Computations of the Mertens function and improved bounds on the Mertens conjecture
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Abstract:
The Mertens function is defined as $M(x) = \sum _{n \leq x} \mu (n)$, where $\mu (n)$ is the Möbius function. The Mertens conjecture states $|M(x)/\sqrt {x}| < 1$ for $x > 1$, which was proven false in 1985 by showing $\liminf M(x)/\sqrt {x} < -1.009$ and $\limsup M(x)/\sqrt {x} > 1.06$. The same techniques used were revisited here with present day hardware and algorithms, giving improved lower and upper bounds of $-1.837625$ and $1.826054$. In addition, $M(x)$ was computed for all $x \leq 10^{16}$, recording all extrema, all zeros, and $10^8$ values sampled at a regular interval. Finally, an algorithm to compute $M(x)$ in $O(x^{2/3+\varepsilon })$ time was used on all powers of two up to $2^{73}$.References
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Additional Information
- Greg Hurst
- Affiliation: Wolfram Research Inc., 100 Trade Center Drive, Champaign, Illinois 61820
- Email: ghurst@wolfram.com
- Received by editor(s): October 28, 2016
- Received by editor(s) in revised form: March 4, 2017
- Published electronically: November 1, 2017
- © Copyright 2017 American Mathematical Society
- Journal: Math. Comp. 87 (2018), 1013-1028
- MSC (2010): Primary 11A25, 11M26, 11Y35, 11Y55, 11Y70
- DOI: https://doi.org/10.1090/mcom/3275
- MathSciNet review: 3739227