>> **Question:** Are the properties as follows holds? **Version 1:** the answer by Bjørn Kjos-Hanssen Let $P$ be a positive integers. We written: $P=$ $a_1^{x_1}a_2^{x_2}...a_n^{x_n}$ $=b_1^{y_1}b_2^{y_2}...b_k^{y_k}$ where $a_i, b_j$ are integers greater than $1$. if $\prod_{i=1}^n a_i \le \prod_{j=1}^k b_j $ then $$\prod_{i=1}^n (1-\frac{1}{a_i}) \le \prod_{j=1}^k (1-\frac{1}{b_j}) $$ $$\prod_{i=1}^n (1-\frac{1}{a_i})^{x_i} \le \prod_{j=1}^k (1-\frac{1}{b_j})^{y_j} $$ **Comment:** The answer of Bjørn Kjos-Hanssen is: > No, let $b_1,b_2,a_1,a_2$ be $2,6,3,4$. Then $$ (1-1/2)(1-1/6)=5/12 \not\ge 1/2=(1-1/3)(1-1/4) $$ But I think the asnswer is not counter example. Because $2.6 \le 3.4$ we can write $$ (1-1/2)(1-1/6)=5/12 \le 1/2=(1-1/3)(1-1/4) $$. To clearly I changes the question as follows: **Version 2:** Let $P$ be a positive integers. We written: $P=$ $a_1^{x_1}a_2^{x_2}...a_n^{x_n}$ $=b_1^{y_1}b_2^{y_2}...b_k^{y_k}$ where $a_i, b_j$ are integers greater than $1$. > if $\prod_{i=1}^n a_i < \prod_{j=1}^k b_j $ and $a_i \le b_j$ then $$\prod_{i=1}^n (1-\frac{1}{a_i}) \le \prod_{j=1}^k (1-\frac{1}{b_j}) $$ $$\prod_{i=1}^n (1-\frac{1}{a_i})^{x_i} \le \prod_{j=1}^k (1-\frac{1}{b_j})^{y_j} $$