Carmichael number

In number theory, a Carmichael number is a composite number $n$ which satisfies the modular arithmetic congruence relation:

b^{n-1}\equiv 1\pmod{n}

for all integers $1<b<n$ which are relatively prime to $n$ . They are named for Robert Carmichael. The Carmichael numbers are the subset K₁ of the Knödel numbers.

Overview

Fermat's little theorem states that if p is a prime number, then for any integer b, the number b^p − b is an integer multiple of p. Carmichael numbers are composite numbers which have the same property of modular arithmetic congruence. In fact, Carmichael numbers are also called Fermat pseudoprimes or absolute Fermat pseudoprimes. Carmichael numbers are important because they pass the Fermat primality test but are not actually prime. Since Carmichael numbers exist, this primality test cannot be relied upon to prove the primality of a number, although it can still be used to prove a number is composite. This makes tests based on Fermat's Little Theorem risky compared to other more stringent tests such as the Solovay-Strassen primality test or a strong pseudoprime test. Still, as numbers become larger, Carmichael numbers become very rare. For example, there are 20,138,200 Carmichael numbers between 1 and 10²¹ (approximately one in 50 trillion (5*10¹³) numbers).^[1]

Korselt's criterion

An alternative and equivalent definition of Carmichael numbers is given by Korselt's criterion.

Theorem (A. Korselt 1899): A positive composite integer

n

is a Carmichael number if and only if

n

is square-free, and for all prime divisors

p

n

, it is true that

p - 1 \mid n - 1

It follows from this theorem that all Carmichael numbers are odd, since any even composite number that is square-free (and hence has only one prime factor of two) will have at least one odd prime factor, and thus $p - 1 \mid n - 1$ results in an even dividing an odd, a contradiction. (The oddness of Carmichael numbers also follows from the fact that $-1$ is a Fermat witness for any even composite number.) From the criterion it also follows that Carmichael numbers are cyclic.^[2]^[3] Additionally, it follows that there are no Carmichael numbers with exactly two prime factors.

Discovery

Korselt was the first who observed the basic properties of Carmichael numbers, but he could not find any examples. In 1910, Carmichael^[4] found the first and smallest such number, 561, which explains the name "Carmichael number".

That 561 is a Carmichael number can be seen with Korselt's criterion. Indeed, $561 = 3 \cdot 11 \cdot 17$ is square-free and $2 \mid 560$ , $10 \mid 560$ and $16 \mid 560$ .

The next six Carmichael numbers are (sequence A002997 in OEIS):

1105 = 5 \cdot 13 \cdot 17 \qquad (4 \mid 1104;\quad 12 \mid 1104;\quad 16 \mid 1104)

1729 = 7 \cdot 13 \cdot 19 \qquad (6 \mid 1728;\quad 12 \mid 1728;\quad 18 \mid 1728)

2465 = 5 \cdot 17 \cdot 29 \qquad (4 \mid 2464;\quad 16 \mid 2464;\quad 28 \mid 2464)

2821 = 7 \cdot 13 \cdot 31 \qquad (6 \mid 2820;\quad 12 \mid 2820;\quad 30 \mid 2820)

6601 = 7 \cdot 23 \cdot 41 \qquad (6 \mid 6600;\quad 22 \mid 6600;\quad 40 \mid 6600)

8911 = 7 \cdot 19 \cdot 67 \qquad (6 \mid 8910;\quad 18 \mid 8910;\quad 66 \mid 8910).

These first seven Carmichael numbers, from 561 to 8911, were all found by the Czech mathematician Václav Šimerka in 1885^[5] (thus preceding not just Carmichael but also Korselt, although Šimerka did not find anything like Korselt's criterion). His work, however, remained unnoticed.

J. Chernick^[6] proved a theorem in 1939 which can be used to construct a subset of Carmichael numbers. The number $(6k + 1)(12k + 1)(18k + 1)$ is a Carmichael number if its three factors are all prime. Whether this formula produces an infinite quantity of Carmichael numbers is an open question (though it is implied by Dickson's conjecture).

Paul Erdős heuristically argued there should be infinitely many Carmichael numbers. In 1994 it was shown by W. R. (Red) Alford, Andrew Granville and Carl Pomerance that there really do exist infinitely many Carmichael numbers. Specifically, they showed that for sufficiently large $n$ , there are at least $n^{2/7}$ Carmichael numbers between 1 and $n$ .^[7]

Löh and Niebuhr in 1992 found some very large Carmichael numbers, including one with 1,101,518 factors and over 16 million digits.

