Mertens Sums requiring Fewer Values of the Möbius function (1807.05890v1)
Abstract: We discuss certain identities involving $\mu(n)$ and $M(x)=\sum_{n\leq x}\mu(n)$, the functions of M\"{o}bius and Mertens. These identities allow calculation of $M(Nd)$, for $d=2,3,4,\ldots\ $, as a sum of $O_d \left( Nd(\log N){2d - 2}\right)$ terms, each a product of the form $\mu(n_1) \cdots \mu(n_r)$ with $r\leq d$ and $n_1,\ldots , n_r\leq N$. We prove a more general identity in which $M(Nd)$ is replaced by $M(g,K)=\sum_{n\leq K}\mu(n)g(n)$, where $g(n)$ is an arbitrary totally multiplicative function, while each $n_j$ has its own range of summation, $1,\ldots , N_j$. We focus on the case $d=2$, $K=N2$, $N_1=N_2=N$, where the identity has the form $M(g,N2) = 2 M(g,N) - {\bf m}{\rm T} A {\bf m}$, with $A$ being the $N\times N$ matrix of elements $a_{mn}=\sum {k \leq N2 /(mn)}\,g(k)$, while ${\bf m}=(\mu (1)g(1),\ldots ,\mu (N)g(N)){\rm T}$. Our results in Sections 2 and 3 assume, moreover, that $g(n)$ equals $1$ for all $n$. In this case the Perron-Frobenius theorem applies: we find that $A$ has an eigenvalue that is approximately $(\pi2 /6)N2$, with eigenvector approximately ${\bf f} = (1,1/2,1/3,\ldots ,1/N){\rm T}$, and that, for large $N$, the second-largest eigenvalue lies in $(-0.58 N, -0.49 N)$. Estimates for the traces of $A$ and $A2$ are obtained. We discuss ways to approximate ${\bf m}{\rm T} A {\bf m}$, using the spectral decomposition of $A$, or Perron's formula: the latter approach leads to a contour integral involving the Riemann zeta-function. We also discuss using the identity $A = N{2\,} {\bf f}{\,} !{\bf f}T - \textstyle{1\over 2} {\bf u} {\bf u}T + Z$, where ${\bf u} = (1,\ldots ,1){\rm T}$ and $Z$ is the $N\times N$ matrix of elements $z{mn} = - \psi(N2 / (mn))$, with $\psi(x)=x - \lfloor x\rfloor - \textstyle{1\over 2}$.