[tex]\cos\dfrac{3x}2=\cos\left(\dfrac\pi2+\dfrac x2\right)[/tex]
[tex]\implies \dfrac{3x}2=2n\pi+\dfrac\pi2+\dfrac x2[/tex]
follows from the fact that the cosine function is [tex]2\pi[/tex]-periodic, which means [tex]\cos x=\cos(2\pi+x)[/tex]. Roughly speaking, this is the same as saying that a point on a circle is the same as the point you get by completing a full revolution around the circle (i.e. add [tex]2\pi[/tex] to the original point's angle with respect to the horizontal axis).
If you make another complete revolution (so we're effectively adding [tex]4\pi[/tex]) we get the same result: [tex]\cos x=\cos(4\pi+x)[/tex]. This is true for any number of complete revolutions, so that this pattern holds for any even multiple of [tex]\pi[/tex] added to the argument. Therefore [tex]\cos x=\cos(2n\pi+x)[/tex] for any integer [tex]n[/tex].
Next, because [tex]\cos(-x)=\cos x[/tex], it follows that [tex]\cos x=\cos(2n\pi-x)[/tex] is also true for any integer [tex]n[/tex]. So we have
[tex]\implies \dfrac{3x}2=2n\pi\pm\left(\dfrac\pi2+\dfrac x2\right)[/tex]
The rest follows from considering either case and solving for [tex]x[/tex].
