Edge-superconnectivity of semiregular cages with odd girth

A graph is said to be edge-superconnected if each minimum edge-cut consists of all the edges incident with some vertex of minimum degree. A graph G is said to be a {d, d + 1}- semiregular graph if all its vertices have degree either d or d+1. A smallest {d,d+1}-semiregular graph G with girth g is said to be a ({d, d+1}; g)-cage.We show that every ({d, d+1}; g)-cage with odd girth g is edge-superconnected.Peer Reviewe

Further topics in connectivity

Continuing the study of connectivity, initiated in §4.1 of the Handbook, we survey here some (sufficient) conditions under which a graph or digraph has a given connectivity or edge-connectivity. First, we describe results concerning maximal (vertex- or edge-) connectivity. Next, we deal with conditions for having (usually lower) bounds for the connectivity parameters. Finally, some other general connectivity measures, such as one instance of the so-called “conditional connectivity,” are considered. For unexplained terminology concerning connectivity, see §4.1.Peer ReviewedPostprint (published version

Estudio sobre algunas nuevas clases de conectividad condicional en grafos dirigidos

La conectividad condicional, definida por Harary en 1983, mide el mínimo número de vértices (o ramas) que hay que eliminar de un grafo o digrafo de forma que todas las componentes conexas resultantes tengan una propiedad prefijada de antemano. La importancia de los diferentes tipos de conectividad condicional está unida al concepto de supervivencia de las componentes que se determinan cuando la red se interrumpe, lo que se expresa especificando las propiedades de estas componentes. Engloban tanto la conectividad estándar como la superconectividad ya que pueden ser interpretadas como conectividades condicionales con respecto a la propiedad que consiste en tener más de cero vértices o un vértice respectivamente.En esta tesis presentamos condiciones suficientes de dos tipos que garantizan altas conectividades condicionales: cotas superiores sobre diámetro y cotas inferiores sobre el orden, ambas formuladas en términos del girth en el caso de grafos, o bien en función del semigirth l en el caso de digrafos.El primer tipo de conectividad condicional abordada es la t-distancia conectividad que juega un papel importante a la hora de medir la fiabilidad de la red como una función de la distancia entre los nodos que queremos comunicar. En este caso se requiere que los conjuntos desconectadotes separen vértices que estaban suficientemente alejados en el (di)grafo original. Se define el t-grado y se muestra que los parámetros que miden la t-distancia conectividad la arco t-distancia conectividad y el t-grado están relacionados por desigualdades que generalizan las desigualdades conocidas para las conectividades estándar. Además, se prueba que otra de las propiedades que estos nuevos parámetros mantienen es la independencia.El trabajo realizado previamente permite profundizar en el estudio de la superconectividad de (di)grafos y de digrafos bipartitos. Se aborda el problema de desconectar de manera no trivial un digrafo superconectado, centrándonos en calcular la máxima distancia a la que se encuentra alejado un vértice de un conjunto desconectador no trivial de cardinal relativamente pequeño. Se introducen los parámetros que miden la superconectividad de un digrafo superconectado, y se estudian condiciones suficientes sobre el diámetro y el orden para obtener cotas inferiores sobre estas medidas de superconectividad. Por último se desarrolla un estudio en el caso de grafos, paralelo al realizado en el caso dirigido. Se expone una tabla en cuyas entradas figuran los órdenes de los grafos con el mayor número de vértices que se conocen hasta el momento junto con sus conectividades respectivas.La última parte de la tesis está dedicado al estudio de grafos que modelan redes conectadas de forma óptima con respecto a la siguiente propiedad de tolerancia a fallos: Cuando algunos nodos o uniones fallan, se exige que en las componentes que se determinan en la red haya un número mínimo de nodos conectados entre sí. Esta conectividad condicional se denomina extraconectividad, que corresponde con la propiedad consistente en tener al menos un cierto número de vértices. Desde este punto de vista, tanto la conectividad estándar como la superconectividad, constituyen medidas de conectividad condicional. El trabajo llevado a cabo mejora sustancialmente las primeras condiciones suficientes sobre el diámetro dadas por Fiol y Fàbrega quienes ya habían conjeturado que la cota superior sobre el diámetro que se había encontrado era posible mejorarla.The conditional connectivity defined by Harary in 1983, gives the minimum number of vertices or edges which have to be eliminated from a graph or a digraph in such a way all the resulting connected components satisfy a determined property The importance of the different types of conditional connectivity is linked to the concept of survival of the components that determine when the network is interrupted, which is expressed by specifying the properties of these components. They include both connectivity standard as superconectividad as they can be interpreted as a conditional connectivities with respect to the property that is to have more than zero points or a vertex respectively.In this thesis we present sufficient conditions of two types that guarantee high conditional connectivities: upper bounds on diameter and lower bounds on the order, both in terms of girth made in the case graph, or in terms of semigirth l in the directed case.The first type of conditional connectivity addressed is the t-distance connectivity that plays an important role in measuring the reliability of the network as a function of the distance between the nodes that we want to communicate. In this case disconnecting sets are required to separate vertices that were sufficiently distant in the original (di)graph. The t-degree is defined and it is shown that the parameters that measure the t-distance connectivity the arc t-distance connectivity and t-degree inequalities are related by the same inequalities known for standard connectivities. In addition, it is proved that another of the properties that these new parameters keep is the independence.The work done previously allows to study in depth the superconectivity of digraphs and bipartite digraphs. It addresses the problem of disconnecting in a non-trivial way a superconnected digraph, focusing on calculating the maximum distance that is a remote vertex from a non-trivial disconnecting set of cardinality relatively small. The superconnectivity parameters are introduced and sufficient conditions on the diameter and on the order to obtain good measures of superconnectivity are given. Finally, there has been a case study in graphs, conducted in parallel to the directed case addressed. A table whose entries include orders of the graph with the largest number of vertices that are known so far along with their respective connectivities is exposed.The last part of the thesis is devoted to the study of connected graphs modeling networks in an optimal way with respect to the following property of fault tolerance: When some nodes or links fail, it is required that all the components that are determined by the network have a minimum number of nodes connected to each other.This kind of conditional connectivity is called extraconectivity, and corresponds to the property of having at least a certain number of vertices. From this point of view, both as the standard connectivity and superconectivity constitute measures of conditional connectivity. The work carried out substantially improves the early sufficient conditions on the diameter given by Fiol and Fàbrega who had already conjetured that the upper bound on the diameter, which they had been found could be improved

