Solution to a problem of Katona on counting cliques of weighted graphs
Abstract
A subset I of the vertex set V(G) of a graph G is called a k-clique independent set of G if no k vertices in I form a k-clique of G. An independent set is a 2-clique independent set. Let πk(G) denote the number of k-cliques of G. For a function w: V(G) → \0, 1, 2, …\, let G(w) be the graph obtained from G by replacing each vertex v by a w(v)-clique Kv and making each vertex of Ku adjacent to each vertex of Kv for each edge \u,v\ of G. For an integer m ≥ 1, consider any w with Σv ∈ V(G) w(v) = m. For U ⊂eq V(G), we say that w is uniform on U if w(v) = 0 for each v ∈ V(G) U and, for each u ∈ U, w(u) = m/|U| or w(u) = m/|U| . Katona asked if πk(G(w)) is smallest when w is uniform on a largest k-clique independent set of G. He placed particular emphasis on the Sperner graph Bn, given by V(Bn) = \X X ⊂eq \1, …, n\\ and E(Bn) = \\X,Y\ X ⊂neq Y ∈ V(Bn)\. He provided an affirmative answer for k = 2 (and any G). We determine graphs for which the answer is negative for every k ≥ 3. These include Bn for n ≥ 2. Generalizing Sperner's Theorem and a recent result of Qian, Engel and Xu, we show that πk(Bn(w)) is smallest when w is uniform on a largest independent set of Bn. We also show that the same holds for complete multipartite graphs and chordal graphs. We show that this is not true of every graph, using a deep result of Bohman on triangle-free graphs.
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