Arithmetic derivative

In number theory, the Lagarias arithmetic derivative, or number derivative, is a function defined for integers, based on prime factorization, by analogy with the product rule for the derivative of a function that is used in mathematical analysis.

There are many versions of "arithmetic derivatives", including the one discussed in this article (the Lagarias arithmetic derivative), such as Ihara's arithmetic derivative and Buium's arithmetic derivatives.

Early history[]

The arithmetic derivative was introduced by Spanish mathematician Josè Mingot Shelly in 1911.^[1][2] The arithmetic derivative also appeared in the 1950 Putnam Competition.^[3]

Definition[]

For natural numbers n the arithmetic derivative D(n)^{[note 1]} is defined as follows:

• D(0) = D(1) = 0.
• D(p) = 1 for any prime p.
• D(pq) = D(p)q + pD(q) for any ${\displaystyle p,q\in \mathbb {N} }$ (Leibniz rule).

Extensions beyond natural numbers[]

Edward J. Barbeau extended the domain to all integers by proving that the choice D(−x) = −D(x), which uniquely extends the domain to the integers, is consistent with the product formula. Barbeau also further extended it to the rational numbers, showing that the familiar quotient rule gives a well-defined derivative on ${\displaystyle \mathbb {Q} }$:

${\displaystyle D\left({\frac {p}{q}}\right)={\frac {D(p)q-pD(q)}{q^{2}}}.}$^[4][5]

and expanded it to the irrationals that can be written as the product of primes raised to arbitrary rational numbers, allowing expressions like ${\displaystyle D({\sqrt {3}})}$ to be computed. ^[6]

The arithmetic derivative can also be extended to any unique factorization domain,^[6] such as the Gaussian integers and the Eisenstein integers, and its associated field of fractions. If the UFD is a polynomial ring, then the arithmetic derivative is the same as the derivation over said polynomial ring. For example, the regular derivative is the arithmetic derivative for the rings of univariate real and complex polynomial and rational functions, which can be proven using the fundamental theorem of algebra.

The arithmetic derivative has also been extended to the ring of integers modulo n.^[7]

Elementary properties[]

The Leibniz rule implies that D(0) = 0 (take p = q = 0) and D(1) = 0 (take p = q = 1).

The power rule is also valid for the arithmetic derivative. For any integers p and n ≥ 0:

${\displaystyle D(p^{n})=np^{n-1}D(p).}$

This allows one to compute the derivative from the prime factorization of an integer, ${\textstyle x=\prod _{i=1}^{\omega (x)}{p_{i}}^{v_{p_{i}}(x)}}$:

${\displaystyle D(x)=\sum _{i=1}^{\omega (x)}\left[v_{p_{i}}(x)\left(\prod _{j=1}^{i-1}{p_{j}}^{v_{p_{j}}(x)}\right)p_{i}^{v_{p_{i}}-1}\left(\prod _{j=i+1}^{\omega (x)}{p_{j}}^{v_{p_{j}}(x)}\right)\right]=\sum _{i=1}^{\omega (x)}{\frac {v_{p_{i}}(x)}{p_{i}}}x=\sum _{\stackrel {p\mid x}{p{\text{ prime}}}}{\frac {v_{p}(x)}{p}}x}$

where ω(x), a prime omega function, is the number of distinct prime factors in x, and v_p(x) is the p-adic valuation of x.

For example:

${\displaystyle D(60)=D\left(2^{2}\cdot 3\cdot 5\right)=\left({\frac {2}{2}}+{\frac {1}{3}}+{\frac {1}{5}}\right)\cdot 60=92,}$

or

${\displaystyle D(81)=D\left(3^{4}\right)=4\cdot 3^{3}\cdot D(3)=4\cdot 27\cdot 1=108.}$

The sequence of number derivatives for k = 0, 1, 2, … begins (sequence A003415 in the OEIS):

${\displaystyle 0,0,1,1,4,1,5,1,12,6,7,1,16,1,9,\ldots }$

Related functions[]

The logarithmic derivative ${\displaystyle \operatorname {ld} (x)={\frac {D(x)}{x}}=\sum _{\stackrel {p\mid x}{p{\text{ prime}}}}{\frac {v_{p}(x)}{p}}}$ is a totally additive function: ${\displaystyle \operatorname {ld} (x\cdot y)=\operatorname {ld} (x)+\operatorname {ld} (y).}$

Inequalities and bounds[]

E. J. Barbeau examined bounds of the arithmetic derivative^[8] and found that

${\displaystyle D(n)\leq {\frac {n\log _{2}n}{2}}}$

and

${\displaystyle D(n)\geq \Omega (n)n^{\frac {\Omega (n)-1}{\Omega (n)}}}$

where Ω(n), a prime omega function, is the number of prime factors in n. In both bounds above, equality always occurs when n is a perfect power of 2, that is n = 2^m for some m.

