Asymmetry in the Doppler Effect for sound

AI Thread Summary
The discussion centers on the asymmetry observed in the Doppler Effect for sound compared to light. When an observer moves towards a sound source, they encounter more wavelengths, increasing the perceived frequency, while if the source moves towards the observer, the wavelengths are compressed, also increasing frequency. The key difference arises from sound requiring a medium for propagation, making the scenarios asymmetric; if the observer moves faster than sound, they may not hear the source at all, while the source can still emit sound towards a stationary observer. In contrast, light does not rely on a medium, allowing for symmetrical frequency shifts regardless of relative motion. This fundamental difference in propagation leads to distinct behaviors in how sound and light frequencies are perceived.
Cookiey
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I'm a bit confused about this. So say there's an observer and a source of sound. If the observer moves towards the source of sound, the frequency seems to increase because he encounters more wavelengths in the same amount of time.

In a second case, if the source moved towards the observer, the wavelengths get sort of 'bunched up' and it makes the effective wavelength shorter, again increasing the frequency.

But even if their relative velocities are the same in both cases, the perceived frequency is different. My textbook (and the internet sources I looked at) didnt really explain this, though one place off handedly said it's because sound only propagates in a medium.

I get how it is numerically different. Can someone help me understand kind of quantitatively how it's different? And why the same doesn't occur for light waves (where both cases would give the same answer?)

Thanks for your help and time!
 
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Why do you expect a symmetry? The sound travels in one direction through a medium, the situation is not symmetric.

Light in vacuum does not have a medium which would fix its relative speed. Light in air is similar to light in vacuum, but if you are fast enough it will show an asymmetry there as well.
 
mfb said:
Why do you expect a symmetry? The sound travels in one direction through a medium, the situation is not symmetric.

Light in vacuum does not have a medium which would fix its relative speed. Light in air is similar to light in vacuum, but if you are fast enough it will show an asymmetry there as well.

I don't understand why the presence of the medium makes it unsymmetric. Why isn't the speed perceived by an observer the only thing that matters?
 
Cookiey said:
I don't understand why the presence of the medium makes it unsymmetric. Why isn't the speed perceived by an observer the only thing that matters?

Consider the situation where the observer is moving away from the source. And, assume, faster than the speed of sound. No sound from the source reaches the observer.

But, if the source is moving away from the observer faster than the speed of sound, then the sound still travels towards the observer at the usual speed.

That's perhaps the ultimate asymmetry of the situation for sound.
 
PeroK said:
Consider the situation where the observer is moving away from the source. And, assume, faster than the speed of sound. No sound from the source reaches the observer.

The observer would still hear sound from the source, but in reverse order. An observer moving away from the source at twice the speed of sound would hear a musical piece in correct time and tune, but backwards.
 
Cookiey said:
Thanks for the link! I'm not done reading it yet, but still thanks.
You are welcome. It is one of my favorites, and I think addresses your concern pretty well.
 
Cookiey said:
I get how it is numerically different. Can someone help me understand kind of quantitatively how it's different?
Imagine you want to achieve infinite Doppler shift:
- How fast must the source move through the medium to compress the distance between wave crests to zero?
- How fast must the receiver move through uncompressed wave crest, to collapse the encounter period to zero?
 

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