As the refractive index for red is less than that for blue, parallel beams of light incident on a lens will be bent more towards the axis for blue light compared to red.

In other words, $\propto_b>\propto_r$

By lens maker's formula,

$$\frac{1}{f}=\left(n_{21}-1\right)\left(\frac{1}{R_1}-\frac{1}{R_2}\right)$$

Therefore, $f_b< f_t$.

Thus, the focal length for blue light will be smaller than that for red.

The least distance of distinct vision of an average person (i.e., $D$ ) is 25 cm , in order to view an object with magnification 10,

Here, $v=D=25 \mathrm{~cm}$ and $u=f$

But the magnification $m=v / u=D / f$

$$\begin{aligned} & m=\frac{D}{f} \\ \Rightarrow\quad & f=\frac{D}{m}=\frac{25}{10}=2.5=0.025 \mathrm{~m} \\ & P=\frac{1}{0.025}=40 \mathrm{D} \end{aligned}$$

This is the required power of lens.

No, the reversibility of the lens maker's equation.

$$\begin{aligned} &\text { Let the apparent depth be } O_1 \text { for the object seen from } m_2 \text {, then }\\ &O_1=\frac{\propto_2}{\propto_1} \frac{h}{3} \end{aligned}$$

Since, apparent depth $=$ real depth $/$ refractive index $\propto$.

Since, the image formed by Medium $1, \mathrm{O}_2$ act as an object for Medium 2.

If seen from $\propto_3$, the apparent depth is $\mathrm{O}_2$.

Similarly, the image formed by Medium $2, \mathrm{O}_2$ act as an object for Medium 3

$$ \begin{aligned} O_2 & =\frac{\propto_3}{\propto_2}\left(\frac{h}{3}+O_1\right) \\ & =\frac{\propto_3}{\propto_2}\left(\frac{h}{3}+\frac{\propto_2 h}{\propto_1 3}\right)=\frac{h}{3}\left(\frac{\propto_3}{\propto_2}+\frac{\propto_2}{\propto_1}\right) \end{aligned}$$

Seen from outside, the apparent height is

$$\begin{aligned} O_3 & =\frac{1}{\propto_3}\left(\frac{h}{3}+O_2\right)=\frac{1}{\propto_3}\left[\frac{h}{3}+\frac{h}{3}\left(\frac{\propto_3}{\propto_2}+\frac{\alpha_3}{\propto_1}\right)\right] \\ & =\frac{h}{3}\left(\frac{1}{\propto_1}+\frac{1}{\propto_2}+\frac{1}{\propto_3}\right) \end{aligned}$$

This is the required expression of apparent depth.