Subgraphs smaller than the girth

For graphs A, B, let () denote the number of subsets of nodes of A for which the induced subgraph is B. If G and H both have girth > k, and if () = () for every k-node tree T, then for every k-node forest F, () = (). Say the spread of a tree is the number of nodes in a longest path. If G is regular of degree d, on n nodes, with girth > k, and if F is a forest of total spread ≤k, then the value of () depends only on n and d.     

The circular chromatic number of the Mycielskian of G

In a search for triangle-free graphs with arbitrarily large chromatic numbers, Mycielski developed a graph transformation that transforms a graph G into a new graph μ(G), we now call the Mycielskian of G, which has the same clique number as G and whose chromatic number equals χ(G) + 1. Chang, Huang, and Zhu [G. J. Chang, L. Huang, & X. Zhu, Discrete Math, to appear] have investigated circular chromatic numbers of Mycielskians for several classes of graphs. In this article, we study circular chromatic numbers of Mycielskians for another class of graphs G. The main result is that χ_c(μ(G)) = χ(μ(G)), which settles a problem raised in [G. J. Chang, L. Huang, & X. Zhu, Discrete Math, to appear, and X. Zhu, to appear]. As χ_c(G) = and χ(G) = , consequently, there exist graphs G such that χ_c(G) is as close to χ(G) − 1 as you want, but χ_c(μ(G)) = χ(μ(G)). © 1999 John Wiley & Sons, Inc. J Graph Theory 32: 63–71, 1999     

Graph minors and linkages

Bollobás and Thomason showed that every 22k‐connected graph is k‐linked. Their result used a dense graph minor. In this paper, we investigate the ties between small graph minors and linkages. In particular, we show that a 6‐connected graph with a K minor is 3‐linked. Further, we show that a 7‐connected graph with a K minor is (2,5)‐linked. Finally, we show that a graph of order n and size at least 7n?29 contains a K minor. © 2005 Wiley Periodicals, Inc. J Graph Theory 49: 75–91, 2005     

Distinguishing two graph-encoded manifolds of Lins

Lins has conjectured that the two 3-manifolds that he refers to as H and H̄ are not homeomorphic. He suggests that their fundamental groups may be the same, but that they may be distinguishable by their quantum invariants. This article describes the proof that they, in fact, have different fundamental groups. © 1999 John Wiley & Sons, Inc. J Graph Theory 32: 298–302, 1999     

On the minimum size of tight hypergraphs

A k-graph, H = (V, E), is tight if for every surjective mapping f: V → {1,….k} there exists an edge α ? E sicj tjat f|_α is injective. Clearly, 2-graphs are tight if and only if they are connected. Bounds for the minimum number ? of edges in a tight k-graph with n vertices are given. We conjecture that ? for every n and prove the equality when 2n + 1 is prime. From the examples, minimal embeddings of complete graphs into surfaces follow. © 1992 John Wiley & Sons, Inc.     

Total relative displacement of vertex permutations of K

Let α denote a permutation of the n vertices of a connected graph G. Define δ_α(G) to be the number , where the sum is over all the unordered pairs of distinct vertices of G. The number δ_α(G) is called the total relative displacement of α (in G). So, permutation α is an automorphism of G if and only if δ_α(G) = 0. Let π(G) denote the smallest positive value of δ_α(G) among the n! permutations α of the vertices of G. A permutation α for which π(G) = δ_α(G) has been called a near‐automorphism of G [ 2 ]. We determine π(K) and describe permutations α of K for which π(K) = δ_α(K). This is done by transforming the problem into the combinatorial optimization problem of maximizing the sums of the squares of the entries in certain t by t matrices with non–negative integer entries in which the sum of the entries in the ith row and the sum of the entries in the ith column each equal to n_i,1≤i≤t. We prove that for positive integers, n₁≤n₂≤…≤n_t, where t≥2 and n_t≥2, where k₀ is the smallest index for which n = n+1. As a special case, we correct the value of π(K_m,n), for all m and n at least 2, given by Chartrand, Gavlas, and VanderJagt [ 2 ]. © 2002 Wiley Periodicals, Inc. J Graph Theory 41: 85–100, 2002     

Normal cirulant graphs with noncyclic regular subroups

We prove that any circulant graph of order n with connection set S such that n and the order of ?(S), the subgroup of ? that fixes S set‐wise, are relatively prime, is also a Cayley graph on some noncyclic group, and shows that the converse does not hold in general. In the special case of normal circulants whose order is not divisible by 4, we classify all such graphs that are also Cayley graphs of a noncyclic group, and show that the noncyclic group must be metacyclic, generated by two cyclic groups whose orders are relatively prime. We construct an infinite family of normal circulants whose order is divisible by 4 that are also normal Cayley graphs on dihedral and noncyclic abelian groups. © 2005 Wiley Periodicals, Inc. J Graph Theory     

Acyclic edge chromatic number of outerplanar graphs

A proper edge coloring of a graph G is called acyclic if there is no 2‐colored cycle in G. The acyclic edge chromatic number of G, denoted by χ(G), is the least number of colors in an acyclic edge coloring of G. In this paper, we determine completely the acyclic edge chromatic number of outerplanar graphs. The proof is constructive and supplies a polynomial time algorithm to acyclically color the edges of any outerplanar graph G using χ(G) colors. © 2009 Wiley Periodicals, Inc. J Graph Theory 64: 22–36, 2010     

Enumeration of graphs by degree sequence

The degree sequence (d₀, d₁, …, d_p-1) of a graph G of order p is defined by d_k = the number of points of G of degree k. Methods of Robinson are extended to produce a generating function F(x₀, x₁, x₂, …) where the coefficient of x…x is the number of graphs of order p having degree sequence (d₀, …, d_p-1).     

