Wanting to understand the linearity of wave equations

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The discussion centers on understanding the linearity of wave equations and its connection to the principle of superposition. It is clarified that if two functions, f1 and f2, are solutions to the wave equation, their sum (f1 + f2) is also a solution, demonstrating linearity. Additionally, scaling a solution by a constant (αf) also yields another valid solution. This property allows for the decomposition of complex waveforms, such as standing waves, into simpler components. The principle of superposition is thus a fundamental characteristic derived from the linear nature of the wave equation.
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dear yall

with tranditional wave equation on the gre book it says by the linearity in function f which represents wave. it leads to the principle of superposition.

I get an intuition about with a standing wave with cos(x)cos(t) you can break it down to pair of left and right moving waves.

i understand if you sum up the wave is produced from the sum of all subwaves. but how can you get the linearity and such superposition property from simply the wave equation:
grad*grad*f = # d^2f/dt^2

thank you very much
 
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jdou86 said:
dear yall

with tranditional wave equation on the gre book it says by the linearity in function f which represents wave. it leads to the principle of superposition.

I get an intuition about with a standing wave with cos(x)cos(t) you can break it down to pair of left and right moving waves.

i understand if you sum up the wave is produced from the sum of all subwaves. but how can you get the linearity and such superposition property from simply the wave equation:
grad*grad*f = # d^2f/dt^2

thank you very much
The linearity comes simply from the fact that if ##f_1## and ##f_2## are solutions, then so is ##f_1 + f_2##.

In addition, if ##f## is a solution and ##\alpha## is a number, then ##\alpha f## is also a solution.
 

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