A Nonlinear Spectral Method for Core--Periphery Detection in Networks
For network scientists, this provides a theoretically grounded, scalable method for core-periphery detection with improved performance.
The paper introduces a new iterative algorithm for detecting core-periphery structure in networks, proving global convergence and linear scalability on sparse networks. It demonstrates advantages over state-of-the-art methods on synthetic and real networks.
We derive and analyse a new iterative algorithm for detecting network core--periphery structure. Using techniques in nonlinear Perron-Frobenius theory, we prove global convergence to the unique solution of a relaxed version of a natural discrete optimization problem. On sparse networks, the cost of each iteration scales linearly with the number of nodes, making the algorithm feasible for large-scale problems. We give an alternative interpretation of the algorithm from the perspective of maximum likelihood reordering of a new logistic core--periphery random graph model. This viewpoint also gives a new basis for quantitatively judging a core--periphery detection algorithm. We illustrate the algorithm on a range of synthetic and real networks, and show that it offers advantages over the current state-of-the-art.