First order theory on G(n, c n-1)

Abstract

A well-known result of Shelah and Spencer tells us that the almost sure theory for first order language on the random graph sequence \G(n, cn-1)\ is not complete. This paper proposes and proves what the complete set of completions of the almost sure theory for \G(n, c n-1)\ should be. The almost sure theory T consists of two sentence groups: the first states that all the components are trees or unicyclic components, and the second states that, given any k ∈ N and any finite tree t, there are at least k components isomorphic to t. We define a k-completion of T to be a first order property A, such that if T + A holds for a graph, we can fully describe the first order sentences of quantifier depth ≤ k that hold for that graph. We show that a k-completion A specifies the numbers, up to "cutoff" k, of the (finitely many) unicyclic component types of given parameters (that only depend on k) that the graph contains. A complete set of k-completions is then the finite collection of all possible k-completions.