Let a set \([n] = \{1,2,\ldots,n\}\) be given. Finding a subset \( S \) of \( 2^{[n]} \) with minimum cardinality such that, for any two distinct elements \( x, y \in [n] \), there exist disjoint subsets \( A_x, A_y \in \mathcal{S} \) such that \( x \in A_x \) and \( y \in A_y \) is called the \emph{extremal set} problem. In this paper, we define the Extremal Set Decision (ESD) Problem and study its complexity.

A cyclic base ordering of a connected graph \( G \) is a cyclic ordering of \( E(G) \) such that every \( |V(G)| – 1 \) cyclically consecutive edges form a spanning tree of \( G \). Let \( G \) be a graph with \( E(G) \neq \emptyset \) and let \( \omega(G) \) denote the number of components in \( G \). The invariants \( d(G) \) and \( \gamma(G) \) are respectively defined as \( d(G) = \frac{|E(G)|}{|V(G)| – \omega(G)} \) and \( \gamma(G) = \text{max}\{d(H)\} \), where \( H \) runs over all subgraphs of \( G \) with \( E(H) \neq \emptyset \). A graph \( G \) is uniformly dense if \( d(G) = \gamma(G) \). Kajitani et al. [8] conjectured in 1988 that a connected graph \( G \) has a cyclic base ordering if and only if \( G \) is uniformly dense. In this paper, we show that this conjecture holds for some classes of uniformly dense graphs.

A graph \( G \) is a \((t, r)\)-regular graph if every collection of \( t \) independent vertices is collectively adjacent to exactly \( r \) vertices. Let \( p, s \), and \( m \) be positive integers, where \( m \geq 2 \), and let \( G \) be a \((2, r)\)-regular graph. If \( n \) is sufficiently large, then \( G \) is isomorphic to \( K_s + mK_p \), where \( 2(p-1) + s = r \). A nested \((2, r)\)-regular graph is constructed by replacing selected cliques in a \((2, r)\)-regular graph with a \((2, r’)\)-regular graph and joining the vertices of the peripheral cliques. We examine the network properties such as the average path length, clustering coefficient, and the spectrum of these nested graphs.

Given a graph \( G \), we show how to compute the number of (perfect) matchings in the graphs \( G \Box P_n \) and \( G \Box C_n \), by looking at appropriate entries in a power of a particular matrix. We give some generalizations and extensions of this result, including showing how to compute tilings of \( k \times n \) boards using monomers, dimers, and \( 2 \times 2 \) tiles.

Consider a simple undirected graph \( G = (V, E) \). A family of subtrees, \(\{T_v\}_{v \in V}\), of a tree \(\mathcal{T}\) is called a \((\mathcal{T}; t)\)-representation of \(G\) provided \( uv \in E \) if and only if \( |T_u \cap T_v| \geq t \). In this paper, we consider \((\mathcal{T}; t)\)-representations for graphs containing large asteroidal sets, where \(\mathcal{T}\) is a subdivision of the \(n\)-star \(K_{1, n}\). An asteroidal set in a graph \(G\) is a subset \(A\) of the vertex set such that for all 3-element subsets of \(A\), there exists a path in \(G\) between any two of these vertices which avoids the neighborhood of the third vertex. We construct a representation of an asteroidal set of size \( n + \sum_{k=2}^{n} \binom{n}{k} \binom{t-2}{k-1} \) and show that no graph containing a larger asteroidal set can be represented.