WORKED EXAMPLES

1) Leaving a bus stop, a bus reaches a velocity of $8.0\,m\,{s^{ - 1}}$ after $10 s$. Calculate the acceleration of the bus.
Step 1: Note that the bus’s initial velocity is $0\,m\,{s^{ - 1}}$.
Therefore:
${\rm{change in velocity}}\,\Delta v = (8.0 - 0)\,m\,{s^{ - 1}}$
$time\,taken\,\Delta t = 10s$
Step 2: Substitute these values in the equation for acceleration:
$\begin{array}{l}
acceleration = \frac{{\Delta v}}{{\Delta t}}\\
 = \frac{{8.0}}{{10}}\\
 = 0.80\,m\,{s^{ - 2}}
\end{array}$
2) A sprinter starting from rest has an acceleration of $5.0\,m\,{s^{ - 1}}$ during the first $2.0 s$ of a race.
Calculate her velocity after $2.0 s$.
Step 1: Rearranging the equation $a = \frac{{v - u}}{t}$ gives:
$v = u + at$
Step 2: Substituting the values and calculating gives:
$v = 0 + (5.0 \times 2.0) = 10\,m\,{s^{ - 1}}$
3) A train slows down from $60\,m\,{s^{ - 1}}$ to $20\,m\,{s^{ - 1}}$ in $50 s$. Calculate the magnitude of the deceleration
of the train.
Step 1: Write what you know:
$u = 60\,m\,{s^{ - 1}}\,\,\,\,\,\,\,\,\,v = 20\,m\,{s^{ - 1}}\,\,\,\,\,\,\,\,\,t = 50s\,$
Step 2: Take care! Here the train’s final velocity is less than its initial velocity. To ensure that we arrive at the correct answer, we will use the alternative form of the equation to calculate a.
$\begin{array}{l}
a = \frac{{v - u}}{t}\\
 = \frac{{20 - 60}}{{50}} = \frac{{ - 40}}{{50}}\\
 =  - 0.80\,m\,{s^{ - 2}}
\end{array}$
The minus sign (negative acceleration) indicates that the train is slowing down. It is decelerating. The magnitude of the deceleration is $0.8\,m\,{s^{ - 2}}$.