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Question
For motion in a straight line with constant acceleration, we derived two primary equations given by Eq. (v = u + at) and (s = ut + `1/2 xx at^2`). Using these two equations, three more equations can be derived, out of which we derived one given in Eq. (v2 = u2 + 2as). Derive the remaining two equations given below
`s = vt - 1/2 at^2 s = 1/2 (u + v)t`
In mathematics, you have learnt the formula for calculating the area of a trapezium. Using that formula, derive the second equation given above.
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Solution
The two equations can be derived using the first two equations of motion:
v = u + at
s = ut + `1/2 xx at^2`
1. Derive `s = vt - 1/2 at^2`
From the first equation:
u = v − at
Substitute this into
`s = ut + 1/2 at^2`
`s = (v - at)t + 1/2at^2`
= `vt - at^2 + 1/2 at^2`
= `vt - 1/2at^2`
Hence,
`s = vt - 1/2at^2`
2. Derive `s = 1/2 (u + v)t`
Using the trapezium area method:
Draw a velocity-time graph.
Initial velocity = u
Final velocity = v
Time = t
The graph forms a trapezium.
The area under the velocity-time graph gives the displacement.
Area of a trapezium:
Area = `1/2 xx ("sum of parallel sides") xx ("height")`
Here,
Parallel sides = u and v
Height = t
Therefore,
`s = 1/2 (u + v) xx t`
= `1/2 (u + v)t`
Hence,
`s = 1/2 (u + v)t`