On a conjecture on maximal planar sequences

Let d1 d2 dp denote the nonincreasing sequence d₁, …, d₁, d₂, …, d₂, …, d_p, …, d_p, where the term d_i appears k_i times (i = 1, 2, …, p). In this work the author proves that the maximal 2-sequences: 7³6¹5¹⁵, 7⁵6¹5¹⁷, 7⁷6¹5¹⁹ are planar graphical, in contrast to a conjecture by Schmeichel and Hakimi.     

An extremal problem for subdivisions of K

It is proved that every graph G with ‖G‖ ≥ 2|G| − 5, |G| ≥ 6, and girth at least 5, except the Petersen graph, contains a subdivision of K, the complete graph on five vertices minus one edge. © 1999 John Wiley & Sons, Inc, J. Graph Theory 30: 261–276, 1999     

On Ramsey‐type positional games

Let K denote the graph obtained from the complete graph K_s+t by deleting the edges of some K_t‐subgraph. We prove that for each fixed s and sufficiently large t, every graph with chromatic number s+t has a K minor. © 2010 Wiley Periodicals, Inc. J Graph Theory 65: 343–350, 2010     

A generalization of Plantholt's theorem

Let K denote the complete graph K_2n+1 with each edge replicated r times and let χ′(G) denote the chromatic index of a multigraph G. A multigraph G is critical if χ′(G) > χ′(G/e) for each edge e of G. Let S be a set of sn – 1 edges of K. We show that, for 0 < s ≦ r, G/S is critical and that χ′ (G/(S ∪{e})) = 2rn + r – s for all e ∈ E(G/S). Plantholt [M. Plantholt, The chromatic index of graphs with a spanning star. J. Graph Theory 5 (1981) 5–13] proved this result in the case when r = 1.     

On the number of hamilton cycles in a random graph

Let a random graph G be constructed by adding random edges one by one, starting with n isolated vertices. We show that with probability going to one as n goes to infinity, when G first has minimum degree two, it has at least (log n) distinct hamilton cycles for any fixed ?>0.     

The size of strength-maximal graphs

Let G be a graph and let k′(G) be the edge-connectivity of G. The strength of G, denoted by k?′(G), is the maximum value of k′(H), where H runs over all subgraphs of G. A simple graph G is called k-maximal if k?′(G) ≤ k but for any edge e ∈ E(G^c), k?′(G + e) ≥ k + 1. Let G be a k-maximal graph of order n. In [3], Mader proved |E(G)| ≤ (n - k)k + (). In this note, we shall show (n - 1)k - () In?n/k + 2)? ≤ |E(G|, and characterize the extremal graphs. We shall also give a characterization of all k-maximal graphs.     

Star factorizations of graph products

A k‐star is the graph K_1,k. We prove a general theorem about k‐star factorizations of Cayley graphs. This is used to give necessary and sufficient conditions for the existence of k‐star factorizations of any power (K_q)^s of a complete graph with prime power order q, products C × C ×··· × C of k cycles of arbitrary lengths, and any power (C_r)^s of a cycle of arbitrary length. © 2001 John Wiley & Sons, Inc. J Graph Theory 36: 59–66, 2001     

On invariant measures of extensions of Markov transition functions

By using the LITTLEWOOD matrices A_2n we generalize CLARKSON' S inequalities, or equivalently, we determine the norms ‖A_2n: l(L_P) → l(L_P)‖ completely. The result is compared with the norms ‖A_2n: l → l‖, which are calculated implicitly in PIETSCH [6].     

The chromatic index of graphs of even order with many edges

We show that, for r = 1, 2, a graph G with 2n + 2 (≥6) vertices and maximum degree 2n + 1 - r is of Class 2 if and only if |E(G/v)| > () - rn, where v is a vertex of G of minimum degree, and we make a conjecture for 1 ≤ r ≤ n, of which this result is a special case. For r = 1 this result is due to Plantholt.     

Short cycle covers of graphs and nowhere‐zero flows

A shortest cycle cover of a graph G is a family of cycles which together cover all the edges of G and the sum of their lengths is minimum. In this article we present upper bounds to the length of shortest cycle covers, associated with the existence of two types of nowhere‐zero flows—circular flows and Fano flows. Fano flows, or Fano colorings, are nowhere‐zero ?‐flows on cubic graphs, with certain restrictions on the flow values meeting at a vertex. Such flows are conjectured to exist on every bridgless cubic graph. Copyright © 2011 Wiley Periodicals, Inc. J Graph Theory 68:340‐348, 2011     

Function Spaces with Exponential Weights II

This paper is a continuation of [8]. We study weighted function spaces of type B and F on the Euclidean space Rⁿ, where u is a weight function of at most exponential growth. In particular, u(χ (±|χ|) is an admissible weight. We deal with atomic decompositions of these spaces. Furthermore, we prove that the spaces B and F are isomorphic to the corresponding unweighted spaces B and F.