Algebraic connectivity
[Image:6n-graf.svg|thumb|250px|An example graph, with 6 vertices, diameter 3, connectivity 1, and algebraic connectivity 0.722]
The algebraic connectivity of a graph ' is the second-smallest eigenvalue of the Laplacian matrix of '. This eigenvalue is greater than 0 if and only if is a connected graph. This is a corollary to the fact that the number of times 0 appears as an eigenvalue in the Laplacian is the number of connected components in the graph. The magnitude of this value reflects how well connected the overall graph is. It has been used in analyzing the robustness and synchronizability of networks.
Properties
file:C60 Molecule.svg|thumb|The truncated icosahedron or Buckminsterfullerene graph has a traditional connectivity of 3, and an algebraic connectivity of 0.243.The algebraic connectivity of undirected graphs with nonnegative weights is, with the inequality being strict if and only if is connected. However, the algebraic connectivity can be negative for general directed graphs, even if ' is a connected graph. Furthermore, the value of the algebraic connectivity is bounded above by the traditional connectivity of a graph,, unless the graph is complete. For an undirected connected graph with nonnegative edge weights, ' vertices, and diameter , the algebraic connectivity is also known to be bounded below by, and in fact by. For the example graph with 6 nodes show above, these bounds would be calculated as:Unlike the traditional form of graph connectivity, defined by local configurations whose removal would disconnect the graph, the algebraic connectivity is dependent on the global number of vertices, as well as the way in which vertices are connected. In random graphs, the algebraic connectivity decreases with the number of vertices, and increases with the average degree.
The exact definition of the algebraic connectivity depends on the type of Laplacian used. Fan Chung has developed an extensive theory using a rescaled version of the Laplacian, eliminating the dependence on the number of vertices, so that the bounds are somewhat different.
In models of synchronization on networks, such as the Kuramoto model, the Laplacian matrix arises naturally, so the algebraic connectivity gives an indication of how easily the network will synchronize. Other measures, such as the average distance can also be used, and in fact the algebraic connectivity is closely related to the average distance.
The algebraic connectivity also relates to other connectivity attributes, such as the isoperimetric number, which is bounded below by half the algebraic connectivity.