OFFSET
1,7
COMMENTS
Row n contains 1+A061775(n) entries (= 1 + number of vertices of the rooted tree).
The Matula-Goebel number of a rooted tree can be defined in the following recursive manner: to the one-vertex tree there corresponds the number 1; to a tree T with root degree 1 there corresponds the t-th prime number, where t is the Matula-Goebel number of the tree obtained from T by deleting the edge emanating from the root; to a tree T with root degree m>=2 there corresponds the product of the Matula-Goebel numbers of the m branches of T.
After activating the Maple program, the command mm(n) will yield the matching polynomial of the rooted tree corresponding to the Matula-Goebel number n.
REFERENCES
C. D. Godsil, Algebraic Combinatorics, Chapman & Hall, New York, 1993.
LINKS
É. Czabarka, L. Székely, and S. Wagner, The inverse problem for certain tree parameters, Discrete Appl. Math., 157, 2009, 3314-3319.
Emeric Deutsch, Rooted tree statistics from Matula numbers, arXiv:1111.4288 [math.CO], 2011.
F. Goebel, On a 1-1-correspondence between rooted trees and natural numbers, J. Combin. Theory, B 29 (1980), 141-143.
I. Gutman and A. Ivic, On Matula numbers, Discrete Math., 150, 1996, 131-142.
I. Gutman and Yeong-Nan Yeh, Deducing properties of trees from their Matula numbers, Publ. Inst. Math., 53 (67), 1993, 17-22.
D. W. Matula, A natural rooted tree enumeration by prime factorization, SIAM Rev. 10 (1968) 273.
FORMULA
Define b(n) (c(n)) to be the generating polynomials of the matchings of the rooted tree with Matula-Goebel number n that contain (do not contain) the root, with respect to the size of the matching. We have the following recurrence for the pair M(n)=[b(n),c(n)]. M(1)=[0,1]; if n=prime(t) (=the t-th prime), then M(n)=[xc(t),b(t)+c(t)]; if n=r*s (r,s,>=2), then M(n)=[b(r)*c(s)+c(r)*b(s), c(r)*c(s)]. Then m(n)=b(n)+c(n) is the generating polynomial of the matchings of the rooted tree with respect to the size of the matchings (a modified matching polynomial). The actual matching polynomial is obtained by the substitution x = -1/x^2, followed by multiplication by x^N(n), where N(n) is the number of vertices of the rooted tree.
MAPLE
with(numtheory): N := proc (n) local r, s: r := proc (n) options operator, arrow: op(1, factorset(n)) end proc: s := proc (n) options operator, arrow: n/r(n) end proc: if n = 1 then 1 elif bigomega(n) = 1 then 1+N(pi(n)) else N(r(n))+N(s(n))-1 end if end proc: M := proc (n) local r, s: r := proc (n) options operator, arrow: op(1, factorset(n)) end proc: s := proc (n) options operator, arrow: n/r(n) end proc: if n = 1 then [0, 1] elif bigomega(n) = 1 then [x*M(pi(n))[2], M(pi(n))[1]+M(pi(n))[2]] else [M(r(n))[1]*M(s(n))[2]+M(r(n))[2]*M(s(n))[1], M(r(n))[2]*M(s(n))[2]] end if end proc: m := proc (n) options operator, arrow: sort(expand(M(n)[1]+M(n)[2])) end proc: mm := proc (n) options operator, arrow: sort(expand(x^N(n)*subs(x = -1/x^2, m(n)))) end proc: for n to 19 do seq(coeff(mm(n), x, j), j = 0 .. N(n)) end do; # yields sequence in triangular form
MATHEMATICA
r[n_] := FactorInteger[n][[1, 1]];
s[n_] := n/r[n];
V[n_] := Which[n == 1, 1, PrimeOmega[n] == 1, 1 + V[PrimePi[n]], True, V[r[n]] + V[s[n]] - 1];
M[n_] := Which[n == 1, {0, 1}, PrimeOmega[n] == 1, {x*M[PrimePi[n]][[2]], M[PrimePi[n]][[1]] + M[PrimePi[n]][[2]]}, True, {M[r[n][[1]]*M[s[n]][[2]] + M[r[n]][[2]]*M[s[n]][[1]], M[r[n]][[2]]*M[s[n]][[2]]}];
m[n_] := M[n] // Total;
mm[n_] := x^V[n]*(m[n] /. x -> -1/x^2);
T[n_] := CoefficientList[mm[n], x];
Table[T[n], {n, 1, 19}] // Flatten (* Jean-François Alcover, Jun 21 2024, after Maple code *)
PROG
(Sage)
def M(n) :
if n == 1 : return [0, 1, 1]
if 1 == sloane.A001222(n) : # bigomega
mpi = M(prime_pi(n))
return [x*mpi[1], mpi[0]+mpi[1], 1+mpi[2]]
r = max(prime_divisors(n)); mr = M(r); ms = M(n//r)
return [mr[0]*ms[1]+mr[1]*ms[0], mr[1]*ms[1], mr[2]+ms[2]-1]
def A193403_coeffs(n) :
mn = M(n)
q = (mn[0]+mn[1]).subs(x=-1/x^2)
p = expand(x^mn[2]*q)
return coefficient_list(p, x)
for n in (1..19) : print(A193403_coeffs(n)) # Peter Luschny, Feb 12 2012
CROSSREFS
KEYWORD
sign,tabf
AUTHOR
Emeric Deutsch, Feb 12 2012
STATUS
approved