Why Does Fundamental Freq Have Largest Amplitude?

In summary, the fundamental frequency usually has the biggest amplitude due to the shape of the string when plucked and the Fourier Transform of the initial shape. However, there are exceptions to this, such as asymmetrical plucking or placing a dampening finger on the string. The lower frequency harmonics typically have bigger amplitudes because of the basic equation for frequency, where the stiffness increases as the frequency increases. Standing waves are produced because the anti-phase condition only occurs at the termination, allowing for superposition of waves to create the standing wave pattern.
  • #1
Jimmy87
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Please could somebody explain why the fundamental frequency always has the biggest amplitude in comparison to the rest of the harmonics?
 
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  • #2
The reason that the fundamental usually dominates will be because of the shape of the string when plucked - the Fourier Transform of the initial shape will normally have a maximum at the fundamental mode. But it doesn't necessarily. You can excite a string with asymmetrical plucking at 1/4 and 3/4 along its length and get the first overtone dominating with no significant fundamental OR by placing a dampening finger, half way along a guitar string (or other places) you can get higher overtones (not exact harmonics unless the medium is ideal - but referred to by guitarists as harmonics - but they're not Physicists so it's OK for them)
 
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  • #3
The fundamental doesn't always have the biggest amplitude.

For example see Fig 2 (page 6 of the PDF) in http://www.haskins.yale.edu/sr/SR111/sr111_23.pdf

Several counter-examples of organ reed pipes here: http://www.pykett.org.uk/reedpipetones.htm - e.g Fig 9 the 5th harmonic is loudest, followed by the 3rd.

The reason why lower frequency harmonics usually have bigger amplitudes than higher, is because of the basic equation for the frequency of a vibrating object, ##f = (1/2\pi)\sqrt{K/M}## where K and M measure the stiffness and mass of whatever is vibrating. Often, the amount of vibrating mass is about the same for all the harmonics, and the stiffness increases as the frequency increases. For a fixed amount of forrce, you get a bigger amplitude of vibration from a low stiffness (because displacement = stiffness / force), and so the low frequency harmonics tend to have bigger amplitudes.
 
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  • #4
Don't they die out??

Two waves traveling in opposite direction should die out according to super position principle (Zero amplitude). Then how standing waves are produced? Is this not a contradiction? Please help. thank you.
 
  • #5
pscience said:
Two waves traveling in opposite direction should die out according to super position principle (Zero amplitude). Then how standing waves are produced? Is this not a contradiction? Please help. thank you.

The anti- phase condition only occurs right at the termination. The relative phases of incident and reflected wave vary with distance and superposition produces the standing wave.
 
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What is the fundamental frequency?

The fundamental frequency is the lowest frequency of a periodic waveform. It is also known as the first harmonic and determines the pitch of a sound.

Why does the fundamental frequency have the largest amplitude?

The fundamental frequency has the largest amplitude because it is the main frequency of a sound and contains the most energy. It is the foundation of the sound and all other frequencies are harmonics of the fundamental frequency.

How is the fundamental frequency determined?

The fundamental frequency is determined by the physical characteristics of the sound source, such as the length and tension of a string or the size and shape of a vibrating object. It can also be mathematically calculated by dividing the speed of sound by the wavelength of the sound wave.

Can the fundamental frequency change?

Yes, the fundamental frequency can change depending on the properties of the sound source. For example, the fundamental frequency of a guitar string can be changed by altering its length or tension. Additionally, the fundamental frequency of a sound can be changed by using effects or filters.

What is the relationship between fundamental frequency and harmonics?

Harmonics are integer multiples of the fundamental frequency. This means that the second harmonic is twice the frequency of the fundamental, the third harmonic is three times the frequency, and so on. The fundamental frequency and harmonics create a series of related frequencies that make up a sound wave.

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