Acceleration is Second Derivative of Displacement with respect to Time

Theorem
The acceleration of a body $M$ is the second derivative of the displacement of $M$ from a given point of reference with respect to time:


 * $\mathbf a = \dfrac {\mathrm d^2 \mathrm s}{\mathrm d t^2}$

Proof
By definition, the acceleration of a body $M$ is defined as the first derivative of the velocity of $M$ relative to a given point of reference with respect to time:


 * $\mathbf a = \dfrac {\mathrm d \mathrm v}{\mathrm d t}$

Also by definition, the velocity of $M$ is defined as the first derivative of the displacement of $M$ from a given point of reference with respect to time:


 * $\mathbf v = \dfrac {\mathrm d \mathrm s}{\mathrm d t}$

That is:


 * $\mathbf a = \dfrac {\mathrm d}{\mathrm d t} \left({\dfrac {\mathrm d \mathrm s}{\mathrm d t}}\right)$

Hence the result by definition of the second derivative.