Existence and Size of the Giant Component in Inhomogeneous Random K-out Graphs

Abstract

Random K-out graphs are receiving attention as a model to construct sparse yet well-connected topologies in distributed systems including sensor networks, federated learning, and cryptocurrency networks. In response to the growing heterogeneity in emerging real-world networks, where nodes differ in resources and requirements, inhomogeneous random K-out graphs, denoted by H(n;μ,Kn), were proposed recently. Motivated by practical settings where establishing links is costly and only a bounded choice of Kn is feasible (Kn = O(1)), we study the size of the largest connected sub-network of H(n;μ,Kn), We first show that the trivial condition of Kn ≥ 2 for all n is sufficient to ensure that H(n;μ,Kn), contains a giant component of size n-O(1) whp. Next, to model settings where nodes can fail or get compromised, we investigate the size of the largest connected sub-network in H(n;μ,Kn), when dn nodes are selected uniformly at random and removed from the network. We show that if dn=O(1), a giant component of size n- (1) persists for all Kn ≥ 2 whp. Further, when dn=o(n) nodes are removed from H(n;μ,Kn), the remaining nodes contain a giant component of size n(1-o(1)) whp for all Kn ≥ 2. We present numerical results to demonstrate the size of the largest connected component when the number of nodes is finite.