Suppose for a sound wave in air, if its amplitude increases, that means the displacement of particles will increase from their undisturbed position.

Shouldn't that means larger compression and rarefaction, and thus, increased wavelength?

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acquavaa t1_jd7001g wrote on March 22, 2023 at 8:27 AM

If you pull a rubber band tighter, it snaps back faster. Same idea here. Whatever the equilibrating force is that is involved with the oscillation, it’s stronger if you increase the displacement from equilibrium. That stronger force causes the wave particle velocity change to keep pace with the peak displacement change, and so the period/wavelength is unchanged.

El_Sephiroth t1_jd8g124 wrote on March 22, 2023 at 4:11 PM

The analogy really ain't that good. Try with a water wave or a guitar string. If you pull a guitar string further the vibration it has gets a bigger amplitude but its mechanical resistance and border limitations won't change. This means the string will move faster or slower but it will oscillate at the same frequency.

Since the frequency is the same, the note is the same. But since amplitude varies, the sound is more intense.

Coomb t1_jd8p3ae wrote on March 22, 2023 at 5:07 PM

Are you trying to draw a distinction here somehow between the wave dynamics in a guitar string and the dynamics in a rubber band that's pulled taut enough to support oscillation? They're the same. A rubber bands stretched taut between two supports and then plucked is exactly the same as a guitar string except that it's far more compliant. Whatever reasoning explains why a guitar string still makes the same sound even if you pluck it harder is identical to the example already given.

[deleted] t1_jd8pnqm wrote on March 22, 2023 at 5:11 PM

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themajorhavok t1_jd705yk wrote on March 22, 2023 at 8:29 AM

The wavelength is determined by the amount of time between peaks or valleys in the pressure, not the amplitude of them. Said differently, the speed of sound is nearly independent of the pressure, so if the time is known, then the distance can be solved for, as simply wavelength (meters) = speed of sound (meters / second) divided by frequency (Hz or cycles / second). In other words, the wavelength depends only on the speed of sound and the frequency, but not the amplitude.

ReindeerBrief561 t1_jd7nm1c wrote on March 22, 2023 at 12:57 PM

Brilliant. I love learning things I wasn’t even looking for. Absolutely brilliant. Thank you

[deleted] t1_jd71nro wrote on March 22, 2023 at 8:51 AM

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[deleted] t1_jd72sjq wrote on March 22, 2023 at 9:08 AM

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[deleted] t1_jddlqrh wrote on March 23, 2023 at 5:10 PM

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