Carmichael number: Difference between revisions

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A '''Carmichael number''' is a composite number named after the mathematician [[Robert Daniel Carmichael]]. A Carmichael number <math>\scriptstyle c\ </math> satisfies for every integer <math>\scriptstyle a\ </math> that <math>\scriptstyle a^c - a\ </math> is divisible by <math>\scriptstyle c\ </math>. A Carmichael number ''c'' also satisfies the congruence <math>\scriptstyle a^{c-1} \equiv 1 \pmod c</math>, if <math>\scriptstyle \operatorname{gcd}(a,c) = 1</math>. The first few Carmichael numbers are 561, 1105, 1729, 2465, 2821, 6601 and 8911. In 1994 Pomerance, Alford and Granville proved that there exist infinitely many Carmichael numbers.
A '''Carmichael number''' is a composite number named after the mathematician [[Robert Daniel Carmichael]]. A Carmichael number <math>\scriptstyle c\ </math> divides <math>\scriptstyle a^c - a\ </math> for every integer <math>\scriptstyle a\ </math>. A Carmichael number ''c'' also satisfies the [[modular arithmetic|congruence]] <math>\scriptstyle a^{c-1} \equiv 1 \pmod c</math>, if <math>\scriptstyle \operatorname{gcd}(a,c) = 1</math>. The first few Carmichael numbers are 561, 1105, 1729, 2465, 2821, 6601 and 8911. In 1994 Pomerance, Alford and Granville proved that there exist infinitely many Carmichael numbers.


== Properties ==
== Properties ==
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To construct Carmichael numbers with <math>\scriptstyle M_3(n) = (6n+1)\cdot (12n+1)\cdot (18n+1)</math>, you could only use numbers <math>n\ </math> which ends with 0, 1, 5 or 6.
To construct Carmichael numbers with <math>\scriptstyle M_3(n) = (6n+1)\cdot (12n+1)\cdot (18n+1)</math>, you could only use numbers <math>n\ </math> which ends with 0, 1, 5 or 6.


This way to construct Carmichael numbers could expand to <math>M_k(n)=(6n+1)(12n+1)\prod_{i=1}^{k-2}(9\cdot 2^in+1)</math> with the restiction, that for <math>(36\cdot 2^jm + 1)</math> the variable <math>m\ </math> is divisible bei <math>2^j\ </math>
This way to construct Carmichael numbers could expand to <math>M_k(n)=(6n+1)(12n+1)\prod_{i=1}^{k-2}(9\cdot 2^in+1)</math> with the restriction, that for <math>(36\cdot 2^jm + 1)</math> the variable <math>m\ </math> is divisible by <math>2^j\ </math>


==References and notes==
==References and notes==
<references/>
<references/>
== Further reading ==
* [[Richard E. Crandall]] and [[Carl Pomerance]]. Prime Numbers: A Computational Perspective. Springer-Verlag, 2001. ISBN 0-387-25282-7
* [[Paolo Ribenboim]]. The New Book of Prime Number Records. Springer-Verlag, 1996, ISBN 0-387-94457-5
== Links ==
*[http://de.wikibooks.org/wiki/Pseudoprimzahlen:_Tabelle_Carmichael-Zahlen List of Carmichael numbers between 561 and 2,301,745,249]

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A Carmichael number is a composite number named after the mathematician Robert Daniel Carmichael. A Carmichael number divides for every integer . A Carmichael number c also satisfies the congruence , if . The first few Carmichael numbers are 561, 1105, 1729, 2465, 2821, 6601 and 8911. In 1994 Pomerance, Alford and Granville proved that there exist infinitely many Carmichael numbers.

Properties

  • Every Carmichael number is square-free and has at least three different prime factors
  • For every Carmichael number c it holds that is divisible by for every one of its prime factors .
  • Every Carmichael number is an Euler pseudoprime.
  • Every absolute Euler pseudoprime is a Carmichael number.

Chernick's Carmichael numbers

J. Chernick found in 1939 a way to construct Carmichael numbers[1]. If, for a natural number n, the three numbers , and are prime numbers, the product is a Carmichael number. Equivalent to this is that if , and are prime numbers, then the product is a Carmichael number.

To construct Carmichael numbers with , you could only use numbers which ends with 0, 1, 5 or 6.

This way to construct Carmichael numbers could expand to with the restriction, that for the variable is divisible by

References and notes