The (a,b,s,t)-diameter of graphs: a particular case of conditional diameter

The conditional diameter of a connected graph $\Gamma=(V,E)$ is defined as follows: given a property ${\cal P}$ of a pair $(\Gamma_1, \Gamma_2)$ of subgraphs of $\Gamma$, the so-called \emph{conditional diameter} or ${\cal P}$-{\em diameter} measures the maximum distance among subgraphs satisfying ${\cal P}$. That is, $$D_{{\cal P}}(\Gamma):=\max_{\Gamma_1, \Gamma_2\subset \Gamma} \{\partial(\Gamma_1, \Gamma_2): \Gamma_1, \Gamma_2 \quad {\rm satisfy }\quad {\cal P}\}.$$ In this paper we consider the conditional diameter in which ${\cal P}$ requires that $\delta(u)\ge \alpha$ for all $u\in V(\Gamma_1)$, $\delta(v)\ge \beta$ for all $v\in V(\Gamma_2)$, $| V(\Gamma_1)| \ge s$ and $| V(\Gamma_2)| \ge t$ for some integers $1\le s,t\le |V|$ and $\delta \le \alpha, \beta \le \Delta$, where $\delta(x)$ denotes the degree of a vertex $x$ of $\Gamma$, $\delta$ denotes the minimum degree and $\Delta$ the maximum degree of $\Gamma$. The conditional diameter obtained is called $(\alpha ,\beta, s,t)$-\emph{diameter}. We obtain upper bounds on the $(\alpha ,\beta, s,t)$-diameter by using the $k$-alternating polynomials on the mesh of eigenvalues of an associated weighted graph. The method provides also bounds for other parameters such as vertex separators

