16.5 Energy and the simple harmonic oscillator  (Page 2/2)

Determine the maximum speed of an oscillating system: a bumpy road

Suppose that a car is 900 kg and has a suspension system that has a force constant $k=6\text{.}\text{53}\times {\text{10}}^4\text{N/m}$ . The car hits a bump and bounces with an amplitude of 0.100 m. What is its maximum vertical velocity if you assume no damping occurs?

Strategy

We can use the expression for $v_{\text{max}}$ given in $v_{\text{max}}=\sqrt{\frac{k}{m}}X$ to determine the maximum vertical velocity. The variables $m$ and $k$ are given in the problem statement, and the maximum displacement $X$ is 0.100 m.

Solution

1. Identify known.
2. Substitute known values into $v_{\text{max}}=\sqrt{\frac{k}{m}}X$ :
   $v_{\text{max}}=\sqrt{\frac{6\text{.}\text{53}\times {\text{10}}^4\text{N/m}}{\text{900}\text{kg}}}\mathrm{(0}\text{.}\text{100}\text{m)}.$
3. Calculate to find $v_{\text{max}}\text{= 0.852 m/s}.$

Discussion

This answer seems reasonable for a bouncing car. There are other ways to use conservation of energy to find $v_{\text{max}}$ . We could use it directly, as was done in the example featured in Hooke’s Law: Stress and Strain Revisited .

The small vertical displacement $y$ of an oscillating simple pendulum, starting from its equilibrium position, is given as

where $a$ is the amplitude, $\omega$ is the angular velocity and $t$ is the time taken. Substituting $\omega =\frac{\mathrm{2\pi }}{T}$ , we have

Thus, the displacement of pendulum is a function of time as shown above.

Also the velocity of the pendulum is given by

so the motion of the pendulum is a function of time.