Dahl, Olsson and Loiko found the arithmetic derivative of natural numbers is bounded by^[9]

${\displaystyle D(n)\leq {\frac {n\log _{p}n}{p}}}$

where p is the least prime in n and equality holds when n is a power of p.

, and found that it is impossible to find similar bounds for the arithmetic derivative extended to rational numbers by proving that between any two rational numbers there are other rationals with arbitrary large or small derivatives.

Order of the average[]

We have

${\displaystyle \sum _{n\leq x}{\frac {D(n)}{n}}=T_{0}x+O(\log x\log \log x)}$

and

${\displaystyle \sum _{n\leq x}D(n)=\left({\frac {1}{2}}\right)T_{0}x^{2}+O(x^{1+\delta })}$

for any δ > 0, where

${\displaystyle T_{0}=\sum _{p}{\frac {1}{p(p-1)}}.}$

Relevance to number theory[]

and have detailed the function's connection to famous number-theoretic conjectures like the twin prime conjecture, the prime triples conjecture, and Goldbach's conjecture. For example, Goldbach's conjecture would imply, for each k > 1 the existence of an n so that D(n) = 2k. The twin prime conjecture would imply that there are infinitely many k for which D²(k) = 1.^[6]

See also[]

• Arithmetic function
• Derivation (differential algebra)
• p-derivation

Notes[]

References[]

• Barbeau, E. J. (1961). "Remarks on an arithmetic derivative". Canadian Mathematical Bulletin. 4: 117–122. doi:10.4153/CMB-1961-013-0. Zbl 0101.03702.
• Ufnarovski, Victor; Åhlander, Bo (2003). "How to Differentiate a Number". Journal of Integer Sequences. 6. Article 03.3.4. ISSN 1530-7638. Zbl 1142.11305.
• Arithmetic Derivative, Planet Math, accessed 04:15, 9 April 2008 (UTC)
• L. Westrick (2003). Investigations of the Number Derivative.
• Peterson, I. Math Trek: Deriving the Structure of Numbers.
• Stay, Michael (2005). "Generalized Number Derivatives". Journal of Integer Sequences. 8. Article 05.1.4. arXiv:math/0508364. ISSN 1530-7638. Zbl 1065.05019.
• Dahl N., Olsson J., Loiko A., Investigation of the properties of the arithmetic derivative.
• Balzarotti, Giorgio; Lava, Paolo Pietro (2013). La derivata aritmetica. Alla scoperta di un nuovo approccio alla teoria dei numeri. Milan: Hoepli. ISBN 978-88-203-5864-8.
• Koviˇc, Jurij (2012). "The Arithmetic Derivative and Antiderivative" (PDF). Journal of Integer Sequences. 15 (3.8).
• Haukkanen, Pentti; Merikoski, Jorma K.; Mattila, Mika; Tossavainen, Timo (2017). "The arithmetic Jacobian matrix and determinant" (PDF). Journal of Integer Sequences. 20. Article 17.9.2. ISSN 1530-7638.
• Haukkanen, Pentti; Merikoski, Jorma K.; Tossavainen, Timo (2018). "The arithmetic derivative and Leibniz-additive functions". Notes on Number Theory and Discrete Mathematics. 24.
• Haukkanen, Pentti (2019). "Generalized arithmetic subderivative". Notes on Number Theory and Discrete Mathematics. 25.
• Haukkanen, Pentti; Merikoski, Jorma K.; Tossavainen, Timo (2020). "Arithmetic Subderivatives: p-adic Discontinuity and Continuity". Journal of Integer Sequences. 23. Article 20.7.3. ISSN 1530-7638.
• Haukkanen, Pentti; Merikoski, Jorma K.; Tossavainen, Timo (2020). "Asymptotics of partial sums of the Dirichlet series of the arithmetic derivative". Mathematical Communications. 25.