Answer :
We have a problem with three different state of the ratio of flow velocity to speed of sound.
That is,
a) Mach number to evaluate is 0.2, that mean we have a subsonic state.
The equation here for lift coefficient is,
[tex]c_1 = 2\pi \alpha[/tex]
where [tex]\alpha[/tex] should be expressed in Rad.
[tex]\alpha = \frac{5}{57.3}= 0.087[/tex]
So replacing in equation for subsonic state,
[tex]c_1 = 2\pi (0.087)=0.548[/tex]
b) In this situation we have a transonic state, so we need to use the Prandtl-Glauert rule,
[tex]c_{t}=\frac{\c{t_0}}{\sqrt{1-M^2_{\infty}}} = \frac{0.548}{\sqrt{1-0.7^2}}=0.767[/tex]
c) For this case we have a supersonic state, so we use that equation,
[tex]c_s = \frac{4\alpha}{\sqrt{M^2_{\infty}-1}}=\frac{4(0.087)}{\sqrt{2^2-1}}=0.2[/tex]