Properties

Factorizations

Carmichael numbers have at least three positive prime factors. The first Carmichael numbers with $k = 3, 4, 5, \ldots$ prime factors are (sequence A006931 in OEIS):

k
3	$561 = 3 \cdot 11 \cdot 17\,$
4	$41041 = 7 \cdot 11 \cdot 13 \cdot 41\,$
5	$825265 = 5 \cdot 7 \cdot 17 \cdot 19 \cdot 73\,$
6	$321197185 = 5 \cdot 19 \cdot 23 \cdot 29 \cdot 37 \cdot 137\,$
7	$5394826801 = 7 \cdot 13 \cdot 17 \cdot 23 \cdot 31 \cdot 67 \cdot 73\,$
8	$232250619601 = 7 \cdot 11 \cdot 13 \cdot 17 \cdot 31 \cdot 37 \cdot 73 \cdot 163\,$
9	$9746347772161 = 7 \cdot 11 \cdot 13 \cdot 17 \cdot 19 \cdot 31 \cdot 37 \cdot 41 \cdot 641\,$

The first Carmichael numbers with 4 prime factors are (sequence A074379 in OEIS):

i
1	$41041 = 7 \cdot 11 \cdot 13 \cdot 41\,$
2	$62745 = 3 \cdot 5 \cdot 47 \cdot 89\,$
3	$63973 = 7 \cdot 13 \cdot 19 \cdot 37\,$
4	$75361 = 11 \cdot 13 \cdot 17 \cdot 31\,$
5	$101101 = 7 \cdot 11 \cdot 13 \cdot 101\,$
6	$126217 = 7 \cdot 13 \cdot 19 \cdot 73\,$
7	$172081 = 7 \cdot 13 \cdot 31 \cdot 61\,$
8	$188461 = 7 \cdot 13 \cdot 19 \cdot 109\,$
9	$278545 = 5 \cdot 17 \cdot 29 \cdot 113\,$
10	$340561 = 13 \cdot 17 \cdot 23 \cdot 67\,$

The second Carmichael number (1105) can be expressed as the sum of two squares in more ways than any smaller number. The third Carmichael number (1729) is the Hardy-Ramanujan Number: the smallest number that can be expressed as the sum of two cubes (of positive numbers) in two different ways.

Distribution

Let $C(X)$ denote the number of Carmichael numbers less than or equal to $X$ . The distribution of Carmichael numbers by powers of 10 (sequence A055553 in OEIS):^[1]

$n$	1	2	3	4	5	6	7	8	9	10	11	12	13	14	15	16
$C(10^n)$	0	0	1	7	16	43	105	255	646	1547	3605	8241	19279	44706	105212	246683

In 1953, Knödel proved the upper bound:

C(X) < X \exp\left({-k_1 \left( \log X \log \log X\right)^\frac{1}{2}}\right)

for some constant $k_1$ .

In 1956, Erdős improved the bound to^[8]

C(X) < X \exp\left(\frac{-k_2 \log X \log \log \log X}{\log \log X}\right)

for some constant $k_2$ . He further gave a heuristic argument suggesting that this upper bound should be close to the true growth rate of $C(X)$ . The table below gives approximate minimal values for the constant k in the Erdős bound for $X=10^n$ as n grows:

$n$	4	6	8	10	12	14	16	18	20	21
k	2.19547	1.97946	1.90495	1.86870	1.86377	1.86293	1.86406	1.86522	1.86598	1.86619

In the other direction, Alford, Granville and Pomerance proved in 1994^[7] that for sufficiently large X,

C(X) > X^\frac{2}{7}.

In 2005, this bound was further improved by Harman^[9] to

C(X) > X^{0.332}

and then has subsequently improved the exponent to just over $1/3$ .

Regarding the asymptotic distribution of Carmichael numbers, there have been several conjectures. In 1956, Erdős^[8] conjectured that there were $X^{1-o(1)}$ Carmichael numbers for X sufficiently large. In 1981, Pomerance^[10] sharpened Erdős' heuristic arguments to conjecture that there are

X^{1-{\frac{\{1+o(1)\}\log\log\log X}{\log\log X}}}

Carmichael numbers up to X. However, inside current computational ranges (such as the counts of Carmichael numbers performed by Pinch^[1] up to 10²¹), these conjectures are not yet borne out by the data.

