On the Diffusion Geometry of Graph Laplacians and Applications

Abstract

We study directed, weighted graphs G=(V,E) and consider the (not necessarily symmetric) averaging operator (Lu)(i) = -Σj ipij (u(j) - u(i)), where pij are normalized edge weights. Given a vertex i ∈ V, we define the diffusion distance to a set B ⊂ V as the smallest number of steps dB(i) ∈ N required for half of all random walks started in i and moving randomly with respect to the weights pij to visit B within dB(i) steps. Our main result is that the eigenfunctions interact nicely with this notion of distance. In particular, if u satisfies Lu = λ u on V and B = \ i ∈ V: - ≤ u(i) ≤ \ ≠ , then, for all i ∈ V, dB(i) ( 1|1-λ| ) ≥ ( |u(i)| \|u\|L∞ ) - (12 + ). dB(i) is a remarkably good approximation of |u| in the sense of having very high correlation. The result implies that the classical one-dimensional spectral embedding preserves particular aspects of geometry in the presence of clustered data. We also give a continuous variant of the result which has a connection to the hot spots conjecture.