v = 45 * <sin(50), cos(50)>
I've bolded v to denote that it's a vector quantity, and the angle brackets (<>) denote a vector with the x portion first and the y portion second. The 45 distributes through to both.
This is your initial velocity. Because we're ignoring air resistance (you are usually allowed in these problems since modeling air resistance can get complicated), the x component does not change for the entire time. This lets us find the amount of time it will take the arrow to reach 150 meters:
t = 150m / (45*sin(50) (m/s))
This gives the time in seconds. We now know everything necessary to apply the formula for the position of an object under constant acceleration to find the height of the arrow.
The formula is: s = x0 + v0*t + (1/2)a*t²
...where s means "position" for some reason, and "x0" and "v0" are the initial position and velocity. Though I've given the vector form of the formula, in this problem we are only concerned with one dimension so we can use the scalar form. Now:
x0 = 0
v0 = 45 * cos(50)
t = 150 / (45 * sin(50))
a = -g = -9.8 m/s²
Plug those into the formula, and you'll have your answer.
]]>a arrow is fired with a velocity of 45 m/s at an angle of 50 degrees. what is the height of the arrow 150 meters away.
]]>