Measuring the Speed of Sound (Cambridge (CIE) IGCSE Physics)
Revision Note
Written by: Katie M
Reviewed by: Caroline Carroll
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Speed of sound in air
The speed of sound in air varies from 330 – 350 m/s
The higher the air temperature, the greater the speed of sound
Speed of sound in materials
Extended tier only
Sound travels at different speeds in different mediums:
Sound travels fastest in solids
Sound travels slowest in gases
Sound travels at:
Around 1500 m/s in liquids
Around 5000 m/s in solids
Measuring the speed of sound
Equipment
Equipment list
Equipment | Purpose |
|---|---|
Trundle Wheel | To measure the distance travelled by the sound waves |
Wooden Blocks | To create a sound when banged together |
Stopwatch | To time how long it takes the sound waves to travel |
Oscilloscope | To display the sound wave electronically |
Microphones x2 | To detect sound waves and turn them into an electrical signal |
Tape Measure | To measure the distance between microphones |
Resolution of measuring equipment:
Trundle wheel = 0.01 m
Tape measure = 0.1 cm
Stopwatch = 0.01 s
Experiment 1: measuring the speed of sound between two points
This experiment aims to measure the speed of sound in air between two points
Variables
Independent variable = Distance
Dependent variable = Time
Control variables:
Same location to carry out the experiment
Method
Measuring the speed of sound in air
Measuring the speed of sound directly between two points
Use the trundle wheel to measure a distance of 100 m between two people
One of the people should have two wooden blocks, which they will bang together above their head to generate sound waves
The second person should have a stopwatch which they start when they see the first person banging the blocks together and stop when they hear the sound
This should be repeated several times and an average taken for the time travelled by the sound waves
Repeat this experiment for various distances, e.g. 120 m, 140 m, 160 m, 180 m
Results
An example results table for the speed of sound in air
Distance / m | Time 1 / s | Time 2 / s | Time 3 / s | Average time / s |
|---|---|---|---|---|
100 |
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120 |
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140 |
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160 |
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180 |
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Analysis of results
The speed of sound can be calculated using the equation:
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The speed of sound in the air should work out to be about 340 m/s
Experiment 2: measuring the speed of sound with oscilloscopes
This experiment aims to measure the speed of sound in air between two points using an oscilloscope
Variables
Independent variable = Distance
Dependent variable = Time
Control variables:
Same location to carry out the experiment
Same set of microphones for each trial
Method
Measuring the speed of sound with an oscilloscope
Measuring the speed of sound using an oscilloscope
Connect two microphones to an oscilloscope
Place them about 2 m apart using a tape measure to measure the distance between them
Set up the oscilloscope so that it triggers when the first microphone detects a sound, and adjust the time base so that the sound arriving at both microphones can be seen on the screen
Make a large clap using the two wooden blocks next to the first microphone
Use the oscilloscope to determine the time at which the clap reaches each microphone and the time difference between them
Repeat this experiment for several distances, e.g. 2 m, 2.5 m, 3 m, 3.5 m
Results
An example results table for obtaining the speed of sound using an oscilloscope
Distance / m | Time 1 / s | Time 2 / s | Time 3 / s | Average time / s |
|---|---|---|---|---|
2.0 |
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2.5 |
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3.0 |
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3.5 |
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4.0 |
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Analysis of results
The speed of sound can be calculated using the equation:
The speed of sound in the air should work out to be about 340 m/s
Evaluating the experiments
Systematic Errors:
In experiment 2, 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 speed
Random errors:
The main cause of error in experiment 1 is the measurement of time
Ensure to take repeat readings when timing intervals and calculate an average to keep this error to a minimum
Maximise the distance between the two people where possible. This will reduce the error in measurements of time because the time taken by the sound waves to travel will be greater
Examiner Tips and Tricks
When answering questions about methods to measure waves, the question could ask you to comment on the accuracy of the measurements.
In the case of measuring the speed of sound:
Experiment 2 is the most accurate because the timing is done automatically
Experiment 1 is the least accurate because the time interval is very short
Whilst this may not be too important when giving a method, you should be able to explain why each method is accurate or inaccurate and suggest ways of making them better (use bigger distances)
For example, if a manual stopwatch is being used there could be variation in the time measured which can be up to 0.2 seconds due to a person's reaction time
The time interval could be as little as 0.3 seconds for sound travelling in the air
This means that the variation due to the stopwatch readings has a big influence on the results and they may not be reliable
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