Difference between revisions of "Delta-function method"
(Importing text file) |
(TeX) |
||
Line 1: | Line 1: | ||
− | A method for finding the [[Green function|Green function]] of a linear differential equation in mathematical physics (i.e. a method for determining the function of the effect of a point source) with the aid of the [[Delta-function|delta-function]] | + | {{TEX|done}} |
+ | A method for finding the [[Green function|Green function]] of a linear differential equation in mathematical physics (i.e. a method for determining the function of the effect of a point source) with the aid of the [[Delta-function|delta-function]] $\delta(x)$. The Green function $G(x,x')$ of a linear differential operator $L$ is defined by the equation | ||
− | + | $$L(x)G(x,x')=\delta(x-x'),$$ | |
− | or | + | or $G(x,x')=-L^{-1}(x)\delta(x-x')$, i.e. it expresses the effect of a point source located at the point $x'$ on the value of the resulting perturbation at the point $x$. The form of the inverse operator $L^{-1}$ is most simply determined in the frequently occurring case when $L$ is a differential operator with constant coefficients (independent of $x$). The solution of a non-homogeneous linear differential equation of a general type for a perturbation $\phi$ with source $\rho$, |
− | + | $$L(x)\phi(x)=-\rho(x),$$ | |
− | is described with the aid of the Green function | + | is described with the aid of the Green function $G(x,x')$ as the convolution |
− | + | $$\phi(x)=\int G(x,x')\rho(x')dx',$$ | |
− | the integration being effected over the entire domain of action of the source | + | the integration being effected over the entire domain of action of the source $\rho$. |
====References==== | ====References==== |
Revision as of 09:56, 26 April 2014
A method for finding the Green function of a linear differential equation in mathematical physics (i.e. a method for determining the function of the effect of a point source) with the aid of the delta-function $\delta(x)$. The Green function $G(x,x')$ of a linear differential operator $L$ is defined by the equation
$$L(x)G(x,x')=\delta(x-x'),$$
or $G(x,x')=-L^{-1}(x)\delta(x-x')$, i.e. it expresses the effect of a point source located at the point $x'$ on the value of the resulting perturbation at the point $x$. The form of the inverse operator $L^{-1}$ is most simply determined in the frequently occurring case when $L$ is a differential operator with constant coefficients (independent of $x$). The solution of a non-homogeneous linear differential equation of a general type for a perturbation $\phi$ with source $\rho$,
$$L(x)\phi(x)=-\rho(x),$$
is described with the aid of the Green function $G(x,x')$ as the convolution
$$\phi(x)=\int G(x,x')\rho(x')dx',$$
the integration being effected over the entire domain of action of the source $\rho$.
References
[1] | D. Ivanenko, A. Sokolov, "Classical field theory" , Mosow-Leningrad (1951) (In Russian) |
Comments
References
[a1] | P.M. Morse, H. Feshbach, "Methods of theoretical physics" , 1–2 , McGraw-Hill (1953) |
Delta-function method. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Delta-function_method&oldid=12041