Generalizations

The notion of Carmichael number generalizes to a Carmichael ideal in any number field K. For any nonzero prime ideal $\mathfrak p$ in ${\mathcal O}_K$ , we have $\alpha^{{\rm N}(\mathfrak p)} \equiv \alpha \bmod {\mathfrak p}$ for all $\alpha$ in ${\mathcal O}_K$ , where ${\rm N}(\mathfrak p)$ is the norm of the ideal $\mathfrak p$ . (This generalizes Fermat's little theorem, that $m^p \equiv m \bmod p$ for all integers m when p is prime.) Call a nonzero ideal $\mathfrak a$ in ${\mathcal O}_K$ Carmichael if it is not a prime ideal and $\alpha^{{\rm N}(\mathfrak a)} \equiv \alpha \bmod {\mathfrak a}$ for all $\alpha \in {\mathcal O}_K$ , where ${\rm N}(\mathfrak a)$ is the norm of the ideal $\mathfrak a$ . When K is $\mathbf Q$ , the ideal $\mathfrak a$ is principal, and if we let a be its positive generator then the ideal $\mathfrak a = (a)$ is Carmichael exactly when a is a Carmichael number in the usual sense.

When K is larger than the rationals it is easy to write down Carmichael ideals in ${\mathcal O}_K$ : for any prime number p that splits completely in K, the principal ideal $p{\mathcal O}_K$ is a Carmichael ideal. Since infinitely many prime numbers split completely in any number field, there are infinitely many Carmichael ideals in ${\mathcal O}_K$ . For example, if p is any prime number that is 1 mod 4, the ideal (p) in the Gaussian integers Z[i] is a Carmichael ideal.

Both prime and Carmichael numbers satisfy the following equality:

\gcd \left(\sum_{x=1}^{n-1} x^{n-1}, n\right)=1

Higher-order Carmichael numbers

Carmichael numbers can be generalized using concepts of abstract algebra.

The above definition states that a composite integer n is Carmichael precisely when the nth-power-raising function p_n from the ring Z_n of integers modulo n to itself is the identity function. The identity is the only Z_n-algebra endomorphism on Z_n so we can restate the definition as asking that p_n be an algebra endomorphism of Z_n. As above, p_n satisfies the same property whenever n is prime.

The nth-power-raising function p_n is also defined on any Z_n-algebra A. A theorem states that n is prime if and only if all such functions p_n are algebra endomorphisms.

In-between these two conditions lies the definition of Carmichael number of order m for any positive integer m as any composite number n such that p_n is an endomorphism on every Z_n-algebra that can be generated as Z_n-module by m elements. Carmichael numbers of order 1 are just the ordinary Carmichael numbers.

An order 2 Carmichael number

According to Howe, 17 · 31 · 41 · 43 · 89 · 97 · 167 · 331 is an order 2 Carmichael number. This product is equal to 443,372,888,629,441.

Properties

Korselt's criterion can be generalized to higher-order Carmichael numbers, as shown by Howe.^[11]

A heuristic argument, given in the same paper, appears to suggest that there are infinitely many Carmichael numbers of order m, for any m. However, not a single Carmichael number of order 3 or above is known.

