Why does the amplitude of a loudspeaker cone change with frequency?

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The amplitude of a loudspeaker cone changes with frequency due to the relationship between inductive reactance and current flow. As frequency increases, inductive reactance rises, opposing current and affecting the magnetic force that drives the cone. This results in a decrease in the cone's displacement because the mass of the cone must be accelerated by the magnetic force. Additionally, mechanical resonances can impact the efficiency of the cone's movement at different frequencies. Overall, the interplay of these factors leads to a complex relationship between frequency and amplitude in loudspeakers.
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AA loud speaker cone is connected to a AC signal genetator.When the frequency of the signal genetor is alterned the amplitude of the cone changes.why?
My working:
As the frequency increases the amplitude decreases because there is less change in the magnetic flux and vice versia...I am a bit confused about the relationship between the amplitude and frequency...

can you please give me some scientific evidence to lead me in the correct path.Any help would highly be appriciated
 
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saltrock said:
AA loud speaker cone is connected to a AC signal genetator.When the frequency of the signal genetor is alterned the amplitude of the cone changes.why?
In a loud speaker, current passes through a coil. As the frequency increases, the inductive reactance increases, which opposes current flow (when frequency decreases, reactance decreases, thereby reducing opposition to current). This change in current would have a proportionate change on the magnetic force driving the cone, thereby chaning the amplitude (distance the cone moves per vibration period (T=1/f)).

AM
 
Also, mechanical resonances, often represented by Bessel functions, vary (nonlinearly?) the efficiency of the cone surface with repect to frequency.
 
Andrew Mason said:
In a loud speaker, current passes through a coil. As the frequency increases, the inductive reactance increases...
That's true to a slight extent, but isn't sufficient to explain the fairly large decrease in cone displacement vs freq. Speakers normally have pretty low reactance at audio frequencies. The main cause of the reduced amplitude is the mass of the system. The mass must be accelerated by the force from the magntic field produced by the coil. If that force changes more quickly, the cone is less able to follow it.
 

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