Extremal orders of an arithmetic function explained

In mathematics, specifically in number theory, the extremal orders of an arithmetic function are best possible bounds of the given arithmetic function. Specifically, if f(n) is an arithmetic function and m(n) is a non-decreasing function that is ultimately positive and

\liminfn

f(n)
m(n)

=1

we say that m is a minimal order for f. Similarly if M(n) is a non-decreasing function that is ultimately positive and

\limsupn

f(n)
M(n)

=1

we say that M is a maximal order for f.[1] Here,

\liminfn

and

\limsupn

denote the limit inferior and limit superior, respectively.

The subject was first studied systematically by Ramanujan starting in 1915.

Examples

\limsupn

|M(x)|
\sqrt{x
} = +\infty, though to date this limit superior has only been shown to be larger than a small constant. This statement is compared with the disproof of Mertens conjecture given by Odlyzko and te Riele in their several decades old breakthrough paper Disproof of the Mertens Conjecture. In contrast, we note that while extensive computational evidence suggests that the above conjecture is true, i.e., along some increasing sequence of

\{xn\}n

tending to infinity the average order of

\sqrt{xn}|M(xn)|

grows unbounded, that the Riemann hypothesis is equivalent to the limit

\limxM(x)/

1+\varepsilon
2
x

=0

being true for all (sufficiently small)

\varepsilon>0

.

See also

Further reading

Notes and References

  1. Book: Tenenbaum, Gérald . Introduction to Analytic and Probabilistic Number Theory . Cambridge studies in advanced mathematics . 46 . Cambridge University Press . 1995 . 0-521-41261-7 .
  2. Book: Hardy . G. H. . G. H. Hardy . Wright . E. M. . E. M. Wright . An Introduction to the Theory of Numbers . Clarendon Press . Oxford . 1979 . 5th . 0-19-853171-0 . registration .
  3. Gronwall. T. H.. Some asymptotic expressions in the theory of numbers . Transactions of the American Mathematical Society . 14. 4 . 1913 . 113–122. 10.1090/s0002-9947-1913-1500940-6 . free.