Answer to Question #114676 in Quantum Mechanics for Michael Mateus

If the bullet is fired horizontally in the same level as that of the target it will be pulled by the gravitational force during the flight.

Initial velocity = 180 m/s

Distance of the target = 75 m

Time taken = dist. / vel.= 75/180 = 0.416 sec

During this time the bullet is under the gravitational pull

Its vertical initial velocity = u = 0 m/s

Acceleration = a = 9.8 m/s²

Time = 0.416 sec

The distance covered "h = ut + \\frac12at\u00b2"

h = "0 \\times 0.416 + \\frac12 (9.8) (0.416)^2"

h = 0 + 0.85 m

The bullet will miss the target by 0.85 m

To adjust this the bullet should be aimed at a little elevated, say θ°

It will be a projectile motion. During the projectile motion the "time of flight" is equal to

T ="\\dfrac{(2 u Sin \u03b8) }{g,}"

& the "horizontal range" R is equal to:

R = "\\dfrac{(u\u00b2 Sin 2\u03b8) }{ g}"

where u is the initial velocity, θ, the angle of elevation., g, the acceleration due to gravity.

75 = "\\frac{(180^2\\sin 2\u03b8) }{9.8}"

75 = "\\frac{32400 \\times \\sin 2\u03b8 }{ 9.8}"

Sin 2θ ="\\frac{ (75 \\times9.8) }{ 32400}" = 0.0227

2θ = 1.3°

θ = 0.65 °

The barrel should be elevated through an angle 0.65°