Learn the Derivation of Motion Equations with Expert Guidance

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SUMMARY

The motion equations \(s = ut + 0.5at^2\) and \(v^2 = u^2 + 2as\) are derived from the definition of acceleration as the second derivative of position with respect to time. When acceleration is constant, integration yields the velocity equation \(v = at + v_0\) and subsequently the position equation \(x(t) = 0.5at^2 + v_0t\). The second equation can be derived by manipulating the position and velocity equations, utilizing the definition of average velocity and substituting terms accordingly.

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Omar
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Hello,

I'm new to the forums. This is my first thread here. I just wanted help in knowing where the motion equations (s=ut+0.5at^2, and v^2=u^2+2as) are derived from?

Thanks in advance..
 
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They are a consequence of the definition of acceleration as the second derivative of position (as a function of time). When the acceleration is constant, it's easy to find the velocity by doing a very simple integration.

x''(t)=a

x'(t)=at+v_0

The constant term is the velocity at time t=0. If we integrate this, we find the position as a function of time.

x(t)=\frac{1}{2}at^2+v_0t

I could have added a new constant term that would have represented the position at time t=0, but this is usually chosen to be zero.

The second equation in your post can be derived from the velocity and position equations above.
 
fundamentally they were derived from equation of acceleration.

:)
 
start off with the definition of acceleration...
a = \frac{v_f-v_0}{t}
v_f = v_0 + at

Definition of average velocity...
v_{ave} = d/t
d = \frac{v_f + v_0}{2}t

substitute...

d = \frac{(v_0+at) + v_0}{2}t
d = \frac{2v_0 + at}{2}t
d = v_0t + \frac{1}{2}at^2

For the second equation...it just a lot of manipulation of the equation above and a substitution of the definition of acceleration.
 

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