
     2[1]  2[1,3]  1[2[3,4]]
           3[1,2]  1[3[2,4]]
                   1[4[2,3]]
                   2[1,3,4]
                   2[1[3,4]]
                   2[3[1,4]]
                   2[4[1,3]]
                   3[1,2,4]
                   3[1[2,4]]
                   3[2[1,4]]
                   3[4[1,2]]
                   4[1,2,3]
                   4[1[2,3]]
                   4[2[1,3]]
                   4[3[1,2]]
(End)

Vaclav Kotesovec, Table of n, a(n) for n = 0..200
David Callan, A sign-reversing involution to count labeled lone-child-avoiding trees, arXiv:1406.7784 [math.CO], (30-June-2014).
Gus Wiseman, Sequences counting series-reduced and lone-child-avoiding trees by number of vertices.

Cf. A231797, A052318 (condition is applied only to leaf nodes).
The unlabeled version is A198518
The non-planted case is A060356.
Labeled rooted trees are A000169.
Lone-child-avoiding rooted trees are A001678(n + 1).
Labeled topologically series-reduced rooted trees are A060313.
Labeled lone-child-avoiding unrooted trees are A108919.
Cf. A000014, A000669, A001679, A005512, A291636, A331488, A331578.

nn = 20; b = 1 + Sum[nn = n; n! Coefficient[Series[(Exp[x] - x)^n, {x, 0, nn}], x^n]*x^n/n!, {n,1, nn}]; c = Sum[a[n] x^n/n!, {n, 0, nn}]; sol = SolveAlways[b == Series[1/(1 - (c - x)), {x, 0, nn}], x]; Flatten[Table[a[n], {n, 0, nn}] /. sol]
nn = 30; CoefficientList[Series[1+x-1/Sum[SeriesCoefficient[(E^x-x)^n,{x,0,n}]*x^n,{n,0,nn}],{x,0,nn}],x] * Range[0,nn]! (* Vaclav Kotesovec, Jan 30 2015 *)
sps[{}]:={{}};sps[set:{i_,_}]:=Join@@Function[s,Prepend[#,s]&/@sps[Complement[set,s]]]/@Cases[Subsets[set],{i,_}];
lrt[set_]:=If[Length[set]==0,{},Join@@Table[Apply[root,#]&/@Join@@Table[Tuples[lrt/@stn],{stn,sps[DeleteCases[set,root]]}],{root,set}]];
Table[Length[Select[lrt[Range[n]],FreeQ[Z@@#,Integer[]]&]],{n,6}] (* Gus Wiseman, Jan 22 2020 *)

E.g.f.: A(x) satisfies 1/(1 - (A(x) - x)) = B(x) where B(x) is the e.g.f. for A231797.

a(n) ~ (1-exp(-1))^(n-1/2) * n^(n-1). - Vaclav Kotesovec, Jan 30 2015

cp's OEIS Frontend

A001678 Number of series-reduced planted trees with n nodes.

Views

Author

Keywords

Comments

Examples

References

Links

Crossrefs

Programs

Maple

Mathematica

PARI

PARI

Formula

Extensions

A291636 Matula-Goebel numbers of lone-child-avoiding rooted trees.

Views

Author

Keywords

Comments

Examples

Links

Crossrefs

Programs

Mathematica

Extensions

A331934 Number of semi-lone-child-avoiding rooted trees with n unlabeled vertices.

Views

Author

Keywords

Comments

Examples

Links

Crossrefs

Programs

Mathematica

PARI

Formula

Extensions

A001679 Number of series-reduced rooted trees with n nodes.

Views

Author

Keywords

Comments

Examples

References

Links

Crossrefs

Programs

Maple

Mathematica

PARI

Formula

Extensions

A254382 Number of rooted labeled trees on n nodes such that every nonroot node is the child of a branching node or of the root.

Views

Author

Keywords

Comments

Examples

Links

Crossrefs

Programs

Mathematica

Formula

A246403 Decimal expansion of a constant related to series-reduced trees.

Views

Author

Keywords

Examples

References

Crossrefs

Formula

Extensions

A363545 G.f. satisfies A(x) = exp( Sum_{k>=1} A(x^k) * x^k/(k * (1 - 2*x^k)) ).

Views

Author

Keywords