Quantitative results of the Romanov type representation functions

Abstract

For α >0, let A=\ a1<a2<a3<·s\ and L=\ 1, 2, 3,·s\ (not~necessarily~different) be two sequences of positive integers with A(m)>( m)α for infinitely many positive integers m and m<0.9 m for sufficiently integers m. Suppose further that (i,ai)=1 for all i. For any n, let fA,L(n) be the number of the available representations listed below in=p+ai (1 i A(n)), where p is a prime number. It is proved that n ∞ fA,L(n) n>0, which covers an old result of Erd os in 1950 by taking ai=2i and i=1. One key ingredient in the argument is a technical lemma established here which illustrates how to pick out the admissible parts of an arbitrarily given set of distinct linear functions. The proof then reduces to the verifications of a hypothesis involving well--distributed sets introduced by Maynard, which of course would be the other key ingredient in the argument.