The distance travelled by the signal is 5 km

Loss suffered in path of transmission $=2 \mathrm{~dB} / \mathrm{km}$

So, total loss suffered in $5 \mathrm{~km}=-2 \times 5=-10 \mathrm{~dB}$

Total amplifier gain $=10 \mathrm{~dB}+20 \mathrm{~dB}=30 \mathrm{~dB}$

Overall gain in signal $=30-10=20 \mathrm{~dB}$

According to the question, gain in $\mathrm{dB}=10 \log _{10} \frac{P_0}{P_i}$

$\therefore \quad 20=10 \log _{10} \frac{P_0}{P_i}$

or $\quad \log _{10} \frac{P_0}{P_i}=2$

Here, $P_i=1.01 \mathrm{~mW}$ and $P_0$ is the output power.

$$\begin{array}{ll} \therefore & \frac{P_0}{P_i}=10^2=100 \\ \Rightarrow & P_0=P_i \times 100=1.01 \times 100 \\ \text { or } & P_0=101 \mathrm{~mW} \end{array}$$

Thus, the output power is 101 mW .

Given, height of antenna $h=20 \mathrm{~m}$

Radius of earth $=6.4 \times 10^6 \mathrm{~m}$

At the ground level,

$$\begin{aligned} & \text {(i) Range }=\sqrt{2 h R}=\sqrt{2 \times 20 \times 6.4 \times 10^6} \\ & =16000 \mathrm{~m}=16 \mathrm{~km} \\ & \text { Area covered } A=\pi(\text { range })^2 \\ & =3.14 \times 16 \times 16=803.84 \mathrm{~km}^2 \end{aligned}$$

(ii) At a height of $H=25 \mathrm{~m}$ from ground level

$$\begin{aligned} \text { Range } & =\sqrt{2 h R}+\sqrt{2 H R} \\ & =\sqrt{2 \times 20 \times 6.4 \times 10^6}+\sqrt{2 \times 25 \times 6.4 \times 10^6} \\ & =16 \times 10^3+17.9 \times 10^3 \\ & =33.9 \times 10^3 \mathrm{~m} \\ & =33.9 \mathrm{~km} \end{aligned}$$

$$\begin{aligned} &\begin{aligned} \text { Area covered } & =\pi(\text { Range })^2 \\ & =3.14 \times 33.9 \times 33.9 \\ & =3608.52 \mathrm{~km}^2 \\ \text { Percentage increase in area } & =\frac{\text { Difference in area }}{\text { Initial area }} \times 100 \\ & =\frac{(3608.52-803.84)}{803.84} \times 100 \\ & =348.9 \% \end{aligned}\\ &\text { Thus, the percentage increase in area covered is 348.9\% } \end{aligned}$$

Consider the figure given below to solve this question.

Suppose the height of transmitting antenna or receiving antenna in order to cover the entire surface of earth through communication is $h_t$ and radius of earth is $R$

Then, maximum distance

$$\begin{array}{l} d_m^2 =\left(R+h_t\right)^2+\left(R+h_t\right)^2 \\ =2\left(R+h_t\right)^2 \\ \therefore \quad d_m =\sqrt{2 h_t R}+\sqrt{2 h_t R}=2 \sqrt{2 h_t R} \\ \Rightarrow \quad 8 h_t R =2\left(R+h_t\right)^2 \\ \Rightarrow \quad 4 h_t R =R^2+2 R h_t+h_t^2 \\ \Rightarrow \quad R^2-2 h_t R+h_t^2 =0 \\ \Rightarrow \quad \left(R-h_t\right)^2 =0 \\ \Rightarrow \quad R =h_t. \end{array}$$

Since, space wave frequency is used so $\lambda<< h_t$, hence only tower height is to be taken into consideration. In three dimensions of earth, 6 antenna towers of each of height $h_t=R$ would be used to cover the entire surface of earth with communication programme.

The maximum frequency for reflection of sky waves

$$f_{\max }=9\left(N_{\max }\right)^{1 / 2}$$

where, $N_{\max }$ is a maximum electron density.

For $\mathrm{F}_1$ layer,

$$\begin{aligned} f_{\max } & =5 \mathrm{MHz} \\ \text{So,}\quad 5 \times 10^6 & =9\left(N_{\max }\right)^{1 / 2} \end{aligned}$$

Maximum electron density

$$N_{\max }=\left(\frac{5}{9} \times 10^6\right)^2=3.086 \times 10^{11} / \mathrm{m}^3$$

For $F_2$ layer, $$f_{\max }=8 \mathrm{MHz}$$

So, $$8 \times 10^6=9\left(N_{\max }\right)^{1 / 2}$$

Maximum electron density

$$N_{\max }=\left(\frac{8 \times 10^6}{9}\right)^2=7.9 \times 10^{11} / \mathrm{m}^3$$

In amplitude modulated signal, only side band frequencies contain information. Thus only $\left(\omega_c+\omega_m\right)$ and $\left(\omega_c-\omega_m\right)$ contain information.

Now, according to question, the total radiated power is due to energy carried by

$$\omega_c,\left(\omega_C-\omega_m\right) \text { and }\left(\omega_c+\omega_m\right) .$$

Thus to minimise the cost of radiation without compromising on information $\omega_c$ can be left and transmitting. $\left(\omega_c+\omega_m\right),\left(\omega_c-\omega_m\right)$ or both $\left(\omega_c+\omega_m\right)$ and $\left(\omega_c-\omega_m\right)$.