1.8 Relative motion of projectiles (Page 3/4)

Kinematics fundamentals Page 3 / 4

Resultant relative motion

The component relative velocities in two mutually perpendicular directions have been derived in the previous section as :

Relative velocity of projectiles

Relative velocity of projectiles depends on initial velocities of projectiles.

$v_{A B x} = u_{A x} - u_{B x}$

$v_{A B y} = u_{A y} - u_{B y}$

These equations are very important results. It means that relative velocity between projectiles is exclusively determined by initial velocities of the two projectiles i.e. by the initial conditions of the two projectiles as shown in the figure below. The component relative velocities do not depend on the subsequent motion i.e. velocities. The resultant relative velocity is vector sum of component relative velocities :

$v_{A B} = v_{A B x} i + v_{A B y} j$

Resultant relative velocity of projectiles

Resultant relative velocity of projectiles is constant.

Since the component relative velocities do not depend on the subsequent motion, the resultant relative velocity also does not depend on the subsequent motion. The magnitude of resultant relative velocity is given by :

\Rightarrow v_{A B} = \sqrt{v_{A B x}^{2} + v_{A B y}^{2}}

The slope of the relative velocity of “A” with respect to “B” from x-direction is given as :

\Rightarrow \tan α = \frac{v_{A B y}}{v_{A B x}}

Problem : Two projectiles are projected simultaneously from two towers as shown in the figure.Find the magnitude of relative velocity, $v_{A B}$ , and the angle that relative velocity makes with horizontal direction

Relative motion of projectiles

Solution : We shall first calculate relative velocity in horizontal and vertical directions and then combine them to find the resultant relative velocity. Let "x" and "y" axes be in horizontal and perpendicular directions. In x-direction,

$v_{A B x} = u_{A x} - u_{B x} = 10 \sqrt{2} \cos 45^{0} - (- 10) = 10 \sqrt{2} X \frac{1}{\sqrt{2}} + 10 = 20 m / s$

In y-direction,

$v_{A B y} = u_{A y} - u_{B y} = 10 \sqrt{2} \cos 45^{0} - 0 = 10 \sqrt{2} X \frac{1}{\sqrt{2}} = 10 m / s$

The magnitude of relative velocity is :

$\Rightarrow v_{A B} = \sqrt{(v_{A B x}^{2} + v_{A B y}^{2})} = \sqrt{(20^{2} + 10^{2})} = 10 \sqrt{5} m / s$

The angle that relative velocity makes with horizontal is :

$\Rightarrow \tan θ = \frac{v_{A B y}}{v_{A B x}} = \frac{10}{20} = \frac{1}{2}$ $\Rightarrow θ = \tan^{- 1} (\frac{1}{2})$

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Physical interpretation of relative velocity of projectiles

The physical interpretation of the results obtained in the previous section will help us to understand relative motion between two projectiles. We recall that relative velocity can be interpreted by assuming that the reference object is stationary. Consider the expression, for example,

$v_{A B x} = u_{A x} - u_{B x}$

What it means that relative velocity “vABx” of object “A” with respect to object “B” in x-direction is the velocity of the object “A” in x-direction as seen by the stationary object “B”. This interpretation helps us in understanding the nature of relative velocity of projectiles.

Extending the reasoning, we can say that object “A” is moving with uniform motion in “x” and “y” directions as seen by the stationary object “B”. The resultant motion of “A”, therefore, is along a straight line with a constant slope. This result may be a bit surprising as we might have expected that two projectiles see (if they could) each other moving along some curve - not a straight line.

Relative velocity of projectiles

Relative velocity of projectiles is constant.

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Source: OpenStax, Kinematics fundamentals. OpenStax CNX. Sep 28, 2008 Download for free at http://cnx.org/content/col10348/1.29

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