One of fundamental inequalities on logarithm is:

$$ 1 – \frac1x \leq \log x \leq x-1 \quad\text{for all $x > 0$},$$

which you may prefer write in the form of

$$ \frac{x}{1+x} \leq \log{(1+x)} \leq x \quad\text{for all $x > -1$}.$$The upper bound is very intuitive — it’s easy to derive from Taylor series as follows:

$$ \log(1+x) = \sum_{n=1}^\infty (-1)^{n+1}\frac{x^n}{n} \leq (-1)^{1+1}\frac{x^1}{1} = x.$$My question is: “

what is the intuition behind the lower bound?” I know how to prove the lower bound of $\log (1+x)$ (maybe by checking the derivative of the function $f(x) = \frac{x}{1+x}-\log(1+x)$ and showing it’s decreasing) but I’m curious how one can obtain this kind of lower bound. My ultimate goal is to come up with a new lower bound on some logarithm-related function, and I’d like to apply the intuition behind thestandard logarithm lower-boundto my setting.

**Answer**

Take the upper bound:

$$

\ln {x} \leq x-1

$$

Apply it to $1/x$:

$$

\ln \frac{1}{x} \leq \frac{1}{x} – 1

$$

This is the same as

$$

\ln x \geq 1 – \frac{1}{x}.

$$

**Attribution***Source : Link , Question Author : Federico Magallanez , Answer Author : Dan Shved*