Heat equation on a half line: Techniques for Solving and Verifying Solutions

AI Thread Summary
The discussion focuses on solving the heat equation on a half line with a time-dependent boundary condition at x=0 and an initial condition. Participants suggest various techniques, including the Laplace transform and heat kernel methods, as alternatives to the sine transformation, which results in a zero value at x=0. The importance of providing the complete problem for better assistance is emphasized, with a mention of Fourier decomposition for specific cases. The original poster expresses difficulty in verifying their solution against the initial condition, particularly when evaluating the limit as t approaches zero. Overall, the conversation highlights the complexity of the problem and the need for clarity in boundary conditions and solution verification.
jollage
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Heat equation on a half line!

Hi,

I am now dealing with the heat equation on a half line, i.e., the heat equation is subject to one time-dependent boundary condition only at x=0 (the other boundary condition is zero at the infinity) and an initial condition.

I searched online, it seems that for the half line problem, only the sine transformation can solve the heat equation, but in that case, the final result is always zero at x=0 since when doing sine transformation, one should assume that the to-be-transformed function is odd, so the function is zero at x=0.

My question is, do you know any other techniques to solve the heat equation on the half line without using sine transform?

Thanks.
 
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Sinusoidally varying temperatures don't really make sense. Try using the Laplace transform.
 
What is the specific problem?
 
jollage said:
I searched online, it seems that for the half line problem, only the sine transformation can solve the heat equation, but in that case, the final result is always zero at x=0 since when doing sine transformation, one should assume that the to-be-transformed function is odd, so the function is zero at x=0.

IF you tell us where you got that (wrong) idea, we might be able to explain what the website means, or confirm that it really is wrong.

mikeph said:
Sinusoidally varying temperatures don't really make sense. Try using the Laplace transform.

Sinusoidal in time, or in space? For example if you were applying a heat flux at x = 0 which was a periodic function of time, it would make good sense to do a Fourier decomposition of it.

As Chestermiller said, posting the complete problem would help.
 
Fourier, yes, decomposing it into sine waves, not so much. You need those exponential decays to make it die at infinity.
 
Hi,

Thanks for all your replies!

I didn't say it's sinusoidal, it's just a time-dependent function, not periodic.

Sorry, I shouldn't say "only the sine transformation can solve the heat equation". Yesterday, I just found using heat kernel can also solve the problem on a half line.

The document I upload is the note I took. I have a problem. When I tried to verify the solution by checking the initial condition and boundary condition, I have some problem to see the solution can really give initial condition, i.e., to set t=0 in the equation 18 of the document. I know one should take the limit as t->0+, but I failed to reach that. Do you have any clue?

Thanks!
 

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