Superior highly composite number

Divisor function $d (n)$ up to $n = 250$

In number theory, a superior highly composite number is a natural number which, in a particular rigorous sense, has many divisors. Particularly, it is defined by a ratio between the number of divisors an integer has and that integer raised to some positive power.

For any possible exponent, whichever integer has the greatest ratio is a superior highly composite number. It is a stronger restriction than that of a highly composite number, which is defined as having more divisors than any smaller positive integer.

The first ten superior highly composite numbers and their factorization are listed.

# prime factors	SHCN $n$	Prime factorization	Prime exponents	# divisors $d (n)$		Primorial factorization
1	2	$2$	1	2	2	$2$
2	6	$2 \cdot 3$	1,1	2²	4	$6$
3	12	$22 \cdot 3$	2,1	3×2	6	$2 \cdot 6$
4	60	$22 \cdot 3 \cdot 5$	2,1,1	3×2²	12	$2 \cdot 30$
5	120	$23 \cdot 3 \cdot 5$	3,1,1	4×2²	16	$22 \cdot 30$
6	360	$23 \cdot 3 2 \cdot 5$	3,2,1	4×3×2	24	$2 \cdot 6 \cdot 30$
7	2520	$23 \cdot 3 2 \cdot 5 \cdot 7$	3,2,1,1	4×3×2²	48	$2 \cdot 6 \cdot 210$
8	5040	$24 \cdot 3 2 \cdot 5 \cdot 7$	4,2,1,1	5×3×2²	60	$22 \cdot 6 \cdot 210$
9	55440	$24 \cdot 3 2 \cdot 5 \cdot 7 \cdot 11$	4,2,1,1,1	5×3×2³	120	$22 \cdot 6 \cdot 2310$
10	720720	$24 \cdot 3 2 \cdot 5 \cdot 7 \cdot 11 \cdot 13$	4,2,1,1,1,1	5×3×2⁴	240	$22 \cdot 6 \cdot 30030$

For a superior highly composite number $n$ there exists a positive real number $ε > 0$ such that for all natural numbers $k > 1$ we have

{\frac {d(n)}{n^{\varepsilon }}}\geq {\frac {d(k)}{k^{\varepsilon }}}

where

d (n)

, the divisor function, denotes the number of divisors of

n

. The term was coined by Ramanujan (1915).^[1]

For example, the number with the most divisors per square root of the number itself is 12; this can be demonstrated using some highly composites near 12.

{\frac {2}{2^{.5}}}\approx 1.414,{\frac {3}{4^{.5}}}=1.5,{\frac {4}{6^{.5}}}\approx 1.633,{\frac {6}{12^{.5}}}\approx 1.732,{\frac {8}{24^{.5}}}\approx 1.633,{\frac {12}{60^{.5}}}\approx 1.549

120 is another superior highly composite number because it has the highest ratio of divisors to itself raised to the .4 power.

{\frac {9}{36^{.4}}}\approx 2.146,{\frac {10}{48^{.4}}}\approx 2.126,{\frac {12}{60^{.4}}}\approx 2.333,{\frac {16}{120^{.4}}}\approx 2.357,{\frac {18}{180^{.4}}}\approx 2.255,{\frac {20}{240^{.4}}}\approx 2.233,{\frac {24}{360^{.4}}}\approx 2.279

The first 15 superior highly composite numbers, 2, 6, 12, 60, 120, 360, 2520, 5040, 55440, 720720, 1441440, 4324320, 21621600, 367567200, 6983776800 (sequence A002201 in the OEIS) are also the first 15 colossally abundant numbers, which meet a similar condition based on the sum-of-divisors function rather than the number of divisors. Neither set, however, is a subset of the other.