On the structure of graphs without short cycles

The objective of this thesis is to study cages, constructions and properties of such families of graphs. For this, the study of graphs without short cycles plays a fundamental role in order to develop some knowledge on their structure, so we can later deal with the problems on cages. Cages were introduced by Tutte in 1947. In 1963, Erdös and Sachs proved that (k, g) -cages exist for any given values of k and g. Since then, large amount of research in cages has been devoted to their construction. In this work we study structural properties such as the connectivity, diameter, and degree regularity of graphs without short cycles. In some sense, connectivity is a measure of the reliability of a network. Two graphs with the same edge-connectivity, may be considered to have different reliabilities, as a more refined index than the edge-connectivity, edge-superconnectivity is proposed together with some other parameters called restricted connectivities. By relaxing the conditions that are imposed for the graphs to be cages, we can achieve more refined connectivity properties on these families and also we have an approach to structural properties of the family of graphs with more restrictions (i.e., the cages). Our aim, by studying such structural properties of cages is to get a deeper insight into their structure so we can attack the problem of their construction. By way of example, we studied a condition on the diameter in relation to the girth pair of a graph, and as a corollary we obtained a result guaranteeing restricted connectivity of a special family of graphs arising from geometry, such as polarity graphs. Also, we obtained a result proving the edge superconnectivity of semiregular cages. Based on these studies it was possible to develop the study of cages. Therefore obtaining a relevant result with respect to the connectivity of cages, that is, cages are k/2-connected. And also arising from the previous work on girth pairs we obtained constructions for girth pair cages that proves a bound conjectured by Harary and Kovács, relating the order of girth pair cages with the one for cages. Concerning the degree and the diameter, there is the concept of a Moore graph, it was introduced by Hoffman and Singleton after Edward F. Moore, who posed the question of describing and classifying these graphs. As well as having the maximum possible number of vertices for a given combination of degree and diameter, Moore graphs have the minimum possible number of vertices for a regular graph with given degree and girth. That is, any Moore graph is a cage. The formula for the number of vertices in a Moore graph can be generalized to allow a definition of Moore graphs with even girth (bipartite Moore graphs) as well as odd girth, and again these graphs are cages. Thus, Moore graphs give a lower bound for the order of cages, but they are known to exist only for very specific values of k, therefore it is interesting to study how far a cage is from this bound, this value is called the excess of a cage. We studied the excess of graphs and give a contribution, in the sense of the work of Biggs and Ito, relating the bipartition of girth 6 cages with their orders. Entire families of cages can be obtained from finite geometries, for example, the graphs of incidence of projective planes of order q a prime power, are (q+1, 6)-cages. Also by using other incidence structures such as the generalized quadrangles or generalized hexagons, it can be obtained families of cages of girths 8 and 12. In this thesis, we present a construction of an entire family of girth 7 cages that arises from some combinatorial properties of the incidence graphs of generalized quadrangles of order (q,q)

On the connectivity and restricted edge-connectivity of 3-arc graphs

A 3−arc of a graph G is a 4-tuple (y, a, b, x) of vertices such that both (y, a, b) and (a, b, x) are paths of length two in G. Let ←→G denote the symmetric digraph of a graph G. The 3-arc graph X(G) of a given graph G is defined to have vertices the arcs of ←→G. Two vertices (ay), (bx) are adjacent in X(G) if and only if (y, a, b, x) is a 3-arc of G. The purpose of this work is to study the edge-connectivity and restricted edge-connectivity of 3-arc graphs.We prove that the 3-arc graph X(G) of every connected graph G of minimum degree δ(G) ≥ 3 has edge-connectivity λ(X(G)) ≥ (δ(G) − 1)2; and restricted edge- connectivity λ(2)(X(G)) ≥ 2(δ(G) − 1)2 − 2 if κ(G) ≥ 2. We also provide examples showing that all these bounds are sharp.Peer Reviewe

Proceedings of the 3rd International Workshop on Optimal Networks Topologies IWONT 2010

Peer Reviewe

On the connectivity of p-diamond-free vertex transitive graphs

AbstractLet G be a graph of order n(G), minimum degree δ(G) and connectivity κ(G). We call the graph G maximally connected when κ(G)=δ(G). The graph G is said to be superconnected if every minimum vertex cut isolates a vertex.For an integer p≥1, we define a p-diamond as the graph with p+2 vertices, where two adjacent vertices have exactly p common neighbors, and the graph contains no further edges. Usually, the 1-diamond is triangle and the 2-diamond is diamond. We call a graph p-diamond-free if it contains no p-diamond as a (not necessarily induced) subgraph. A graph is vertex transitive if its automorphism group acts transitively on its vertex set.In this paper, we give some sufficient conditions for vertex transitive graphs to be maximally connected. In addition, superconnected p-diamond-free (1≤p≤3) vertex transitive graphs are characterized