Common pilot channel: Difference between revisions

Latest revision as of 21:12, 28 March 2013

Arnold Sommerfeld defined the condition of radiation for a scalar field satisfying the Helmholtz equation as

"the sources must be sources, not sinks of energy. The energy which is radiated from the sources must scatter to infinity; no energy may be radiated from infinity into ... the field."^[1]

Mathematically, consider the inhomogeneous Helmholtz equation

(\nabla^{2} + k^{2}) u = - f in ℝ^{n}

where $n = 2, 3$ is the dimension of the space, $f$ is a given function with compact support representing a bounded source of energy, and $k > 0$ is a constant, called the wavenumber. A solution $u$ to this equation is called radiating if it satisfies the Sommerfeld radiation condition

\lim_{| x | \to \infty} | x |^{\frac{n - 1}{2}} (\frac{\partial}{\partial | x |} - i k) u (x) = 0

uniformly in all directions

\hat{x} = \frac{x}{| x |}

(above, $i$ is the imaginary unit and $| \cdot |$ is the Euclidean norm). Here, it is assumed that the time-harmonic field is $e^{- i ω t} u .$ If the time-harmonic field is instead $e^{i ω t} u,$ one should replace $- i$ with $+ i$ in the Sommerfeld radiation condition.

The Sommerfeld radiation condition is used to solve uniquely the Helmholtz equation. For example, consider the problem of radiation due to a point source $x_{0}$ in three dimensions, so the function $f$ in the Helmholtz equation is $f (x) = δ (x - x_{0}),$ where $δ$ is the Dirac delta function. This problem has an infinite number of solutions. All solutions have the form

u = c u_{+} + (1 - c) u_{-}

where $c$ is a constant, and

u_{\pm} (x) = \frac{e^{\pm i k | x - x_{0} |}}{4 π | x - x_{0} |} .

Of all these solutions, only $u_{+}$ satisfies the Sommerfeld radiation condition and corresponds to a field radiating from $x_{0} .$ The other solutions are unphysical. For example, $u_{-}$ can be interpreted as energy coming from infinity and sinking at $x_{0} .$

References

↑ A. Sommerfeld, Partial Differential Equations in Physics, Academic Press, New York, New York, 1949.

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[1] A. Sommerfeld, Partial Differential Equations in Physics, Academic Press, New York, New York, 1949.

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+[[Arnold Sommerfeld]] defined the condition of radiation for a scalar field satisfying the [[Helmholtz equation]] as
+: "the sources must be sources, not sinks of energy. The energy which is radiated from the sources must scatter to infinity; no energy may be radiated from infinity into ... the field."<ref>A. Sommerfeld, ''Partial Differential Equations in Physics'', Academic Press, New York, New York, 1949.</ref>
+Mathematically, consider the inhomogeneous [[Helmholtz equation]]
+:<math>
+(\nabla^2 + k^2) u = -f \mbox{ in } \mathbb R^n
+</math>
+where <math>n=2, 3</math> is the dimension of the space, <math>f</math> is a given function with [[compact support]] representing a bounded source of energy, and <math>k>0</math> is a constant, called the ''wavenumber''. A solution <math>u</math> to this equation is called ''radiating'' if it satisfies the '''Sommerfeld radiation condition'''
+: <math>\lim_{|x| \to \infty} |x|^{\frac{n-1}{2}} \left( \frac{\partial}{\partial |x|} - ik \right) u(x) = 0</math>
+uniformly in all directions
+:<math>\hat{x} = \frac{x}{|x|}</math>
+(above, <math>i</math> is the [[imaginary unit]] and <math>|\cdot|</math> is the [[Euclidean norm]]). Here, it is assumed that the time-harmonic field is <math>e^{-i\omega t}u.</math> If the time-harmonic field is instead <math>e^{i\omega t}u,</math> one should replace  <math>-i</math> with <math>+i</math> in the Sommerfeld radiation condition.
+The Sommerfeld radiation condition is used to solve uniquely the Helmholtz equation. For example, consider the problem of radiation due to a point source <math>x_0</math> in three dimensions, so the function <math>f</math> in the Helmholtz equation is <math>f(x)=\delta(x-x_0),</math> where <math>\delta</math> is the [[Dirac delta function]].  This problem has an infinite number of solutions. All solutions have the form
+:<math>u = cu_+ + (1-c) u_- \,</math>
+where <math>c</math> is a constant, and
+: <math>u_{\pm}(x) = \frac{e^{\pm ik|x-x_0|}}{4\pi |x-x_0|}.</math>
+Of all these solutions, only <math>u_+</math> satisfies the Sommerfeld radiation condition and corresponds to a field radiating from <math>x_0.</math> The other solutions are unphysical. For example, <math>u_{-}</math> can be interpreted as energy coming from infinity and sinking at <math>x_0.</math>
+==References==
+<references/>
+*{{cite book
+ | last       = Martin
+ | first      = P. A
+ | title      = Multiple scattering: interaction of time-harmonic waves with N obstacles
+ | publisher  = Cambridge; New York: Cambridge University Press
+ | year       = 2006
+ | pages      =
+ | isbn       = 0-521-86554-9
+}}
+==External links==
+* {{springer|id=r/r077060|title=Radiation conditions|author=A.G. Sveshnikov}}
+[[Category:Waves]]
+[[Category:Partial differential equations]]

Common pilot channel: Difference between revisions

Latest revision as of 21:12, 28 March 2013

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