YouTube Encyclopedic

1/5
Views:
87 250
37 937
41 259
1 178
375

Transcription

Properties

All superior highly composite numbers are highly composite. This is easy to prove: if there is some number k that has the same number of divisors as n but is less than n itself (i.e. $d(k)=d(n)$ , but $k<n$ ), then ${\frac {d(k)}{k^{\varepsilon }}}>{\frac {d(n)}{n^{\varepsilon }}}$ for all positive ε, so if a number "n" is not highly composite, it cannot be superior highly composite.

An effective construction of the set of all superior highly composite numbers is given by the following monotonic mapping from the positive real numbers.^[2] Let

e_{p}(x)=\left\lfloor {\frac {1}{{\sqrt[{x}]{p}}-1}}\right\rfloor

for any prime number p and positive real x. Then

s(x)=\prod _{p\in \mathbb {P} }p^{e_{p}(x)}

is a superior highly composite number.

Note that the product need not be computed indefinitely, because if $p>2^{x}$ then $e_{p}(x)=0$ , so the product to calculate $s(x)$ can be terminated once $p\geq 2^{x}$ .

Also note that in the definition of $e_{p}(x)$ , $1/x$ is analogous to $\varepsilon$ in the implicit definition of a superior highly composite number.

Moreover, for each superior highly composite number $s'$ exists a half-open interval $I\subset \mathbb {R} ^{+}$ such that $\forall x\in I:s(x)=s'$ .

This representation implies that there exist an infinite sequence of $\pi _{1},\pi _{2},\ldots \in \mathbb {P}$ such that for the n-th superior highly composite number $s_{n}$ holds

s_{n}=\prod _{i=1}^{n}\pi _{i}

The first $\pi _{i}$ are 2, 3, 2, 5, 2, 3, 7, ... (sequence A000705 in the OEIS). In other words, the quotient of two successive superior highly composite numbers is a prime number.

Radices

The first few superior highly composite numbers have often been used as radices, due to their high divisibility for their size. For example:

Binary (base 2)
Senary (base 6)
Duodecimal (base 12)
Sexagesimal (base 60)

Bigger SHCNs can be used in other ways. 120 appears as the long hundred, while 360 appears as the number of degrees in a circle.

Notes

^ Weisstein, Eric W. "Superior Highly Composite Number". mathworld.wolfram.com. Retrieved 2021-03-05.
^ Ramanujan (1915); see also URL http://wwwhomes.uni-bielefeld.de/achim/hcn.dvi

References

Ramanujan, S. (1915). "Highly composite numbers". Proc. London Math. Soc. Series 2. 14: 347–409. doi:10.1112/plms/s2_14.1.347. JFM 45.1248.01. Reprinted in Collected Papers (Ed. G. H. Hardy et al.), New York: Chelsea, pp. 78–129, 1962
Sándor, József; Mitrinović, Dragoslav S.; Crstici, Borislav, eds. (2006). Handbook of number theory I. Dordrecht: Springer-Verlag. pp. 45–46. ISBN 1-4020-4215-9. Zbl 1151.11300.

External links

Weisstein, Eric W. "Superior highly composite number". MathWorld.

v t e Divisibility-based sets of integers
Overview	Integer factorization Divisor Unitary divisor Divisor function Prime factor Fundamental theorem of arithmetic
Factorization forms	Prime Composite Semiprime Pronic Sphenic Square-free Powerful Perfect power Achilles Smooth Regular Rough Unusual
Constrained divisor sums	Perfect Almost perfect Quasiperfect Multiply perfect Hemiperfect Hyperperfect Superperfect Unitary perfect Semiperfect Practical Erdős–Nicolas
With many divisors	Abundant Primitive abundant Highly abundant Superabundant Colossally abundant Highly composite Superior highly composite Weird
Aliquot sequence-related	Untouchable Amicable (Triple) Sociable Betrothed
Base-dependent	Equidigital Extravagant Frugal Harshad Polydivisible Smith
Other sets	Arithmetic Deficient Friendly Solitary Sublime Harmonic divisor Descartes Refactorable Superperfect

