Euler pseudoprime: Difference between revisions

Revision as of 09:33, 17 November 2007

A composite number n is called an Euler pseudoprime to a natural base a, if $\scriptstyle a^{\frac {n-1}{2}}\equiv 1{\pmod {n}}$ or $\scriptstyle a^{\frac {n-1}{2}}\equiv \left(-1\right){\pmod {n}}$

Properties

Every Euler pseudoprime is odd.
Every Euler pseudoprime is also a Fermat pseudoprime:

\left(a^{\frac {n-1}{2}}\right)^{2}=a^{n-1}

and

1^{2}=\left(-1\right)^{2}=1\

Every Euler Pseudoprime to base a, which satisfy $\scriptstyle a^{(n-1)/2}\equiv \left({\frac {a}{n}}\right){\pmod {n}}$ is an Euler-Jacobi pseudoprime.
Carmichael numbers and Strong pseudoprimes are Euler pseudoprimes too.

Absolute Euler pseudoprime

An absolute Euler pseudoprime is a composite number c, that satisfies the conrgruence $\scriptstyle a^{\frac {c-1}{2}}\equiv 1{\pmod {c}}$ or $\scriptstyle a^{\frac {n-1}{2}}\equiv \left(-1\right){\pmod {n}}$ for every base a that is coprime to c. Every absolute Euler pseudoprime is also a Carmichael number.

@@ Line 1: / Line 1: @@
-A composite number ''n'' is called an '''Euler pseudoprime''' to a natural base ''a'', if <math>a^{\frac {n-1}{2}} \equiv 1 \pmod n</math> or <math>a^{\frac {n-1}{2}} \equiv \left( -1\right) \pmod n</math>
+A composite number ''n'' is called an '''Euler pseudoprime''' to a natural base ''a'', if <math>\scriptstyle a^{\frac {n-1}{2}} \equiv 1 \pmod n</math> or <math>\scriptstyle a^{\frac {n-1}{2}} \equiv \left( -1\right) \pmod n</math>
 == Properties ==
@@ Line 7: / Line 7: @@
 :and
 :<math>1^2 = \left( -1\right) ^2 = 1\ </math>
-*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>\scriptstyle 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.
 == Absolute Euler pseudoprime ==
-An absolute Euler pseudoprime is a composite number ''c'', that satisfies the conrgruence <math>a^{\frac{c-1}{2}} \equiv 1 \pmod c </math>  or <math>a^{\frac {n-1}{2}} \equiv \left( -1\right) \pmod n</math> for every base ''a'' that is coprime to ''c''. Every absolute Euler pseudoprime is also a [[Carmichael number]].
+An absolute Euler pseudoprime is a composite number ''c'', that satisfies the conrgruence <math>\scriptstyle a^{\frac{c-1}{2}} \equiv 1 \pmod c </math>  or <math>\scriptstyle a^{\frac {n-1}{2}} \equiv \left( -1\right) \pmod n</math> for every base ''a'' that is coprime to ''c''. Every absolute Euler pseudoprime is also a [[Carmichael number]].
 == Further reading ==

Euler pseudoprime: Difference between revisions

Revision as of 09:33, 17 November 2007

Properties

Absolute Euler pseudoprime

Further reading

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