Hall–Janko graph

Hall–Janko graph
	HJ as Foster graph (90 outer vertices) plus Steiner system S(3,4,10) (10 inner vertices).
Named after	Zvonimir Janko ; Marshall Hall
Vertices	100
Edges	1800
Radius	2
Diameter	2
Girth	3
Automorphisms	1209600
Chromatic number	10
Properties	Strongly regular ; Vertex-transitive ; Cayley graph ; Eulerian ; Hamiltonian ; Integral
	Table of graphs and parameters

Last updated April 05, 2019

In the mathematical field of graph theory, the Hall–Janko graph, also known as the Hall-Janko-Wales graph, is a 36-regular undirected graph with 100 vertices and 1800 edges.^[1]

Mathematics Field of study concerning quantity, patterns and change

Mathematics includes the study of such topics as quantity, structure, space, and change.

Graph theory study of graphs, which are mathematical structures used to model pairwise relations between objects

In mathematics, graph theory is the study of graphs, which are mathematical structures used to model pairwise relations between objects. A graph in this context is made up of vertices which are connected by edges. A distinction is made between undirected graphs, where edges link two vertices symmetrically, and directed graphs, where edges, then called arrows, link two vertices asymmetrically; see Graph for more detailed definitions and for other variations in the types of graph that are commonly considered. Graphs are one of the prime objects of study in discrete mathematics.

In graph theory, a regular graph is a graph where each vertex has the same number of neighbors; i.e. every vertex has the same degree or valency. A regular directed graph must also satisfy the stronger condition that the indegree and outdegree of each vertex are equal to each other. A regular graph with vertices of degree $k$ is called a $k$ ‑regular graph or regular graph of degree $k$ . Also, from the handshaking lemma, a regular graph of odd degree will contain an even number of vertices.

It is a rank 3 strongly regular graph with parameters (100,36,14,12) and a maximum coclique of size 10. This parameter set is not unique, it is however uniquely determined by its parameters as a rank 3 graph. The Hall–Janko graph was originally constructed by D. Wales to establish the existence of the Hall-Janko group as an index 2 subgroup of its automorphism group.

In mathematical finite group theory, a rank 3 permutation group acts transitively on a set such that the stabilizer of a point has 3 orbits. The study of these groups was started by Higman. Several of the sporadic simple groups were discovered as rank 3 permutation groups.

Strongly regular graph class of graphs in which the number of shared neighbors of two vertices depends only on whether they are adjacent

In graph theory, a strongly regular graph is defined as follows. Let G = be a regular graph with v vertices and degree k. G is said to be strongly regular if there are also integers λ and μ such that:

In mathematics, specifically group theory, the index of a subgroup H in a group G is the "relative size" of H in G: equivalently, the number of "copies" (cosets) of H that fill up G. For example, if H has index 2 in G, then intuitively half of the elements of G lie in H. The index of H in G is usually denoted |G : H| or [G : H] or (G:H).

The Hall–Janko graph can be constructed out of objects in U₃(3), the simple group of order 6048:^[2]^[3]

In U₃(3) there are 36 simple maximal subgroups of order 168. These are the vertices of a subgraph, the U₃(3) graph. A 168-subgroup has 14 maximal subgroups of order 24, isomorphic to S₄. Two 168-subgroups are called adjacent when they intersect in a 24-subgroup. The U₃(3) graph is strongly regular, with parameters (36,14,4,6)
There are 63 involutions (elements of order 2). A 168-subgroup contains 21 involutions, which are defined to be neighbors.
Outside U₃(3) let there be a 100th vertex C, whose neighbors are the 36 168-subgroups. A 168-subgroup then has 14 common neighbors with C and in all 1+14+21 neighbors.
An involution is found in 12 of the 168-subgroups. C and an involution are non-adjacent, with 12 common neighbors.
Two involutions are defined as adjacent when they generate a dihedral subgroup of order 8.^[4] An involution has 24 involutions as neighbors.

The characteristic polynomial of the Hall–Janko graph is $(x-36)(x-6)^{36}(x+4)^{63}$ . Therefore the Hall–Janko graph is an integral graph: its spectrum consists entirely of integers.

In the mathematical field of graph theory, an integral graph is a graph whose adjacency matrix's spectrum consists entirely of integers. In other words, a graph is an integral graph if all of the roots of the characteristic polynomial of its adjacency matrix are integers.

In mathematics, spectral graph theory is the study of the properties of a graph in relationship to the characteristic polynomial, eigenvalues, and eigenvectors of matrices associated with the graph, such as its adjacency matrix or Laplacian matrix.

Related Research Articles

This is a glossary of graph theory terms. Graph theory is the study of graphs, systems of nodes or vertices connected in pairs by edges.

In the area of modern algebra known as group theory, the Conway groups are the three sporadic simple groups Co₁, Co₂ and Co₃ along with the related finite group Co₀ introduced by (Conway 1968, 1969).

