Heat equation: Difference between revisions

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(Began a basic description of what the equation is, what it is for, and how it may be solved.)
 
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The heat equation is so called because it was studied by [[Joseph Fourier]] as a way of describing the way heat spreads over time.  The heat equation can also be used to describe other processes such as diffusion.
The heat equation is so called because it was studied by [[Joseph Fourier]] as a way of describing the way heat spreads over time.  The heat equation can also be used to describe other processes such as diffusion.


On an infinite spatial domain, the heat equation is usually solved using the [[Fourier transform]].  On a finite spatial domain, [[separation of variables]] is often used along with the [[Fourier Series]].
On an infinite spatial domain, the heat equation is usually solved using the [[Fourier transform]].  On a finite spatial domain, [[separation of variables]] is often used along with the [[Fourier series]].

Revision as of 01:36, 3 September 2010

The heat equation is a partial differential equation of the form

where denotes the Laplacian. When there is only one spatial dimension being considered, the heat equation takes the form

The heat equation is so called because it was studied by Joseph Fourier as a way of describing the way heat spreads over time. The heat equation can also be used to describe other processes such as diffusion.

On an infinite spatial domain, the heat equation is usually solved using the Fourier transform. On a finite spatial domain, separation of variables is often used along with the Fourier series.