In this post, for integers $n\geq 1$, I denote the sum of divisors $\sum_{1\leq d\mid n}d$ as $\sigma(n)$ and the Euler's totient function as $\varphi(n)$. It's easy to check* that if we assume that $n=N$ is an odd perfect number then the inequalities
$$\frac{\sigma\left(\frac{\sigma(n)}{2}n^2\right) }{\frac{\sigma(n)}{2}(\sigma(n)-n)^2}\leq \frac{n}{\varphi(\sigma(n)-n)}\tag{1}$$
and
$$8\frac{\sigma\left(\frac{\sigma(n)}{2}n^2\right) }{\frac{\sigma(n)}{2}(\sigma(\sigma(n))-\sigma(n))^2}\leq \frac{n}{\varphi(\sigma(\sigma(n))-\sigma(n))},\tag{2}$$
hold. And it is obvious that every odd perfect number $n=N$ **is an odd integer** satisfying
$$2\mid \sigma(n).\tag{3}$$
**Example.** The odd integer $n=1102725$ is the least positive integer satisfying $(1)$ and $(3)$. But (I know that) this odd integer doesn't satisfy $(2)$.
I'm asking what work can be done for the following questions (the part A) is just a computational exercise) before I'm accepting an answer.
>**Question.** A) Please, I would like to know if you can to calculate the least odd integer $n\geq 1$ satisfying the inequality $(1)$, the condition $(3)$ and also the inequality $(3)$. B) I would like to know if it is possible to elucidate (what work can be done about this) **if the set of solutions** $n$ satisfying all requirements $n\equiv 1\text{ mod }2$, the inequalities $(1)$, $(2)$ and $2\mid \sigma(n)$) **is bounded**, that's: are there finitely/infinitely many solutions over odd integers $n\geq 1$ satisfying both inequalities together the cited condition $(3)$? **Many thanks.**
The motivation of A) is that I'm not able (with my computer and knowledges) to calculate it.
*The calculation is easy from a well known inequality for the sum of divisors function and the Euler's totient (Exercise 9 for Chapter 3 of [1]), since for perfect numbers $\sigma(N)/2=\sigma(N)-N=N$ and thus our inequalities are simplified by using $x^a/\varphi(x^a)=x/\varphi(x)$.
References:
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[1] Tom M. Apostol, *Introduction to Analytic Number Theory*, UTM, Springer (1976).