A novel approach to the giant component fluctuations

Abstract

We present a novel approach to study the evolution of the size (i.e. the number of vertices) of the giant component of a random graph process. It is based on the exploration algorithm called simultaneous breadth-first walk, introduced by Limic in 2019, that encodes the dynamic of the evolution of the sizes of the connected components of a large class of random graph processes. We limit our study to the variant of the Erdos-R\'enyi graph process (Gn(s))s≥ 0 with n vertices where an edge connecting a pair of vertices appears at an exponential rate 1 waiting time, independently over pairs. We first use the properties of the simultaneous breadth-first walk to obtain an alternative and self-contained proof of the functional central limit theorem recently established by Enriquez, Faraud and Lemaire in the super-critical regime (s=cn and c>1). Next, to show the versatility of our approach, we prove a functional central limit theorem in the barely super-critical regime (s=1+tεnn where t>0 and (εn)n is a sequence of positive reals that converges to 0 such that (nεn3)n tends to +∞).

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