The Doppler Effect
- When a source of sound, such as the whistle of a train or the siren of an ambulance, moves away from an observer:
- It appears to decrease in frequency, i.e. it sounds lower in pitch
- The source of the sound however, remains at a constant frequency
- This frequency change due to the relative motion between a source of sound or light and an observer is known as the Doppler effect (or Doppler shift)
- When the observer and the source of sound (e.g. ambulance siren) are both stationary:
- The waves appear to remain at the same frequency for both the observer and the source
- When the observer and the source of sound (e.g. ambulance siren) are moving relative to each other
- The waves appear to have a different frequency for both the observer and the source
Stationary source and observer. The wavelength of the waves are the same for both observers
- When the source starts to move towards the observer, the wavelength of the waves is shortened
- The sound, therefore, appears at a higher frequency to the observer
Moving source at speed vs and stationary observer. The waves are closer together closer near the stationary observer
- Notice how the waves are closer together between the source and the observer compared to point P and the source
- This also works if the source is moving away from the observer
- If the observer was at point P instead, they would hear the sound at a lower frequency due to the wavelength of the waves broadening
- The frequency is increased when the source is moving towards the observer
- The frequency is decreased when the source is moving away from the observer
- The same phenomena occurs for electromagnetic waves, such as light
- Waves moving away from the observer are red-shifted
- Their wavelengths shift to the red end of the electromagnetic spectrum
- This is equivalent to sound waves appearing at a lower frequency to the observer
- Waves moving towards the observer are blue-shifted
- Their wavelengths shift to the blue end of the electromagnetic spectrum
- This is equivalent to sound waves appearing at a higher frequency to the observer
- This is because red light has a longer wavelength than blue light
Red shift and blue shift for electromagnetic waves
Worked example
A cyclist rides a bike ringing their bell past a stationary observer.
Which row correctly describes the Doppler shift caused by the sound of the bell?
Answer: D
- If the cyclist is riding past the observer, the wavelength of sound waves are going to become longer
- This rules out options A and C
- A longer wavelength means a lower frequency (from )
- Lower frequency creates a lower sound pitch
- Therefore, the answer is row D
Exam Tip
The relationship between frequency and wavelength is determined by the wave equation, which is given in your data booklet. The speed v of the wave does not change.