Measuring the Speed of Waves (OCR Gateway GCSE Physics)

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Measuring the Speed of Waves

  • Sound waves in air are a type of longitudinal wave
    • The speed of sound can be measured

Experiments to Determine the Speed of Sound

  • There are several experiments that can be carried out to determine the speed of sound
  • Three methods are described below
    • The apparatus for each experiment is given in bold

Method 1: Measuring Sound Between Two Points

sound-method-1, IGCSE & GCSE Physics revision notes

Measuring the speed of sound directly between two points

  1. Two people stand a distance of around 100 m apart
  2. The distance between them is measured using a trundle wheel
  3. One person has two wooden blocks, which they bang together above their head
  4. The second person has a stopwatch which they start when they see the first person banging the blocks together and stops when they hear the sound
  5. This is then repeated several times and an average value is taken for the time
  6. The speed of sound can then be calculated using the equation:

Speed of sound equation (2), IGCSE & GCSE Physics revision notes

Method 2: Using Echoes

sound-method-2, IGCSE & GCSE Physics revision notes

Measuring the speed of sound using echoes

  1. A person stands about 50 m away from a wall (or cliff) using a trundle wheel to measure this distance
  2. The person claps two wooden blocks together and listens for the echo
  3. The person then starts to clap the blocks together repeatedly, in rhythm with the echoes
  4. A second person has a stopwatch and starts timing when they hear one of the claps and stops timing 20 claps later
  5. The process is then repeated and an average time calculated
  6. The distance travelled by the sound between each clap and echo will be (2 × 50) m
  7. The total distance travelled by sound during the 20 claps will be (20 × 2 × 50) m
  8. The speed of sound can be calculated from this distance and the time using the equation:

Speed of sound equation (3), IGCSE & GCSE Physics revision notes

Method 3: Using an Oscilloscope

sound-method-3, IGCSE & GCSE Physics revision notes

Measuring the speed of sound using an oscilloscope

  1. Two microphones are connected to an oscilloscope and placed about 5 m apart using a tape measure to measure the distance
  2. The oscilloscope is set up so that it triggers when the first microphone detects a sound, and the time base is adjusted so that the sound arriving at both microphones can be seen on the screen
  3. Two wooden blocks are used to make a large clap next to the first microphone
  4. The oscilloscope is then used to determine the time at which the clap reaches each microphone and the time difference between them
  5. This is repeated several times and an average time difference calculated
  6. The speed can then be calculated using the equation:

Speed of sound equation (1), IGCSE & GCSE Physics revision notes

Measuring Wave Speed in Water

  • Ripples on water surfaces are used to model transverse waves
    • The speed of these water waves can be measured

Creating ripples in water

  1. Choose a calm flat water surface such as a lake or a swimming pool
  2. Two people stand a few metres apart using a tape measure to measure this distance
  3. One person counts down from three and then disturbs the water surface (using their hand, for example) to create a ripple
  4. The second person then starts a stopwatch to time how long it takes for the first ripple to get to them
  5. The experiment is then repeated 10 times and an average value for the time is calculated
  6. The average time and distance can then be used to calculate the wave speed using the equation:

Speed distance equation, IGCSE & GCSE Physics revision notes

Worked example

Small water waves are created in a ripple tank by a wooden bar. The wooden bar vibrates up and down hitting the surface of the water. The diagram below shows a cross-section of the ripple tank and water.Which letter shows:

   a) The amplitude of a water wave?

   b) The wavelength of the water wave?

Part (a)

Step 1: Recall the definition of amplitude

    • Amplitude = The distance from the undisturbed position to the peak or trough of a wave

Step 2: Mark the undisturbed position on the wave

    • This is the centre of the wave

WE Ripple Tank Ans 1, downloadable IGCSE & GCSE Physics revision notes

Step 3: Identify the arrow between the undisturbed position and a peak

    • The amplitude is arrow D

Part (b)

Step 1: Recall the definition of wavelength

    • Wavelength = The distance from one point on the wave to the same point on the next wave

Step 2: Draw lines on each horizontal arrow

    • This helps to identify the points on the wave the arrows are referring to

WE Ripple Tank Ans 2, downloadable IGCSE & GCSE Physics revision notes

Step 3: Identify the arrow between two of the same points on the wave

    • The wavelength is arrow C

Examiner Tip

When you are 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:
    • Method 3 is the most accurate because the timing is done automatically
    • Method 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 air
  • This means that the variation due to the stopwatch readings has a big influence on the results and they may not be reliable

Evidence for Energy Transfer

  • Waves transfer energy and information
  • Waves are described as oscillations or vibrations about a fixed point
    • For example, ripples cause particles of water to oscillate up and down
    • Sound waves cause particles of air to vibrate back and forth

  • In all cases, waves transfer energy without transferring matter
    • For water waves, this means it is the wave and not the water (the matter) itself that travels
    • For sound waves, this means it is the wave and not the air molecules (the matter) itself that travels
  • Objects floating on water provide evidence that waves only transfer energy and not matter

Worked example

The diagram below shows a toy duck bobbing up and down on top of the surface of some water, as waves pass it underneath.Explain how the toy duck demonstrates that waves do not transfer matter.

Step 1: Identify the type of wave

    • The type of wave on the surface of a body of water is a transverse wave
    • This is because the duck is moving perpendicular to the direction of the wave

Step 2: Describe the motion of the toy duck

    • The plastic duck moves up and down but does not travel with the wave

Step 3: Explain how this motion demonstrates that waves do not transfer matter

    • Both transverse and longitudinal waves transfer energy, but not the particles of the medium
    • This means when a wave travels between two points, no matter actually travels with it, the points on the wave just vibrate back and forth about fixed positions
    • Objects floating on the water simply bob up and down when waves pass under them, demonstrating that there is no movement of matter in the direction of the wave, only energy

Examiner Tip

There is a key distinction between the wave itself and the particles in the wave. The wave causes the particles to move, but the particles themselves are not the wave, since they are not transferring energy, which a wave does.

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Ashika

Author: Ashika

Expertise: Physics Project Lead

Ashika graduated with a first-class Physics degree from Manchester University and, having worked as a software engineer, focused on Physics education, creating engaging content to help students across all levels. Now an experienced GCSE and A Level Physics and Maths tutor, Ashika helps to grow and improve our Physics resources.