Abstract
We establish a broad generalization of Whitney's broken circuit theorem on the chromatic polynomial of a graph to sums of type $\sum_{A\subseteq S} f(A)$ where $S$ is a finite set and $f$ is a mapping from the power set of $S$ into an abelian group. We give applications to the domination polynomial and the subgraph component polynomial of a graph, the chromatic polynomial of a hypergraph, the characteristic polynomial and Crapo's beta invariant of a matroid, and the principle of inclusion-exclusion. Thus, we discover several known and new results in a concise and unified way. As further applications of our main result, we derive a new generalization of the maximums-minimums identity and of a theorem due to Blass and Sagan on the Möbius function of a finite lattice, which generalizes Rota's crosscut theorem. For the classical Möbius function, both Euler's totient function and its Dirichlet inverse, and the reciprocal of the Riemann zeta function we obtain new expansions involving the greatest common divisor resp. least common multiple. We finally establish an even broader generalization of Whitney's broken circuit theorem in the context of convex geometries (antimatroids).
Highlights
Whitney’s broken circuit theorem [29] is one of the most significant results on the chromatic polynomial of a graph
As further applications of our main result, we derive a new generalization of the maximums-minimums identity and of a theorem due to Blass and Sagan on the Mobius function of a finite lattice, which generalizes Rota’s crosscut theorem
The significance of the chromatic polynomial lies in the fact that for any x ∈ N it evaluates to the number of proper x-colourings of G, that is, the number of mappings f : V → {1, . . . , x} such that f (v) = f (w) for any edge {v, w} ∈ E
Summary
Whitney’s broken circuit theorem [29] is one of the most significant results on the chromatic polynomial of a graph. Some new results are deduced as well, among them a broken circuit theorem for the recent subgraph component polynomial [3, 27], a generalization of the Blass-Sagan theorem on the Mobius function of a finite lattice [7], and a generalization of the well-known maximum-minimums identity [23]. This main result generalizes Whitney’s broken circuit theorem to sums of the type A⊆S f (A) where S is a finite set and f is a mapping from the power set of S to an abelian group. The electronic journal of combinatorics 21(4) (2014), #P4.32 this generalization states that, if its requirements are fulfilled, the sum A⊆S f (S) can be restricted to the free sets of a convex geometry on S
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