Proof Lengths for Instances of the Paris-Harrington Principle

Abstract

As Paris and Harrington have famously shown, Peano Arithmetic does not prove that for all numbers k,m,n there is an N which satisfies the statement PH(k,m,n,N): For any k-colouring of its n-element subsets the set \0,…,N-1\ has a large homogeneous subset of size ≥ m. At the same time very weak theories can establish the 1-statement ∃NPH( k, m, n,N) for any fixed parameters k,m,n. Which theory, then, does it take to formalize natural proofs of these instances? It is known that ∀m∃NPH( k,m, n,N) has a natural and short proof (relative to n and k) by n-1-induction. In contrast, we show that there is an elementary function e such that any proof of ∃NPH(e(n),n+1, n,N) by n-2-induction is ridiculously long. In order to establish this result on proof lengths we give a computational analysis of slow provability, a notion introduced by Sy-David Friedman, Rathjen and Weiermann. We will see that slow uniform 1-reflection is related to a function that has a considerably lower growth rate than F_0 but dominates all functions Fα with α<0 in the fast-growing hierarchy.