In every right triangle, you have the following identites:
[tex] o = h\sin(\alpha),\quad a = h\cos(\alpha) [/tex]
Where [tex] \alpha [/tex] is one of the acute angles, [tex] o [/tex] is the leg opposite to the angle, [tex] a [/tex] is the leg adjacent to the angle and [tex] a [/tex] is the hypothenuse.
In this case, we know that the adjacent leg is 100ft long, so we can use the second formula to compute the hypothenuse:
[tex] 100 = h\cos(37) \implies h = \dfrac{100}{\cos(37)} [/tex]
Now let's use the first equation to compute the length of the opposite leg, i.e. the one you're interested in:
[tex] o = h\sin(\alpha) = \dfrac{100}{\cos(37)}\sin(37) [/tex]
Note that the ratio between the sine and the cosine is the tangent:
[tex] o = 100\tan(37) [/tex]
If you ask for the tangent of 37 to a calculator, you get
[tex] \tan(37) \approx 0.753554050\ldots [/tex]
So, you have
[tex] 100\tan(37) \approx 75.3554050\ldots[/tex]
Which rounded to the nearest tenth is 75.36
