Product of Divisor Sum and Euler Phi Functions

Theorem
Let $n$ be an integer such that $n \ge 2$.

Let the prime decomposition of $n$ be:
 * $n = p_1^{k_1} p_2^{k_2} \ldots p_r^{k_r}$

Let $\map \sigma n$ be the sigma function of $n$.

Let $\map \phi n$ be the Euler phi function of $n$.

Then:
 * $\ds \map \sigma n \map \phi n = n^2 \prod_{1 \mathop \le i \mathop \le r} \paren {1 - \frac 1 {p_i^{k_i + 1} } }$

Proof
From Euler Phi Function of Integer:
 * $\ds \map \phi n = \prod_{1 \mathop \le i \mathop \le r} p_i^{k_i - 1} \paren {p_i - 1}$

From Sigma Function of Integer:
 * $\ds \map \sigma n = \prod_{1 \mathop \le i \mathop \le r} \frac {p_i^{k_i + 1} - 1} {p_i - 1}$

So:
 * $\ds \map \sigma n \map \phi n = \prod_{1 \mathop \le i \mathop \le r} \paren {\frac {p_i^{k_i + 1} - 1} {p_i - 1} } p_i^{k_i - 1} \paren {p_i - 1}$

Taking a general factor of this product:

So:
 * $\ds \map \sigma n \map \phi n = \prod_{1 \mathop \le i \mathop \le r} p_i^{2 k_i} \paren {1 - \frac 1 {p_i^{k_i + 1} } }$

Hence:
 * $\ds \prod_{1 \mathop \le i \mathop \le r} p_i^{2 k_i} = \paren {\prod_{1 \mathop \le i \mathop \le r} p_i^{k_i} }^2 = n^2$

and the result follows.