Sequences of consecutive factoradic happy numbers

Abstract

Given a positive integer n, the factorial base representation of n is given by n=Σi=1kai· i!, where ak≠ 0 and 0≤ ai≤ i for all 1≤ i≤ k. For e≥ 1, we define Se,!:Z≥0≥0 by Se,!(0) = 0 and Se,!(n)=Σi=0naie, for n ≠ 0. For ≥ 0, we let Se,!(n) denote the -th iteration of Se,!, while Se,!0(n)=n. If p∈Z+ satisfies Se,!(p)=p, then we say that p is an e-power factoradic fixed point of Se,!. Moreover, given x∈ Z+, if p is an e-power factoradic fixed point and if there exists ∈ Z≥ 0 such that Se,!(x)=p, then we say that x is an e-power factoradic p-happy number. Note an integer n is said to be an e-power factoradic happy number if it is an e-power factoradic 1-happy number. In this paper, we prove that all positive integers are 1-power factoradic happy and, for 2≤ e≤ 4, we prove the existence of arbitrarily long sequences of e-power factoradic p-happy numbers. A curious result establishes that for any e≥ 2 the e-power factoradic fixed points of Se,! that are greater than 1, always appear in sets of consecutive pairs. Our last contribution, provides the smallest sequences of m consecutive e-power factoradic happy numbers for 2≤ e≤ 5, for some values of m.