English

Fake Mu's

Number Theory 2021-12-13 v1

Abstract

Let f(n)f(n) denote a multiplicative function with range {1,0,1}\{-1,0,1\}, and let F(x)=nxf(n)F(x) = \sum_{n\leq x} f(n). Then F(x)/x=ax+b+E(x)F(x)/\sqrt{x} = a\sqrt{x} + b + E(x), where aa and bb are constants and E(x)E(x) is an error term that either tends to 00 in the limit, or is expected to oscillate about 00 in a roughly balanced manner. We say F(x)F(x) has persistent bias bb (at the scale of x\sqrt{x}) in the first case, and apparent bias bb in the latter. For example, if f(n)=μ(n)f(n)=\mu(n), the M\"{o}bius function, then F(x)=nxμ(n)F(x) = \sum_{n\leq x} \mu(n) has b=0b=0 so exhibits no persistent or apparent bias, while if f(n)=λ(n)f(n)=\lambda(n), the Liouville function, then F(x)=nxλ(n)F(x) = \sum_{n\leq x} \lambda(n) has apparent bias b=1/ζ(1/2)b=1/\zeta(1/2). We study the bias when f(pk)f(p^k) is independent of the prime pp, and call such functions fake μs\mu's. We investigate the conditions required for such a function to exhibit a persistent or apparent bias, determine the functions in this family with maximal and minimal bias of each type, and characterize the functions with no bias of either type. For such a function F(x)F(x) with apparent bias bb, we also show that F(x)/xaxbF(x)/\sqrt{x}-a\sqrt{x}-b changes sign infinitely often.

Keywords

Cite

@article{arxiv.2112.05227,
  title  = {Fake Mu's},
  author = {Greg Martin and Michael J. Mossinghoff and Timothy S. Trudgian},
  journal= {arXiv preprint arXiv:2112.05227},
  year   = {2021}
}
R2 v1 2026-06-24T08:11:33.177Z