Core Practical: Using an Oscilloscope (Edexcel IGCSE Physics (Modular))
Revision Note
Written by: Ashika
Reviewed by: Caroline Carroll
Core practical 7: using an oscilloscope
Aims of the experiment
The aim of this experiment is to investigate the frequency of a sound wave using an oscilloscope
Variables
Independent variable = Tuning forks of different frequencies
Dependent variable = Time period
Equipment
Equipment List
Equipment | Purpose |
|---|---|
Tuning fork | To generate sound waves of different frequencies |
Microphone | To detect sound waves from the tuning fork |
Oscilloscope | To display the sound waves electronically |
Wires | To connect the microphone to the oscilloscope |
Method
A diagram of the oscilloscope and tuning fork set up
Measuring the frequency of a sound wave using an oscilloscope
Connect the microphone to the oscilloscope as shown in the image above
Test the microphone displays a signal by humming
Adjust the time base of the oscilloscope until the signal fits on the screen - ensure that multiple complete waves can be seen
Strike the tuning fork on the edge of a hard surface to generate sound waves of a pure frequency
Hold the tuning fork near to the microphone and observe the sound wave on the oscilloscope screen
Freeze the image on the oscilloscope screen, or take a picture of it
Measure and record the time period of the wave signal on the screen by counting the number of divisions for one complete wave cycle
Repeat steps 4-6 for a variety of tuning forks
Results
An example results table of the oscilloscope display
Analysis of results
To convert the time period of the wave from the number of divisions into seconds, use the scale of the time base. For example:
The time base is usually measured in units of ms/cm (milliseconds per centimetre)
This would mean a wave with a time base of 4 cm has a time period of 4 ms
To calculate the frequency of the sound waves produced by the tuning forks, use the equation:
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This is explained in more detail in the revision note The wave equation
Evaluating the experiment
Systematic Errors:
Ensure the scale of the time base is accounted for correctly
The scale is likely to be small (e.g. milliseconds) so ensure this is taken into account when calculating the time period
Random Errors:
A cause of random error in this experiment is noise in the environment, so ensure it is carried out in a quiet location
Examiner Tips and Tricks
You have a lot of core practicals to know about. Make sure you don't get those relating to sound confused with each other. To succeed in questions about this particular practical you need to know exactly how an oscilloscope works. To do that revise this in the revision note about Sound & oscilloscopes.
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