A smooth summation of Ramanujan expansions

Abstract

We studied Ramanujan series Σq=1∞G(q)cq(a), where cq(a) is the well-known Ramanujan sum and the complex numbers G(q), as q∈N, are the Ramanujan coefficients; of course, we mean, implicitly, that the series converges pointwise, in all natural a, as its partial sums Σq QG(q)cq(a) converge in C, when Q ∞. Motivated by our recent study of infinite and finite Euler products for the Ramanujan series, in which we assumed G multiplicative, we look at a kind of (partial) smooth summations. These are Σq∈ (P)G(q)cq(a), where the indices q in (P) means that all prime factors p of q are up to P (fixed); then, we pass to the limit over P ∞. Notice that this kind of partial sums over P-smooth numbers (i.e., in (P), see the above) make up an infinite sum, themselves, ∀ P∈P fixed, in general; however, our summands contain cq(a), that has a vertical limit, i.e. it's supported over indices q∈N for which the p-adic valuations of, resp., q and a, namely vp(q), resp., vp(a) satisfy vp(q) vp(a)+1 and this is true ∀ p P (P's fixed). In other words, ∀ G:N → C, here, Σq∈ (P)G(q)cq(a) is a finite sum, ∀ a∈ N, ∀ P∈ P fixed: we will call Σq=1∞G(q)cq(a) a 'smooth Ramanujan series' if and only if ∃ P Σq∈ (P)G(q)cq(a)∈ C, ∀ a∈ N. Notice a very important property : smooth Ramanujan series and Ramanujan series need not to be the same. We prove : smooth Ramanujan series converge under Wintner Assumption. (This is not necessarily true for Ramanujan series.) We apply this to correlations and to the Hardy--Littlewood "2k-Twin Primes" Conjecture.