Assume that for every \eta > 0, there is a g(\eta) so that for l > g(\eta) and n > 0, l^-1 sum_{k = 0}^l-1 f(n+k) < \alpha+\eta; then to every \epsilon > 0, \delta > 0 , there is an h(\epsilon,\delta) so that for all but \epsilon x integers n < x, we have for every l > h(\epsilon,\delta) that

This generalizes (a strengthened form of) a result of R.Bellman and H.N.Shapiro (Zbl 057.28602).
Theorem 2. To every c₁, there is a c₂ (c₁), so that if a₁ < a₂ < ··· < a_k \leq n are integers, k > c₁n, A = a₁a₂...a_n, then sum_{d | A} d^-1 > c₂ log n. The proof uses Brun's method.
Also the following result (not stated as a formal theorem) is proved: Let a₁ < a₂ < ··· < a_k \leq x be k integers such that no two of them are relatively prime, but every three are. If, for given x, one sets max k = f(x), then f(x) = (¹/₂ +o(1))(log x)/(log log x).
Reviewer:  E.Grosswald
Classif.:  * 11N64 Characterization of arithmetic functions
Index Words:  number theory

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