Notes

1 2 3 Richard Pinch, "The Carmichael numbers up to 10²¹", May 2007.
↑ Carmichael Multiples of Odd Cyclic Numbers "Any divisor of a Carmichael number must be an odd cyclic number"
↑ Proof sketch: If $n$ is square-free but not cyclic, $p_i \mid p_j - 1$ for two prime factors $p_i$ and $p_j$ of $n$ . But if $n$ satisfies Korselt then $p_j - 1 \mid n - 1$ , so by transitivity of the "divides" relation $p_i \mid n - 1$ . But $p_i$ is also a factor of $n$ , a contradiction.
↑ R. D. Carmichael (1910). "Note on a new number theory function". Bulletin of the American Mathematical Society 16 (5): 232–238. doi:10.1090/s0002-9904-1910-01892-9.
↑ V. Šimerka (1885). "Zbytky z arithmetické posloupnosti (On the remainders of an arithmetic progression)". Časopis pro pěstování matematiky a fysiky 14 (5): 221–225.
↑ Chernick, J. (1939). "On Fermat's simple theorem" (PDF). Bull. Amer. Math. Soc. 45: 269–274. doi:10.1090/S0002-9904-1939-06953-X.
1 2 W. R. Alford; Andrew Granville; Carl Pomerance (1994). "There are Infinitely Many Carmichael Numbers" (PDF). Annals of Mathematics 139: 703–722. doi:10.2307/2118576.
1 2 Erdős, P. (1956). "On pseudoprimes and Carmichael numbers" (PDF). Publ. Math. Debrecen 4: 201–206. MR 79031.
↑ Glyn Harman (2005). "On the number of Carmichael numbers up to x". Bulletin of the London Mathematical Society 37: 641–650. doi:10.1112/S0024609305004686.
↑ Pomerance, C. (1981). "On the distribution of pseudoprimes". Math. Comp. 37: 587–593. doi:10.1090/s0025-5718-1981-0628717-0. JSTOR 2007448.
↑ Everett W. Howe. "Higher-order Carmichael numbers." Mathematics of Computation 69 (2000), pp. 1711–1719.

References

Carmichael, R. D. (1910). "Note on a new number theory function". Bulletin of the American Mathematical Society 16 (5): 232–238. doi:10.1090/s0002-9904-1910-01892-9.
Carmichael, R. D. (1912). "On composite numbers P which satisfy the Fermat congruence $a^{P-1}\equiv 1\bmod P$ ". American Mathematical Monthly 19 (2): 22–27. doi:10.2307/2972687. delete character in |title= at position 64 (help)
Chernick, J. (1939). "On Fermat's simple theorem" (PDF). Bull. Amer. Math. Soc. 45: 269–274. doi:10.1090/S0002-9904-1939-06953-X.
Korselt, A. R. (1899). "Problème chinois". L'Intermédiaire des Mathématiciens 6: 142–143.
Löh, G.; Niebuhr, W. (1996). "A new algorithm for constructing large Carmichael numbers" (PDF). Math. Comp. 65: 823–836. doi:10.1090/S0025-5718-96-00692-8.
Ribenboim, P. (1989). The Book of Prime Number Records. Springer. ISBN 978-0-387-97042-4.
Šimerka, V. (1885). "Zbytky z arithmetické posloupnosti (On the remainders of an arithmetic progression)". Časopis pro pěstování matematiky a fysiky 14 (5): 221–225.

External links

Hazewinkel, Michiel, ed. (2001), "Carmichael number", Encyclopedia of Mathematics, Springer, ISBN 978-1-55608-010-4
Table of Carmichael numbers
$10^{12}$
$10^{18}$
"The Dullness of 1729" at MathPages.com.
Weisstein, Eric W., "Carmichael Number", MathWorld.
Final Answers Modular Arithmetic

Classes of natural numbers

Powers and
related numbers

Of the form
a × 2^b ± 1

Other polynomial
numbers

Recursively defined
numbers

Possessing a
specific set
of other numbers

Expressible via
specific sums

Generated
via a sieve

Lucky

Code related

Meertens

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 Octahedral Dodecahedral Icosahedral Stella octangula

pyramidal	Square pyramidal Pentagonal pyramidal Hexagonal pyramidal Heptagonal pyramidal

4-dimensional

centered	Centered pentachoric Squared triangular

non-centered	Pentatope

Pseudoprimes

Combinatorial
numbers

Arithmetic functions

By properties of σ(n)	Abundant Almost perfect Arithmetic Colossally abundant Descartes Hemiperfect Highly abundant Highly composite Hyperperfect Multiply perfect Perfect Practical number Primitive abundant Quasiperfect Refactorable Sublime Superabundant Superior highly composite Superperfect

By properties of Ω(n)	Almost prime Semiprime

By properties of φ(n)	Highly cototient Highly totient Noncototient Nontotient Perfect totient Sparsely totient

By properties of s(n)	Amicable Betrothed Deficient Semiperfect

Dividing a quotient

Other prime factor
or divisor related
numbers

Recreational
mathematics

Base-dependent
numbers

This article is issued from Wikipedia - version of the Wednesday, March 02, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.