Structure from Voltage

02/28/2022

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Effective resistance (ER) is an attractive way to interrogate the structure of graphs. It is an alternative to computing the eigen-vectors of the graph Laplacian. Graph laplacians are used to find low dimensional structures in high dimensional data. Here too, ER based analysis has advantages over eign-vector based methods. Unfortunately Von Luxburg et al. (2010) show that, when vertices correspond to a sample from a distribution over a metric space, the limit of the ER between distant points converges to a trivial quantity that holds no information about the structure of the graph. We show that by using scaling resistances in a graph with n vertices by n^2, one gets a meaningful limit of the voltages and of effective resistances. We also show that by adding a "ground" node to a metric graph one gets a simple and natural way to compute all of the distances from a chosen point to all other points.

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Structure from Voltage

Effective resistance in metric spaces

Scaling limits for random triangulations on the torus

Threshold for Detecting High Dimensional Geometry in Anisotropic Random Geometric Graphs

Dynamic Streaming Spectral Sparsification in Nearly Linear Time and Space

A Unifying Perspective on Neighbor Embeddings along the Attraction-Repulsion Spectrum

Multiscale Graph Comparison via the Embedded Laplacian Distance

Betweenness centrality in dense spatial networks

Structure from Voltage

Related Research

Effective resistance in metric spaces

Scaling limits for random triangulations on the torus

Threshold for Detecting High Dimensional Geometry in Anisotropic Random Geometric Graphs

Dynamic Streaming Spectral Sparsification in Nearly Linear Time and Space

A Unifying Perspective on Neighbor Embeddings along the Attraction-Repulsion Spectrum

Multiscale Graph Comparison via the Embedded Laplacian Distance

Betweenness centrality in dense spatial networks