RANGE OF A PROJECTILE


In physics, a projectile launched with specific initial conditions in a uniform gravity field will have a predictable range. As in Trajectory of a projectile, we will use:

g: the gravitational acceleration—usually taken to be 9.81 m/s2 near the Earth's surface

θ: the angle at which the projectile is launched

v: the velocity at which the projectile is launched

y0: the initial height of the projectile

d: the total horizontal distance travelled by the projectile
When neglecting air resistance, the range of a projectile will be
: d = rac{v cos heta}{g} left( v sin heta + sqrt{(v sin heta)^2 + 2gy_0}
ight)
If (y0) is taken to be zero, meaning the object is being launched on flat ground, the range of the projectile will then simplify to
: d = rac{v^2}{g} sin 2 heta
= Derivations =

Contents
Flat Ground
Uneven Ground
Flat Ground

First we examine the case where (y0) is zero. The horizontal position (x(t)) of the projectile is
: x(t) = rac{}{} vcos left( heta
ight) t
In the vertical direction
: y(t) = rac{} {} vsin left( heta
ight) t - rac{1} {2} g t^2
We are interested in the time when the projectile returns to the same height it originated at, thus
: 0 = rac{} {} vsin left( heta
ight) t - rac{1} {2} g t^2
By applying the quadratic formula
: rac{} {}t = 0
or
: t = rac{2 v sin heta} {g}
The first solution corresponds to when the projectile is first launched. The second solution is the useful one for determining the range of the projectile. Plugging this value for (t) into the horizontal equation yields
: x = rac {2 v^2 cos left( heta
ight) sin left( heta
ight)} {g}
Applying the trigonometric identity
: sin(2x) = 2 sin (x) cos(x)
allows us to simplify the solution to
: d = rac {v^2} {g} sin 2 heta
Note that when (theta) is 45°, the solution becomes
: d = rac {v^2} {g}
Uneven Ground

Now we will allow (y0) to be nonzero. Our equations of motion are now
: x(t) = rac{}{} vcos left( heta
ight) t
and
: y(t) = y_0 + rac{} {} vsin left( heta
ight) t - rac{1} {2} g t^2
Once again we solve for (t) in the case where the (y) position of the projectile is at zero (since this is how we defined our starting height to begin with)
: 0 = y_0 + rac{} {} vsin left( heta
ight) t - rac{1} {2} g t^2
Again by applying the quadratic formula we find two solutions for the time. After several steps of algebraic manipulation
: t = rac {v sin heta} {g} pm rac {sqrt{left(v sin heta
ight)^2 + 2 g y_0}} {g}
The square root must be a positive number, and since the velocity and the cosine of the launch angle can also be assumed to be positive, the solution with the greater time will occur when the positive of the plus or minus sign is used. Thus, the solution is
: t = rac {v sin heta} {g} + rac {sqrt{left(v sin heta
ight)^2 + 2 g y_0}} {g}
Solving for the range once again
: d = rac {v cos heta} {g} left [ v sin heta + sqrt{left(v sin heta
ight)^2 + 2 g y_0}
ight]

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