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Starting from F=ma, and using calculus, derive v=v₀+at and x=x₀+v₀ t+1/2 at^2.

User Amdg
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Answer:

See below.

Step-by-step explanation:

Here using F = ma , we need to derive the fire and second equation of motion.


\displaystyle \longrightarrow F = ma \dots(i)

As we know that the rate of change of velocity is called acceleration. Therefore,


\displaystyle \longrightarrow F = m(dv)/(dt)

From equation (i) we have,


\displaystyle \longrightarrow ma = m(dv)/(dt)

If the mass is constant,


\displaystyle \longrightarrow a =(dv)/(dt)\\


\displaystyle \longrightarrow dv = a.dt

On integrating both sides,


\displaystyle \longrightarrow \int dv = \int a .dt

LHS will be integrated from v₀ to v and RHS will be integrated from 0 to t , as ;


\displaystyle \longrightarrow\int^v_(v_0) dv =\int^t_0 a .dt

Here a is constant , so ;


\displaystyle \longrightarrow v|^v_(v_0)= a \int^t_0 dt\\


\displaystyle \longrightarrow v - v_0= a(t-0)

Adding v₀ both sides,


\displaystyle \longrightarrow</p><p> \underline{\underline{ v =v_0+at}}

Hence we have derived the First equation of motion.

For second , as we know that ,


\displaystyle \longrightarrow v =(dx)/(dt)\\


\displaystyle \longrightarrow dx = v.dt

Integrating both sides, we have;


\displaystyle \longrightarrow \int dx =\int v.dt\\

Putting the limits,


\displaystyle \longrightarrow \int^x_(x_0) dx =\int_0^t v.dt

From first equation,


\displaystyle \longrightarrow x|^x_(x_0)= \int^t_0 ( v_0+at).dt

Distribute ,


\displaystyle \longrightarrow x - x_0= \int^t_0 v_0dt +\int^t_0 at.dt\\


\displaystyle \longrightarrow x-x_0= v_0(t-0)+a\bigg[(t^2)/(2)\bigg]^t_0\\

Simplify,


\displaystyle \longrightarrow \underline{\underline{ x-x_0= v_0t +(1)/(2)at^2}}

Therefore we have derived the second equation of motion.

And we are done!

User SJMan
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