Euler's theorem

Euler's theorem is a generalization of Fermat's little theorem and states that

$a^{\\varphi (m)} = 1 \\;\\; in \\;\\; Z_{m}$

where $\\varphi(m)$ is Euler's function and $gcd(a,\\; m) = 1$ .

Euler's function

Euler's function $\\varphi(n)$ , where $n \\gt 2$ , is defined as number of integers less than , which are relatively prime to (i.e. their greatest common divisor is equal to ). $\\varphi(1)$ is defined as .

Computing Euler's function

To compute Euler's function of , we factorize to its prime factors $p_{1},\\; p_{2}, \\cdots ,\\; p_{r}$ and plug them into the following formula:

$\\varphi (p_{1}^{n_{1}} \\cdot p_{2}^{n_{2}} \\cdots p_{r}^{n_{r}}) = p_{1}^{n_{1}} \\cdot (1 - {1 \\over p_{1}}) \\cdot p_{2}^{n_{2}} \\cdot (1 - {1 \\over p_{2}}) \\; \\cdots \\; p_{r}^{n_{r}} \\cdot (1 - {1 \\over p_{r}}) =$
$= n \\cdot (1 - {1 \\over p_{1}}) \\cdot (1 - {1 \\over p_{2}}) \\; \\cdots \\; (1 - {1 \\over p_{r}})$

Proof of Euler's theorem

For each number greater than and less or equal to m - 1 , which is relatively prime to and has an inverse in $Z_{m}$ , there exist according to Euler's function exactly $\\varphi(m)$ invertible elements. Let's denote them as $b_{1},\\; b_{2},\\; b_{3}, \\cdots ,\\; b_{n}$ .

For every two elements $b_{i}$ and $b_{j}$ , where and are integers from set $\\{0,\\; 1,\\; 2, \\cdots,\\; \\varphi (m)\\}$ , it holds that:

$b_{i} \\cdot a \\neq b_{j} \\cdot a \\;\\; in \\;\\; Z_{m}$

because $b_{i}$ , $b_{j}$ and are defined as numbers relatively prime to .

Now suppose we have two following sequences:

$b_{1} \\cdot a,\\; b_{2} \\cdot a,\\; b_{3} \\cdot a, \\cdots ,\\; b_{\\varphi (n)} \\cdot a$
$b_{1},\\; b_{2},\\; b_{3}, \\cdots ,\\; b_{\\varphi (n)}$

The sequences contain identical numbers (regardless their order). So let's factor out from the first sequence:

$a^{\\varphi (n)} \\cdot (b_{1},\\; b_{2},\\; b_{3}, \\cdots ,\\; b_{\\varphi (n)}) = b_{1},\\; b_{2},\\; b_{3}, \\cdots ,\\; b_{\\varphi(n)} \\;\\; in \\;\\; Z_{m}$

Finally we can cancel out the whole second sequence and we get the desired expression:

$a^{\\varphi (n)} = 1 \\;\\; in \\;\\; Z_{m}$

Example

Calculate $7^{3822}$ in $Z_{15}$ .

$15 = 5 \\cdot 3$
$\\varphi (15) = 15 \\cdot (1- {1 \\over 5}) \\cdot(1- {1 \\over 3}) = 8$
${{3822} \\over {8}} = 477 \\; (residue \\; 6)$
$7^{3822} = (7^{8})^{477} \\cdot 7^{6} = 1^{477} \\cdot 7^{6} = 1 \\cdot 7^{2} \\cdot 7^{2} \\cdot 7^{2} = 49 \\cdot 49 \\cdot 49 =$
$= 4 \\cdot 4 \\cdot 4 = 16 \\cdot 4 = 1 \\cdot 4 = 4 \\;\\; in \\;\\; Z_{15}$

Sources

VELEBIL, Jiří. Diskrétní matematika : Text k přednášce. Praha : [s.n.], 2007. 193 p.

Euler's function

Computing Euler's function

Proof of Euler's theorem

Example

Sources

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