Recall the double angle identity,
[tex]\sin^2x=\dfrac{1-\cos2x}2[/tex]
Then
[tex]\sin^2x=\dfrac{1-\cos2x}2=\dfrac1{36}\implies\cos2x=\dfrac{17}{18}[/tex]
[tex]\cos x[/tex] has a period of [tex]2\pi[/tex], so that [tex]\cos x=\cos(x+2n\pi)[/tex] for any integer [tex]n[/tex]. This means
[tex]2x=\cos^{-1}\dfrac{17}{18}+2n\pi[/tex]
[tex]\implies x=\dfrac12\cos^{-1}\dfrac{17}{18}+n\pi[/tex]
We get solutions of this form in the interval [tex][0,2\pi][/tex] for [tex]n=0[/tex] and [tex]n=1[/tex], giving
[tex]x=\dfrac12\cos^{-1}\dfrac{17}{18}[/tex]
or
[tex]x=\dfrac12\cos^{-1}\dfrac{17}{18}+\pi[/tex]
