Resistance distance
In graph theory, the resistance distance between two vertices of a simple connected graph, G, is equal to the resistance between two equivalent points on an electrical network, constructed so as to correspond to G, with each edge being replaced by a 1 ohm resistance. It is a metric on graphs.
Definition
On a graph G, the resistance distance Ωi,j between two vertices vi and vj is[1]
where , with denoting the Moore–Penrose inverse, the Laplacian matrix of G, is the number of vertices in G, and is the matrix containing all 1s.
Properties of resistance distance
If i = j then
For an undirected graph
General sum rule
For any N-vertex simple connected graph G = (V, E) and arbitrary N×N matrix M:
From this generalized sum rule a number of relationships can be derived depending on the choice of M. Two of note are;
where the are the non-zero eigenvalues of the Laplacian matrix. This unordered sum Σi<jΩi,j is called the Kirchhoff index of the graph.
Relationship to the number of spanning trees of a graph
For a simple connected graph G = (V, E), the resistance distance between two vertices may be expressed as a function of the set of spanning trees, T, of G as follows:
where is the set of spanning trees for the graph .
As a squared Euclidean distance
Since the Laplacian is symmetric and positive semi-definite, so is , thus its pseudo-inverse is also symmetric and positive semi-definite. Thus, there is a such that and we can write:
showing that the square root of the resistance distance corresponds to the Euclidean distance in the space spanned by .
See also
References
- https://mathworld.wolfram.com/ResistanceDistance.html
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