The asymptotic number of labeled graphs with given degree sequences

Asymptotics are obtained for the number of n × n symmetric non-negative integer matrices subject to the following constraints: (i) each row sum is specified and bounded, (ii) the entries are bounded, and (iii) a specified “sparse” set of entries must be zero. The result can be interpreted in terms of incidence matrices for labeled graphs.     

The asymptotic number of labeled connected graphs with a given number of vertices and edges

Let c(n, q) be the number of connected labeled graphs with n vertices and q ≤ N = (2n ) edges. Let x = q/n and k = q ? n. We determine functions w_k ? 1. a(x) and φ(x) such that c(n, q) ? w_k(q^N)eⁿφ(x)+a(x) uniformly for all n and q ≥ n. If ? > 0 is fixed, n→ ∞ and 4q > (1 + ?)n log n, this formula simplifies to c(n, q) ? (N^q) exp(–ne^?2q/n). on the other hand, if k = o(n^1/2), this formula simplifies to c(n, n + k) ? 1/2 w_k (3/π)^1/2 (e/12k)^k/2nⁿ?^(3k?1)/2.     

Nonseparable graphs with a given number of cycles

G. Ringel conjectured that for every positive integer n other than 2, 4, 5, 8, 9, and 16, there exists a nonseparable graph with n cycles. It is proved here that the conjecture is true even with the restriction to planar and hamiltonian graphs.     

On the geodetic number of permutation graphs

A vertex set S in a graph G is a geodetic set if every vertex of G lies on some u?v geodesic of G, where u,v∈S. The geodetic number g(G) of G is the minimum cardinality over all geodetic sets of G. Let G ₁ and G ₂ be disjoint copies of a graph G, and let σ:V(G ₁)→V(G ₂) be a bijection. Then, a permutation graph G _σ =(V,E) has the vertex set V=V(G ₁)∪V(G ₂) and the edge set E=E(G ₁)∪E(G ₂)∪{uv∣v=σ(u)}. For any connected graph G of order n≥3, we prove the sharp bounds 2≤g(G _σ )≤2n?(1+△(G)), where △(G) denotes the maximum degree of G. We give examples showing that neither is there a function h ₁ such that g(G)<h ₁(g(G _σ )) for all pairs (G,σ), nor is there a function h ₂ such that h ₂(g(G))>g(G _σ ) for all pairs (G,σ). Further, we characterize permutation graphs G _σ satisfying g(G _σ )=2|V(G)|?(1+△(G)) when G is a cycle, a tree, or a complete k-partite graph.     

The forcing number of graphs with given girth

In this paper, we study a dynamic coloring of the vertices of a graph G that starts with an initial subset S of colored vertices, with all remaining vertices being non-colored. At each discrete time interval, a colored vertex with exactly one non-colored neighbor forces this non-colored neighbor to be colored. The initial set S is called a forcing set of G if, by iteratively applying the forcing process, every vertex in G becomes colored. The forcing number, originally known as the zero forcing number, and denoted F (G), of G is the cardinality of a smallest forcing set of G. We study lower bounds on the forcing number in terms of its minimum degree and girth, where the girth g of a graph is the length of a shortest cycle in the graph. Let G be a graph with minimum degree δ ≥ 2 and girth g ≥ 3. Davila and Kenter [Theory and Applications of Graphs, Volume 2, Issue 2, Article 1, 2015] conjecture that F (G) ≥ δ + (δ ? 2)(g ? 3). This conjecture has recently been proven for g ≤ 6. The conjecture is also proven when the girth g ≥ 7 and the minimum degree is sufficiently large. In particular, it holds when g = 7 and δ ≥ 481, when g = 8 and δ ≥ 649, when g = 9 and δ ≥ 30, and when g = 10 and δ ≥ 34. In this paper, we prove the conjecture for g ∈ {7, 8, 9, 10} and for all values of δ ≥ 2.     

The maximum interval number of graphs with given genus

The interval number of a graph G, denoted i(G), is the least positive integer t such that G is the intersection graph of sets, each of which is the union of t compact real intervals. It is known that every planar graph has interval number at most 3 and that this result is best possible. We investigate the maximum value of the interval number for graphs with higher genus and show that the maximum value of the interval number of graphs with genus g is between ?√g? and 3 + ?√3g?. We also show that the maximum arboricity of graphs with genus g is either 1 + ?√3g? or 2 + ?√3g?.     

The number of graphs and a random graph with a given degree sequence

We consider the set of all graphs on n labeled vertices with prescribed degrees D = (d₁,…,d_n). For a wide class of tame degree sequences D we obtain a computationally efficient asymptotic formula approximating the number of graphs within a relative error which approaches 0 as n grows. As a corollary, we prove that the structure of a random graph with a given tame degree sequence D is well described by a certain maximum entropy matrix computed from D. We also establish an asymptotic formula for the number of bipartite graphs with prescribed degrees of vertices, or, equivalently, for the number of 0‐1 matrices with prescribed row and column sums. © 2012 Wiley Periodicals, Inc. Random Struct. Alg., 2013     

The number of independent sets in unicyclic graphs with a given diameter

Let U_n,d denote the set of unicyclic graphs with a given diameter d. In this paper, the unique unicyclic graph in U_n,d with the maximum number of independent sets, is characterized.     

List coloring of graphs having cycles of length divisible by a given number

Let G be a graph and χ_l(G) denote the list chromatic number of G. In this paper we prove that for every graph G for which the length of each cycle is divisible by l (l≥3), χ_l(G)≤3.     

Infinite families of crossing-critical graphs with a given crossing number

A graph is crossing-critical if deleting any edge decreases its crossing number on the plane. It is proved that, for any n ? 3, there is an infinite family of 3-connected crossing-critical graphs with crossing number n.     

On the number of graphs with a given endomorphism monoid

For a given finite monoid , let be the number of graphs on n vertices with endomorphism monoid isomorphic to . For any nontrivial monoid we prove that where and are constants depending only on with .For every k there exists a monoid of size k with , on the other hand if a group of unity of has a size k>2 then .     

The smallest signless Laplacian spectral radius of graphs with a given clique number

The signless Laplacian spectral radius of a graph G is the largest eigenvalue of its signless Laplacian matrix. In this paper, the first four smallest values of the signless Laplacian spectral radius among all connected graphs with maximum clique of size greater than or equal to 2 are obtained.     

Spectral radius of graphs with given matching number

In this paper, we show that of all graphs of order n with matching number β, the graphs with maximal spectral radius are K_n if n = 2β or 2β + 1; if 2β + 2 ? n < 3β + 2; or if n = 3β + 2; if n > 3β + 2, where is the empty graph on t vertices.     

Enumeration of labeled connected graphs with given order and size

We deduce a new formula for the number of labeled connected graphs with given order and number of edges in terms of the block generating function. Applying this formula, we exactly and asymptotically enumerate cacti with given order and cyclomatic number.