if we assume the projectile was launched at ground level and landed at ground level,
time of flight = 2.3
time to reach max height = 2.3/2 = 1.15
vertical velocity at max height = 0 (because the projectile has to turn)
v = u +at
we know that initial vertical velocity is given by u*sin(a), where 'a' represents the initial angle
at max height: 0 = usin(a) + (-9.8)(1.15)
rearranging, we get: usin(a) = 11.27 which implies that u = (11.27)/sin(a)
horizontal range formula: s = u*cos(a)*t , where 'u*cos(a)' represents initial horizontal velocity
we know total range is 70m, and this occurs at the end of flight when t = 2.3
therefore: 70 = 2.3ucos(a)
dividing both sides by 2.3, we get (70/2.3) = ucos(a) which implies that u = (70/2.3)/cos(a)
now that we have 2 expressions for u, set both equal to each other
(11.27)/sin(a) = (70/2.3)/cos(a)
rearranging by cross multiplying, we get
11.27cos(a) = (70/2.3)*sin(a)
dividing both sides by cos(a), we get
11.27 = (70/2.3)*tan(a)
dividing both sides by (70/2.3), we get
tan(a) = (25.921/70), now we can take inverse tangent of both sides and get
a = 20.3 degrees (1 d.p)
let me know if there were any mistakes because i had to type this out. process should be correct though