In the area of modern algebra known as group theory, the Higman–Sims group HS is a sporadic simple group of order

In mathematical graph theory, the Higman–Sims graph is a 22-regular undirected graph with 100 vertices and 1100 edges. It is the unique strongly regular graph srg(100,22,0,6), i.e. no neighboring pair of vertices share a common neighbor and each non-neighboring pair of vertices share six common neighbors. It was first constructed by Mesner (1956) and rediscovered in 1968 by Donald G. Higman and Charles C. Sims as a way to define the Higman–Sims group, and that group is a subgroup of index two in the group of automorphisms of the Higman–Sims graph.

In the area of modern algebra known as group theory, the Rudvalis groupRu is a sporadic simple group of order

In the mathematical field of graph theory, the Heawood graph is an undirected graph with 14 vertices and 21 edges, named after Percy John Heawood.

In the mathematical field of graph theory, the Hoffman–Singleton graph is a 7-regular undirected graph with 50 vertices and 175 edges. It is the unique strongly regular graph with parameters (50,7,0,1). It was constructed by Alan Hoffman and Robert Singleton while trying to classify all Moore graphs, and is the highest order Moore graph known to exist. Since it is a Moore graph where each vertex has degree 7, and the girth is 5, it is a (7,5)-cage.

In the area of modern algebra known as group theory, the Janko groupJ₂ or the Hall-Janko groupHJ is a sporadic simple group of order

In the mathematical field of graph theory, the Shrikhande graph is a named graph discovered by S. S. Shrikhande in 1959. It is a strongly regular graph with 16 vertices and 48 edges, with each vertex having degree 6. Every pair of nodes has exactly two other neighbors in common, whether the pair of nodes is connected or not.

In the area of modern algebra known as group theory, the McLaughlin group McL is a sporadic simple group of order

The Gewirtz graph is a strongly regular graph with 56 vertices and valency 10. It is named after the mathematician Allan Gewirtz, who described the graph in his dissertation.

In the mathematical field of graph theory, the Brouwer–Haemers graph is a 20-regular undirected graph with 81 vertices and 810 edges. It is a strongly regular graph, a distance-transitive graph, and a Ramanujan graph. Although its construction is folklore, it was named after Andries Brouwer and Willem H. Haemers, who proved its uniqueness as a strongly regular graph.

In the mathematical field of graph theory, the Schläfli graph, named after Ludwig Schläfli, is a 16-regular undirected graph with 27 vertices and 216 edges. It is a strongly regular graph with parameters srg(27, 16, 10, 8).

In the area of modern algebra known as group theory, the Conway groupCo₂ is a sporadic simple group of order

In mathematics, a near polygon is an incidence geometry introduced by Ernest E. Shult and Arthur Yanushka in 1980. Shult and Yanushka showed the connection between the so-called tetrahedrally closed line-systems in Euclidean spaces and a class of point-line geometries which they called near polygons. These structures generalise the notion of generalized polygon as every generalized 2n-gon is a near 2n-gon of a particular kind. Near polygons were extensively studied and connection between them and dual polar spaces was shown in 1980s and early 1990s. Some sporadic simple groups, for example the Hall-Janko group and the Mathieu groups, act as automorphism groups of near polygons.

In the mathematical field of graph theory, the McLaughlin graph is a strongly regular graph with parameters (275,112,30,56), and is the only such graph.

The M₂₂ graph, also called the Mesner graph, is the unique strongly regular graph with parameters (77, 16, 0, 4). It is constructed from the Steiner system (3, 6, 22) by representing its 77 blocks as vertices and joining two vertices iff they have no terms in common or by deleting a vertex and its neighbors from the Higman–Sims graph.

In graph theory, a locally linear graph is an undirected graph in which the neighborhood of every vertex is an induced matching. That is, for every vertex $, every neighbor of should be adjacent to exactly one other neighbor of . Equivalently, every edge of such a graph belongs to a unique triangle . Locally linear graphs have also been called locally matched graphs.$

In graph theory, Conway's 99-graph problem is an unsolved problem asking whether there exists an undirected graph with 99 vertices, in which each two adjacent vertices have exactly one common neighbor, and in which each two non-adjacent vertices have exactly two common neighbors. Equivalently, every edge should be part of a unique triangle and every non-adjacent pair should be one of the two diagonals of a unique 4-cycle. John Horton Conway has offered a $1000 prize for its solution.

References

↑ Weisstein, Eric W. "Hall-Janko graph". MathWorld .
↑ Andries E. Brouwer, "Hall-Janko graph".
↑ Andries E. Brouwer, "U₃(3) graph".
↑ Robert A. Wilson, 'The Finite Simple Groups', Springer-Verlag (2009), p. 224.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Weisstein, Eric W. "Hall-Janko graph". MathWorld .

[2] Andries E. Brouwer, "Hall-Janko graph".

[3] Andries E. Brouwer, "U₃(3) graph".

[4] Robert A. Wilson, 'The Finite Simple Groups', Springer-Verlag (2009), p. 224.

Hall–Janko graph
HJ as Foster graph (90 outer vertices) plus Steiner system S(3,4,10) (10 inner vertices).
Named after	Zvonimir Janko Marshall Hall
Vertices	100
Edges	1800
Radius	2
Diameter	2
Girth	3
Automorphisms	1209600
Chromatic number	10
Properties	Strongly regular Vertex-transitive Cayley graph Eulerian Hamiltonian Integral
Table of graphs and parameters