Amplitude, Period and Frequency
Here is a ball moving back and forth with simple harmonic motion (SHM):
Its position \(x\) as a function of time \(t\) is:
\(x (t) = A \cdot \cos \Bigl( \frac {2\cdot \pi \cdot t}{T} \Bigr)\)
where \(A\) is the amplitude of motion: the distance from the centre of motion to either extreme
\(T\) is the period of motion: the time for one complete cycle of the motion.
Questions
Which ball has a larger amplitude?
Ball A or Ball B
Ball A - Correct!
Ball B - No. That is not correct
Which ball has a longer period?
Ball A or Ball B
Ball A - Correct!
Ball B - No. That is not correct
What is the period of Ball B?
A) 4.0s
B) 8.0s
C) 12 s
D) 16s
A) 4.0s - No. The period is the time for one full oscillation.
B) 8.0s - No. The period is the time for one full oscillation.
C) 12 s - Correct!
D) 16s - No. The period is the time for one full oscillation.
The frequency of motion, \(f\), is the rate of repetition of the motion -- the number of cycles per unit time. There is a simple relation between frequency and period: \(f = T^{-1}\)
What is the frequency of ball B (recall, the period is 12s)?
A) 0.0625 Hz
B) 0.0833 Hz
C) 0.125 Hz
D) 0.250 Hz
A) 0.0625 Hz - No. Remember \(f = 1/T\)
B) 0.0833 Hz - Correct!
C) 0.125 Hz - No. Remember \(f = 1/T\)
D) 0.250 Hz - No. Remember \(f = 1/T\)
Angular frequency is the rotational analogy to frequency. Represented as , and is the rate of change of an angle when something is moving in a circular orbit. This is the usual frequency (measured in cycles per second), converted to radians per second. That is \(\omega = 2\pi / T = 2\pi f\)
Which ball has the larger angular frequency?
Ball A or Ball B
Ball A - No. \(\omega\) is proportional to \(f\)
Ball B - Correct!
What is ball B's angular frequency?
A) \(0.125\pi \; \mathrm {rad} \; s^{-1}\)
B) \(0.167\pi \; \mathrm {rad} \; s^{-1}\)
C) \(0.250\pi \; \mathrm {rad} \; s^{-1}\)
D) \(0.500\pi \; \mathrm {rad} \; s^{-1}\)
A) \(0.125\pi \; \mathrm {rad} \; s^{-1}\) - No. \(\omega = 2pf\)
B) \(0.167\pi \; \mathrm {rad} \; s^{-1}\) - Correct!
C) \(0.250\pi \; \mathrm {rad} \; s^{-1}\) - No. \(\omega = 2pf\)
D) \(0.500\pi \; \mathrm {rad} \; s^{-1}\) - No. \(\omega = 2pf\)
From this graph, find the following:
| 1. Amplitude (\(A\)) | 2. period (\(T\)) | 3. frequency (\(f\)) | 4. angular frequency (\(\omega\)) |
|---|---|---|---|
| A) 20 cm | A) 0.20 s | A) 0.20 Hz | A) \(0.20 \pi \; rad \; s^{-1}\) |
| B) 1.0 cm | B) 1.0 s | B) 1.0 Hz | B) \(1.0 \pi \; rad \; s^{-1}\) |
| C) 5.0 cm | C) 5.0 s | C) 5.0 Hz | C) \(5.0 \pi \; rad \; s^{-1}\) |
| D) 10 cm | D) 10 s | D) 10 Hz | D) \(10 \pi \; rad \; s^{-1}\) |
- amplitude (\(A\)):
A) 20 cm - No. It is not the distance from a crest to a trough.
B) 1.0 cm - No. That is not correct.
C) 5.0 cm - No. That is not correct.
D) 10 cm - Correct!
- period (\(T\)):
A) 0.20 s - Correct!
B) 1.0 s - No. The period is the time for one full oscillation.
C) 5.0 s - No. The period is the time for one full oscillation.
D) 10 s - No. The period is the time for one full oscillation.
- frequency (\(f\)):
A) 0.20 Hz - No. The frequency is \(1/T\)
B) 1.0 Hz - No. The frequency is \(1/T\)
C) 5.0 Hz - Correct!
D) 10 Hz - No. The frequency is \(1/T\)
- angular frequency (\(\omega\)):
A) \(0.20 \pi \; rad \; s^{-1}\) - No. \(\omega = 2\pi f\)
B) \(1.0 \pi \; rad \; s^{-1}\) - No. \(\omega = 2\pi f\)
C) \(5.0 \pi \; rad \; s^{-1}\) - No. \(\omega = 2\pi f\)
D) \(10 \pi \; rad \; s^{-1}\) - Correct!