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Search: id:A059066
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| A059066 |
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Card-matching numbers (Dinner-Diner matching numbers). |
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1
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| 1, 2, 3, 0, 1, 10, 24, 27, 16, 12, 0, 1, 56, 216, 378, 435, 324, 189, 54, 27, 0, 1, 346, 1824, 4536, 7136, 7947, 6336, 3936, 1728, 684, 128, 48, 0, 1, 2252, 15150, 48600, 99350, 144150, 156753, 131000, 87075, 45000, 19300, 6000
(list; graph; listen)
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OFFSET
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0,2
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COMMENT
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This is a triangle of card matching numbers. A deck has 3 kinds of cards, n of each kind. The deck is shuffled and dealt in to 3 hands each with n cards. A match occurs for every card in the j-th hand of kind j. Triangle T(n,k) is the number of ways of achieving exactly k matches (k=0..3n). The probability of exactly k matches is T(n,k)/((3n)!/n!^3).
Rows have lengths 1,4,7,10,...
Analogous to A008290 - Zerinvary Lajos (zerinvarylajos(AT)yahoo.com), Jun 22 2005
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REFERENCES
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F. N. David and D. E. Barton, Combinatorial Chance, Hafner, NY, 1962, Ch. 7 and Ch. 12.
F. F. Knudsen and I. Skau, On the Asymptotic Solution of a Card-Matching Problem, Mathematics Magazine 69 (1996), 190-197.
B. H. Margolius, The Dinner-Diner Matching Problem, Mathematics Magazine, 76 (2003), 107-118.
S. G. Penrice, Derangements, permanents and Christmas presents, The American Mathematical Monthly 98(1991), 617-620.
J. Riordan, An Introduction to Combinatorial Analysis, Wiley, 1958, p. 174-178.
R. P. Stanley, Enumerative Combinatorics Volume I, Cambridge University Press, 1997, p. 71.
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LINKS
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Barbara H. Margolius, Dinner-Diner Matching Probabilities
Index entries for sequences related to card matching
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FORMULA
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G.f.: sum(coeff(R(x, n, k), x, j)*(t-1)^j*(n*k-j)!, j=0..n*k) where n is the number of kinds of cards (3 in this case), k is the number of cards of each kind and R(x, n, k) is the rook polynomial given by R(x, n, k)=(k!^2*sum(x^j/((k-j)!^2*j!))^n (see Stanley or Riordan). coeff(R(x, n, k), x, j) indicates the coefficient for x^j of the rook polynomial.
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EXAMPLE
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There are 27 ways of matching exactly 2 cards when there are 2 cards of each kind and 3 kinds of card so T(2,2)=27.
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MAPLE
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p := (x, k)->k!^2*sum(x^j/((k-j)!^2*j!), j=0..k); R := (x, n, k)->p(x, k)^n; f := (t, n, k)->sum(coeff(R(x, n, k), x, j)*(t-1)^j*(n*k-j)!, j=0..n*k);
for n from 0 to 7 do seq(coeff(f(t, 3, n), t, m)/n!^3, m=0..3*n); od;
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CROSSREFS
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Cf. A008290, A059056-A059071.
Cf. A008290.
Sequence in context: A163465 A004443 A008290 this_sequence A059067 A065861 A126832
Adjacent sequences: A059063 A059064 A059065 this_sequence A059067 A059068 A059069
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KEYWORD
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nonn,tabf,nice
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AUTHOR
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Barbara Haas Margolius (margolius(AT)math.csuohio.edu)
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