Answer:
Initial velocity = 16.15 m/s, 30.63° above horizontal
Explanation:
We have equation of motion , [tex]s= ut+\frac{1}{2} at^2[/tex], s is the displacement, u is the initial velocity, a is the acceleration and t is the time.
The horizontal component of a projectile is constant throughout its journey. If u is the initial velocity, the horizontal velocity = u cos θ is a constant.
Final horizontal velocity = 19 cos 43 = 13.90 m/s
So initial horizontal velocity = u cos θ = 13.90 m/s.
We also have horizontal displacement = 30 meter.
Substituting in the equation of motion
[tex]30 = 13.90*t+\frac{1}{2} *0*t^2\\ \\ t=2.16 seconds[/tex]
We also have final vertical velocity = 19*sin 43 = 12.96 m/s, but in vertical direction acceleration due to gravity is there.
We have equation of motion, v = u + at, where v is the final velocity, u is the initial velocity, a is the acceleration and t is the time taken.
In case of vertical motion, final velocity = 12.96 m/s, time taken = 2.16 seconds, acceleration = 9.81 [tex]m/s^2[/tex] and initial velocity = u sin θ
12.96 = u sin θ + 9.81*2.16
u sin θ = -8.23 m/s = 8.23 m/s (upward direction)
So magnitude of initial velocity = [tex]\sqrt{13.90^2+8.23^2} =16.15m/s[/tex]
Direction, θ = tan⁺¹(8.23/13.90) = 30.63° above horizontal ( Since initial vertical velocity is in upward direction)
So Initial velocity = 16.15 m/s, 30.63° above horizontal
