Phase transition in inhomogenous Erdos-R\'enyi random graphs via tree counting

Abstract

Consider the complete graph \(Kn\) on \(n\) vertices where each edge \(e\) is independently open with probability \(pn(e)\) or closed otherwise. Here \(C-αnn ≤ pn(e) ≤ C+αnn\) where \(C > 0\) is a constant not depending on~\(n\) or~\(e\) and \(0 ≤ αn 0\) as \(n → ∞.\) The resulting random graph~\(G\) is inhomogenous and we use a tree counting argument to establish phase transition in \(G.\) We also obtain that the critical value for phase transition is one in the following sense. For \(C < 1,\) all components of \(G\) are small (i.e. contain at most \(Mn\) vertices) with high probability, i.e., with probability converging to one as \(n → ∞.\) For \(C > 1,\) with high probability, there is at least one giant component (containing at least \(ε n\) vertices for some \(ε > 0\)) and every component is either small or giant. For \(C > 8,\) with positive probability, the giant component is unique and every other component is small. As a consequence of our method, we directly obtain the fraction of vertices present in the giant component in the form of an infinite series.