Walk-regular graph

In graph theory, a walk-regular graph is a simple graph where the number of closed walks of any length $\ell$ from a vertex to itself does only depend on $\ell$ but not depend on the choice of vertex. Walk-regular graphs can be thought of as a spectral graph theory analogue of vertex-transitive graphs. While a walk-regular graph is not neccessarily very symmetric, all its vertices still behave identically with respect to the graph's spectral properties.

Equivalent definitions

Suppose that $G$ is a simple graph. Let $A$ denote the adjacency matrix of $G$ , $V(G)$ denote the set of vertices of $G$ , and $\Phi _{G-v}(x)$ denote the characteristic polynomial of the vertex-deleted subgraph $G-v$ for all $v\in V(G).$ Then the following are equivalent:

$G$ is walk-regular.
$A^{k}$ is a constant-diagonal matrix for all $k\geq 0.$
$\Phi _{G-u}(x)=\Phi _{G-v}(x)$ for all $u,v\in V(G).$

Examples

The vertex-transitive graphs are walk-regular.
The semi-symmetric graphs are walk-regular.^[1]^{[unreliable source]}
The distance-regular graphs are walk-regular. More generally, any simple graph in a homogeneous coherent algebra is walk-regular.
A connected regular graph is walk-regular if:^{[dubious – discuss]}^{[citation needed]}
- It has at most four distinct eigenvalues.
- It is triangle-free and has at most five distinct eigenvalues.
- It is bipartite and has at most six distinct eigenvalues.

Properties

A walk-regular graph is necessarily a regular graph.
Complements of walk-regular graphs are walk-regular.
Cartesian products of walk-regular graphs are walk-regular.
Categorical products of walk-regular graphs are walk-regular.
Strong products of walk-regular graphs are walk-regular.
In general, the line graph of a walk-regular graph is not walk-regular.

k-walk-regular graphs

A graph is $k$ -walk-regular if for any two vertices $v$ and $w$ of distance at most $k,$ the number of walks of length $\ell$ from $v$ to $w$ depends only on $k$ and $\ell$ . ^[2]

For $k=0$ these are exactly the walk-regular graphs.

In analogy to walk-regular graphs generalizing vertex-transitive graphs, 1-walk-regular graphs can be thought of as generalizing symmetric graphs, that is, graphs that are both vertex- and edge-transitive. For example, the Hoffman graph is 1-walk-regular but not symmetric.

If $k$ is at least the diameter of the graph, then the $k$ -walk-regular graphs coincide with the distance-regular graphs. In fact, if $k\geq 2$ and the graph has an eigenvalue of multiplicity at most $k$ (except for eigenvalues $d$ and $-d$ , where $d$ is the degree of the graph), then the graph is already distance-regular.^[3]

References

^ "Are there only finitely many distinct cubic walk-regular graphs that are neither vertex-transitive nor distance-regular?". mathoverflow.net. Retrieved 2017-07-21.
^ Cristina Dalfó, Miguel Angel Fiol, and Ernest Garriga, "On $k$ -Walk-Regular Graphs," Electronic Journal of Combinatorics 16(1) (2009), article R47.
^ Marc Camara et al., "Geometric aspects of 2-walk-regular graphs," Linear Algebra and its Applications 439(9) (2013), 2692-2710.

External links

Chris Godsil and Brendan McKay, Feasibility conditions for the existence of walk-regular graphs.

[1] "Are there only finitely many distinct cubic walk-regular graphs that are neither vertex-transitive nor distance-regular?". mathoverflow.net. Retrieved 2017-07-21.

[2] Cristina Dalfó, Miguel Angel Fiol, and Ernest Garriga, "On $k$ -Walk-Regular Graphs," Electronic Journal of Combinatorics 16(1) (2009), article R47.

[3] Marc Camara et al., "Geometric aspects of 2-walk-regular graphs," Linear Algebra and its Applications 439(9) (2013), 2692-2710.

[1]

[2]

[3]