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a x = g sin α

a y = - g cos α

3: Time of flight

The expression of time of flight differs only with respect to angle of sine function in the numerator of the expression :

T = 2 u sin θ + α g cos α

4: Range of flight

The expression of range of flight differs only with respect to angle of sine function :

R = u 2 g cos 2 α { sin 2 θ + α + sin α }

It is very handy to note that expressions have changed only with respect of the sign of “α” for the time of flight and the range. We only need to exchange “α” by “-α” .

Problem : A ball is projected in horizontal direction from an elevated point “O” of an incline of angle “α” with a speed “u”. If the ball hits the incline surface at a point “P” down the incline, find the coordinates of point “P”.

Projectile motion down an incline

A ball is projected in horizontal direction.

Solution : We can answer this question, using the relation of coordinates with range “R” as :

Projectile motion down an incline

A ball is projected in horizontal direction.

x = R cos α

y = R sin α

Now, range of the flight for the downward flight is given as :

R = u 2 g cos 2 α { sin 2 θ + α + sin α }

The important thing to realize here is that the ball is projected in horizontal direction. As we measure angle from the horizontal line, it is evident that the angle of projection is zero. Hence,

θ = 0 0

Putting in the equation for the range of flight, we have :

R = 2 u 2 sin α g cos 2 α

Therefore, coordinates of the point of return, “P”, is :

x = R cos α = 2 u 2 sin α g cos α

x = 2 u 2 tan α g

Similarly,

y = R sin α = 2 u 2 sin α g cos 2 α sin α

y = 2 u 2 tan 2 α g

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This example illustrated how to use formulae of the range of flight. We should, however, know that actually, we have the options to analyze projectile motion down an incline without using derived formula.

As a matter of fact, we can consider projectile motion down an incline as equivalent to projectile motion from an elevated point as studied in the previous module with out any reference to an incline or wedge. We need to only shift the horizontal base line to meet the point of return. The line joining the point of projection and point of return, then, represents the incline surface.

Projectile motion down an incline

A ball is projected in horizontal direction.

Observe the projectile motion from a height as shown in the figure. Let the projectile returns to a point “P”. The line “OP” then represents the incline surface. We can analyze this motion in rectangular coordinates “x” and “y” in horizontal and vertical direction, using general technique of analysis in component directions.

Here, we work with the same example as before to illustrate the working in this alternative manner.

Problem : A ball is projected in horizontal direction from an elevated point “O” of an incline of angle “α” with a speed “u”. If the ball hits the incline surface at a point “P” down the incline, find the coordinates of point “P”.

Projectile motion down from a height

A ball is projected in horizontal direction.

Solution : We draw or shift the horizontal base and represent the same by the line QP as shown in the figure below.

From the general consideration of projectile motion, the vertical displacement, “y”, is :

y = u y T + 1 2 a y T 2

y = 0 - 1 2 g T 2

Considering the magnitude of vertical displacement only, we have :

y = 1 2 g T 2

On the other hand, consideration of motion in x-direction yields,

x = u x T = u T

Since, we aim to find the coordinates of point of return “P”, we eliminate “T” from the two equations. This gives us :

y = g x 2 2 u 2

From the triangle OPQ, we have :

tan α = y x

y = x tan α

Combining two equations, we have :

y = x tan α = g x 2 2 u 2

tan α = g x 2 u 2

x = 2 u 2 tan α g

and

y = x tan α = 2 u 2 tan 2 α g

The y-coordinate, however, is below origin and is negative. Thus, we put a negative sign before the expression :

y = - 2 u 2 tan 2 α g

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Source:  OpenStax, Physics for k-12. OpenStax CNX. Sep 07, 2009 Download for free at http://cnx.org/content/col10322/1.175
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