In mechanics, the derivative of the position vs. time graph of an object is equal to the velocity of the object. In the International System of Units, the position of the moving object is measured in meters relative to the origin, while the time is measured in seconds. Placing position on the y-axis and time on the x-axis, the slope of the curve is given by:
v=
| \Deltay | |
| \Deltax |
=
| \Deltas | |
| \Deltat |
.
Here
s
t
{\Deltas}
{ds}
{\Deltat}
{dt}
t
A similar fact also holds true for the velocity vs. time graph. The slope of a velocity vs. time graph is acceleration, this time, placing velocity on the y-axis and time on the x-axis. Again the slope of a line is change in
y
x
a=
| \Deltay | |
| \Deltax |
=
| \Deltav | |
| \Deltat |
where
v
t
\begin{matrix}
| dv | |
| dt |
\end{matrix}
t
| m/s2 |
Since the velocity of the object is the derivative of the position graph, the area under the line in the velocity vs. time graph is the displacement of the object. (Velocity is on the y-axis and time on the x-axis. Multiplying the velocity by the time, the time cancels out, and only displacement remains.)
The same multiplication rule holds true for acceleration vs. time graphs. When acceleration is multiplied
The expressions given above apply only when the rate of change is constant or when only the average (mean) rate of change is required. If the velocity or positions change non-linearly over time, such as in the example shown in the figure, then differentiation provides the correct solution. Differentiation reduces the time-spans used above to be extremely small (infinitesimal) and gives a velocity or acceleration at each point on the graph rather than between a start and end point. The derivative forms of the above equations are
v=
| ds | |
| dt |
,
a=
| dv | |
| dt |
.
Since acceleration differentiates the expression involving position, it can be rewritten as a second derivative with respect to time:
a=
| d2s | |
| dt2 |
.
Since, for the purposes of mechanics such as this, integration is the opposite of differentiation, it is also possible to express position as a function of velocity and velocity as a function of acceleration. The process of determining the area under the curve, as described above, can give the displacement and change in velocity over particular time intervals by using definite integrals:
s(t2)-s(t1)=
| t2 | |
| \int | |
| t1 |
{v}dt,
v(t2)-v(t1)=
| t2 | |
| \int | |
| t1 |
{a}dt.