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m →Labelled structures: Graph (mathematics) is now a disambiguation link; please fix., replaced: labelled graph{{dn|date=January 2016}} → labelled graph using AWB |
m LaTeX spacing clean up, replaced: \,</math> → </math> (9) using AWB |
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The [[Pólya enumeration theorem]] solves this problem in the unlabelled case. Let ''f''(''z'') be the [[ordinary generating function]] (OGF) of the objects, then the OGF of the configurations is given by the substituted [[cycle index]]
:<math>Z(G)(f(z), f(z^2), \ldots, f(z^n)).
In the labelled case we use an [[exponential generating function]] (EGF) ''g''(''z'') of the objects and apply the [[Labelled enumeration theorem]], which says that the EGF of the configurations is given by
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This operator corresponds to the class
:<math>1 + E_1 + E_2 + E_3 + \cdots
and represents sequences, i.e. the slots are not being permuted and there is exactly one empty sequence. We have
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This operator corresponds to the class
:<math>C_1 + C_2 + C_3 + \cdots
i.e., cycles containing at least one object. We have
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The labelled even cycle operator <math>\mathfrak{C}_{\operatorname{even}}</math> is
:<math>C_2 + C_4 + C_6 + \cdots
which yields
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The series is
:<math>1 + S_1 + S_2 + S_3 + \cdots
i.e., the symmetric group is applied to the slots. This creates multisets in the unlabelled case and sets in the labelled case (there are no multisets in the labelled case because the labels distinguish multiple instances of the same object from the set being put into different slots). We include the empty set in both the labelled and the unlabelled case.
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so that
:<math>\mathfrak{M}(f(z)) = M(f(z), 1).
Evaluating <math>M(f(z), 1)</math> we obtain
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|<math>\mathcal{A} = \mathfrak{C}\{\mathcal{B}\}</math>
|<math>A(z) = \sum_{k=1}^{\infty} \frac{\phi(k)}{k} \ln \frac{1}{1 - B(z^{k})}</math> (where <math>\phi(k)
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|<math>\mathcal{A} = \Theta\mathcal{B}</math>
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|<math>\mathcal{A} = \mathcal{B} \circ \mathcal{C}</math>
|<math>A(z) = B(C(z))
|}
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This ''binomial convolution'' relation for the terms is equivalent to multiplying the EGFs,
:<math>A(z) \cdot B(z).
===Sequence===
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