|
|
| Line 1: |
Line 1: |
| A '''separable''' [[partial differential equation]] (PDE) is one that can be broken into a set of separate equations of lower dimensionality (fewer independent variables) by a method of [[separation of variables]]. This generally relies upon the problem having some special form or [[symmetry]]. In this way, the PDE can be solved by solving a set of simpler PDEs, or even [[ordinary differential equation]]s (ODEs) if the problem can be broken down into one-dimensional equations.
| | Alyson is the title individuals use to contact me and I believe it seems quite good when you say it. He is an info officer. North Carolina is the place he loves most but now he is contemplating other options. She is truly fond of caving but she doesn't have the time recently.<br><br>My webpage - [http://www.aseandate.com/index.php?m=member_profile&p=profile&id=13352970 clairvoyants] |
| | |
| The most common form of separation of variables is simple separation of variables in which a solution is obtained by assuming a solution of the form given by a product of functions of each individual coordinate.There is a special form of separation of variables called <math>R</math>-separation of variables which is accomplished by writing the solution as a particular fixed function of the coordinates multiplied by a product of functions of each individual coordinate. Laplace's equation on <math>{\mathbb R}^n</math> is an example of a partial differential equation which admits solutions through <math>R</math>-separation of variables.
| |
| | |
| (This should not be confused with the case of a separable ODE, which refers to a somewhat different class of problems that can be broken into a pair of [[integral]]s; see [[separation of variables]].)
| |
| | |
| == Example ==
| |
| | |
| For example, consider the time-independent [[Schrödinger equation]]
| |
| | |
| :<math>[-\nabla^2 + V(\mathbf{x})]\psi(\mathbf{x}) = E\psi(\mathbf{x})</math> | |
| | |
| for the function <math>\psi(\mathbf{x})</math> (in dimensionless units, for simplicity). (Equivalently, consider the inhomogeneous [[Helmholtz equation]].) If the function <math>V(\mathbf{x})</math> in three dimensions is of the form
| |
| | |
| :<math>V(x_1,x_2,x_3) = V_1(x_1) + V_2(x_2) + V_3(x_3),</math>
| |
| | |
| then it turns out that the problem can be separated into three one-dimensional ODEs for functions <math>\psi_1(x_1)</math>, <math>\psi_2(x_2)</math>, and <math>\psi_3(x_3)</math>, and the final solution can be written as <math>\psi(\mathbf{x}) = \psi_1(x_1) \cdot \psi_2(x_2) \cdot \psi_3(x_3)</math>. (More generally, the separable cases of the Schrödinger equation were enumerated by Eisenhart in 1948.<ref>L. P. Eisenhart, "Enumeration of potentials for which one-particle Schrodinger equations are separable," ''Phys. Rev.'' '''74''', 87-89 (1948).</ref>)
| |
| | |
| == References == | |
| <references/>
| |
| [[Category:Differential equations]]
| |
Latest revision as of 21:31, 9 December 2014
Alyson is the title individuals use to contact me and I believe it seems quite good when you say it. He is an info officer. North Carolina is the place he loves most but now he is contemplating other options. She is truly fond of caving but she doesn't have the time recently.
My webpage - clairvoyants