Representation functions with prescribed rates of growth
Abstract
Fix an integer h ≥ 2, and let b1, …, bh be (not necessarily distinct) positive integers with (b1, …, bh) = 1. For any subset A ⊂eq N, let rA(n) denote the number of solutions (k1, …, kh) ∈ Ah to the equation \[ b1 k1 + ·s + bh kh = n. \] Given a function F satisfying F(n) ≤ rN(n), we ask: when does there exist a set A ⊂eq N such that rA(n) F(n)? We prove that this is always possible when F is regularly varying and satisfies n∞ F(n)/ n = ∞. If one only requires rA(n) F(n), much weaker regularity conditions suffice: we show such a set A exists for every increasing function F satisfying F(2x) F(x) and x F(x) xh-1. Finally, we give a probabilistic heuristic supporting the following: if A ⊂eq N satisfies n∞ rA(n)/ n < 1, then rA(n) = 0 for infinitely many n.
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