Euler pseudoprime: Difference between revisions
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*Every Euler Pseudoprime to base ''a'', which satisfy <math>a^{(n-1)/2}\equiv\left(\frac an\right)\pmod n</math> is an [[Euler-Jacobi pseudoprime]]. | *Every Euler Pseudoprime to base ''a'', which satisfy <math>a^{(n-1)/2}\equiv\left(\frac an\right)\pmod n</math> is an [[Euler-Jacobi pseudoprime]]. | ||
*[[Carmichael number|Carmichael numbers]] and [[Strong pseudoprime|Strong pseudoprimes]] are Euler pseudoprimes too. | *[[Carmichael number|Carmichael numbers]] and [[Strong pseudoprime|Strong pseudoprimes]] are Euler pseudoprimes too. | ||
== Further reading == | |||
* [[Richard E. Crandall]] and [[Carl Pomerance]]: Prime Numbers. A Computational Perspective. Springer Verlag, ISBN 0-387-25282-7 | |||
* [[Paolo Ribenboim]]: The New Book of Prime Number Records. Springer Verlag, 1996, ISBN 0-387-94457-5 | |||
[[Category:Mathematics Workgroup]] | |||
Revision as of 13:49, 7 November 2007
A composite number n is called an Euler pseudoprime to a natural base a, if
Properties
- Every Euler pseudoprime is odd.
- Every Euler pseudoprime is also a Fermat Pseudoprime:
- and
- Every Euler Pseudoprime to base a, which satisfy is an Euler-Jacobi pseudoprime.
- Carmichael numbers and Strong pseudoprimes are Euler pseudoprimes too.
Further reading
- Richard E. Crandall and Carl Pomerance: Prime Numbers. A Computational Perspective. Springer Verlag, ISBN 0-387-25282-7
- Paolo Ribenboim: The New Book of Prime Number Records. Springer Verlag, 1996, ISBN 0-387-94457-5