Abstract
The spectrum of the non-backtracking matrix plays a crucial role in determining various structural and dynamical properties of networked systems, ranging from the threshold in bond percolation and non-recurrent epidemic processes, to community structure, to node importance. Here we calculate the largest eigenvalue of the non-backtracking matrix and the associated non-backtracking centrality for uncorrelated random networks, finding expressions in excellent agreement with numerical results. We show however that the same formulas do not work well for many real-world networks. We identify the mechanism responsible for this violation in the localization of the non-backtracking centrality on network subgraphs whose formation is highly unlikely in uncorrelated networks, but rather common in real-world structures. Exploiting this knowledge we present an heuristic generalized formula for the largest eigenvalue, which is remarkably accurate for all networks of a large empirical dataset. We show that this newly uncovered localization phenomenon allows to understand the failure of the message-passing prediction for the percolation threshold in many real-world structures.
Highlights
The spectrum of the non-backtracking matrix plays a crucial role in determining various structural and dynamical properties of networked systems, ranging from the threshold in bond percolation and non-recurrent epidemic processes, to community structure, to node importance
The non-backtracking centrality (NBC) can be practically calculated by using the Ihara–Bass determinant formula[2,17], which shows that the NBC values xi correspond to the first N elements of the principal eigenvector (PEV) of the 2N × 2N matrix
Our results show that the non-backtracking centrality, which was introduced to avoid the pathological selfreinforcement mechanism that plagues standard eigenvector centrality, is affected by the same problem
Summary
The spectrum of the non-backtracking matrix plays a crucial role in determining various structural and dynamical properties of networked systems, ranging from the threshold in bond percolation and non-recurrent epidemic processes, to community structure, to node importance. It is possible that other types of subgraphs play for the NB centrality the same role that star graphs play for eigenvector centrality: They can have, alone, large values of μM , so that, if present within an otherwise random network, they determine μM of the whole structure, with the overall NBC localized on them.
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