Classes of natural numbers

Powers and related numbers
Achilles Power of 2 Power of 3 Power of 10 Square Cube Fourth power Fifth power Sixth power Seventh power Eighth power Perfect power Powerful Prime power

Of the form a × 2^b ± 1
Cullen Double Mersenne Fermat Mersenne Proth Thabit Woodall

Other polynomial numbers
Hilbert Idoneal Leyland Loeschian Lucky numbers of Euler

Recursively defined numbers
Fibonacci Jacobsthal Leonardo Lucas Narayana Padovan Pell Perrin

Possessing a specific set of other numbers
Amenable Congruent Knödel Riesel Sierpiński

Expressible via specific sums
Nonhypotenuse Polite Practical Primary pseudoperfect Ulam Wolstenholme

Figurate numbers

2-dimensional

centered	Centered triangular Centered square Centered pentagonal Centered hexagonal Centered heptagonal Centered octagonal Centered nonagonal Centered decagonal Star
non-centered	Triangular Square Square triangular Pentagonal Hexagonal Heptagonal Octagonal Nonagonal Decagonal Dodecagonal

3-dimensional

centered	Centered tetrahedral Centered cube Centered octahedral Centered dodecahedral Centered icosahedral
non-centered	Tetrahedral Cubic Octahedral Dodecahedral Icosahedral Stella octangula
pyramidal	Square pyramidal

4-dimensional

non-centered	Pentatope Squared triangular Tesseractic

Combinatorial numbers
Bell Cake Catalan Dedekind Delannoy Euler Eulerian Fuss–Catalan Lah Lazy caterer's sequence Lobb Motzkin Narayana Ordered Bell Schröder Schröder–Hipparchus Stirling first Stirling second Telephone number Wedderburn–Etherington

Primes
Wieferich Wall–Sun–Sun Wolstenholme prime Wilson

Pseudoprimes
Carmichael number Catalan pseudoprime Elliptic pseudoprime Euler pseudoprime Euler–Jacobi pseudoprime Fermat pseudoprime Frobenius pseudoprime Lucas pseudoprime Lucas–Carmichael number Perrin pseudoprime Somer–Lucas pseudoprime Strong pseudoprime

Arithmetic functions and dynamics

Divisor functions	Abundant Almost perfect Arithmetic Betrothed Colossally abundant Deficient Descartes Hemiperfect Highly abundant Highly composite Hyperperfect Multiply perfect Perfect Practical Primitive abundant Quasiperfect Refactorable Semiperfect Sublime Superabundant Superior highly composite Superperfect
Prime omega functions	Almost prime Semiprime
Euler's totient function	Highly cototient Highly totient Noncototient Nontotient Perfect totient Sparsely totient
Aliquot sequences	Amicable Perfect Sociable Untouchable
Primorial	Euclid Fortunate

Other prime factor or divisor related numbers
Blum Cyclic Erdős–Nicolas Erdős–Woods Friendly Giuga Harmonic divisor Jordan–Pólya Lucas–Carmichael Pronic Regular Rough Smooth Sphenic Størmer Super-Poulet Zeisel

Numeral system-dependent numbers

Arithmetic functions
and dynamics

Persistence
- Additive
- Multiplicative

Digit sum	Digit sum Digital root Self Sum-product
Digit product	Multiplicative digital root Sum-product
Coding-related	Meertens
Other	Dudeney Factorion Kaprekar Kaprekar's constant Keith Lychrel Narcissistic Perfect digit-to-digit invariant Perfect digital invariant Happy

P-adic numbers-related

Automorphic
- Trimorphic

Digit-composition related

Digit-permutation related

Divisor-related

Other

Friedman

Binary numbers
Evil Odious Pernicious

Generated via a sieve
Lucky Prime

Sorting related
Pancake number Sorting number

Natural language related
Aronson's sequence Ban

Graphemics related
Strobogrammatic

Mathematics portal

This page was last edited on 10 April 2024, at 16:05

From Wikipedia, the free encyclopedia