# Difference between revisions of "Carmichael function"

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== First Definition == | == First Definition == | ||

− | The Carmichael function <math>\lambda</math> is defined at <math>n</math> to be the smallest [[positive integer]] <math>\lambda(n)</math> such that <math>a^{\lambda(n)} \equiv 1\pmod {n}</math> for all positive [[integer]]s <math>a</math> [[relatively prime]] to <math>n</math>. The [[order]] of <math>a\pmod {n}</math> always divides <math>\lambda(n)</math>. | + | The Carmichael function <math>\lambda</math> is defined at <math>n</math> to be the smallest [[positive integer]] <math>\lambda(n)</math> such that <math>a^{\lambda(n)} \equiv 1\pmod {n}</math> for all positive [[integer]]s <math>a</math> [[relatively prime]] to <math>n</math>. The [[order(group theory)]] of <math>a\pmod {n}</math> always divides <math>\lambda(n)</math>. |

This function is also known as the ''reduced totient function'' or the ''least universal exponent'' function. | This function is also known as the ''reduced totient function'' or the ''least universal exponent'' function. |

## Revision as of 15:53, 26 February 2020

There are two different functions called the **Carmichael function**. Both are similar to Euler's totient function .

## First Definition

The Carmichael function is defined at to be the smallest positive integer such that for all positive integers relatively prime to . The order(group theory) of always divides .

This function is also known as the *reduced totient function* or the *least universal exponent* function.

Suppose . We have

### Examples

*This article is a stub. Help us out by expanding it.*

Evaluate . [1]

## Second Definition

The second definition of the Carmichael function is the least common multiples of all the factors of . It is written as . However, in the case , we take as a factor instead of .

### Examples

*This article is a stub. Help us out by expanding it.*