Kirchhoff integral theorem

Kirchhoff's integral theorem (sometimes referred to as the Fresnel–Kirchhoff integral theorem)^[1] is a surface integral to obtain the value of the solution of the homogeneous scalar wave equation at an arbitrary point P in terms of the values of the solution and the solution's first-order derivative at all points on an arbitrary closed surface (on which the integration is performed) that encloses P.^[2] It is derived by using Green's second identity and the homogeneous scalar wave equation that makes the volume integration in Green's second identity zero.^[2][3]

The integral has the following form for a monochromatic wave:^[2][3][4]

${\displaystyle U(𝐫)=\frac{1}{4\pi }\underset{S}{\int }[U\frac{\partial }{\partial \widehat{𝐧}}\left(\frac{e^{iks}}{s}\right)-\frac{e^{iks}}{s}\frac{\partial U}{\partial \widehat{𝐧}}]dS,}$

where the integration is performed over an arbitrary closed surface S enclosing the observation point ${\displaystyle 𝐫}$, ${\displaystyle k}$ in ${\displaystyle e^{iks}}$ is the wavenumber, ${\displaystyle s}$ in ${\displaystyle \frac{e^{iks}}{s}}$ is the distance from an (infinitesimally small) integral surface element to the point ${\displaystyle 𝐫}$, ${\displaystyle U}$ is the spatial part of the solution of the homogeneous scalar wave equation (i.e., ${\displaystyle V(𝐫,t)=U(𝐫)e^{-i\omega t}}$ as the homogeneous scalar wave equation solution), ${\displaystyle \widehat{𝐧}}$ is the unit vector inward from and normal to the integral surface element, i.e., the inward surface normal unit vector, and ${\displaystyle \frac{\partial }{\partial \widehat{𝐧}}}$ denotes differentiation along the surface normal (i.e., a normal derivative) i.e., ${\displaystyle \frac{\partial f}{\partial \widehat{𝐧}}=\mathrm{\nabla }f\cdot \widehat{𝐧}}$ for a scalar field ${\displaystyle f}$. Note that the surface normal is inward, i.e., it is toward the inside of the enclosed volume, in this integral; if the more usual outer-pointing normal is used, the integral will have the opposite sign.

This integral can be written in a more familiar form

${\displaystyle U(𝐫)=\frac{1}{4\pi }\underset{S}{\int }(U\mathrm{\nabla }\left(\frac{e^{iks}}{s}\right)-\frac{e^{iks}}{s}\mathrm{\nabla }U)\cdot d\overrightarrow{S},}$

where ${\displaystyle d\overrightarrow{S}=dS\widehat{𝐧}}$.^[3]

A more general form can be derived for non-monochromatic waves. The complex amplitude of the wave can be represented by a Fourier integral of the form

${\displaystyle V(r,t)=\frac{1}{\sqrt{2\pi }}\int U_{\omega }(r)e^{-i\omega t}d\omega ,}$

where, by Fourier inversion, we have

${\displaystyle U_{\omega }(r)=\frac{1}{\sqrt{2\pi }}\int V(r,t)e^{i\omega t}dt.}$

The integral theorem (above) is applied to each Fourier component ${\displaystyle U_{\omega }}$, and the following expression is obtained:^[2]

${\displaystyle V(r,t)=\frac{1}{4\pi }\underset{S}{\int }\{[V]\frac{\partial }{\partial n}\left(\frac{1}{s}\right)-\frac{1}{cs}\frac{\partial s}{\partial n}\left[\frac{\partial V}{\partial t}\right]-\frac{1}{s}\left[\frac{\partial V}{\partial n}\right]\}dS,}$

where the square brackets on V terms denote retarded values, i.e. the values at time t − s/c.

Kirchhoff showed that the above equation can be approximated to a simpler form in many cases, known as the Kirchhoff, or Fresnel–Kirchhoff diffraction formula, which is equivalent to the Huygens–Fresnel equation, except that it provides the inclination factor, which is not defined in the Huygens–Fresnel equation. The diffraction integral can be applied to a wide range of problems in optics.

Here, the derivation of the Kirchhoff's integral theorem is introduced. First, the Green's second identity as the following is used.

$${\displaystyle \underset{V}{\int }(U_1{\mathrm{\nabla }}^2{U}_2-U_2{\mathrm{\nabla }}^2{U}_1)dV={{\displaystyle \oint }}_{\partial V}(U_2\frac{\partial U_1}{\partial \widehat{𝐧}}-U_1\frac{\partial U_2}{\partial \widehat{𝐧}})dS,}$$ where the integral surface normal unit vector ${\displaystyle \widehat{𝐧}}$ here is toward the volume ${\displaystyle V}$ closed by an integral surface ${\displaystyle \partial V}$. Scalar field functions ${\displaystyle U_1}$ and ${\displaystyle U_2}$ are set as solutions of the Helmholtz equation, ${\displaystyle {\mathrm{\nabla }}^{2}U+k^{2}U=0}$ where ${\displaystyle k=\frac{2\pi }{\lambda }}$ is the wavenumber (${\displaystyle \lambda }$ is the wavelength), that gives the spatial part of a complex-valued monochromatic (single frequency in time) wave expression. (The product between the spatial part and the temporal part of the wave expression is a solution of the scalar wave equation.) Then, the volume part of the Green's second identity is zero, so only the surface integral is remained as $${\displaystyle {{\displaystyle \oint }}_{\partial V}(U_2\frac{\partial U_1}{\partial \widehat{𝐧}}-U_1\frac{\partial U_2}{\partial \widehat{𝐧}})dS=0.}$$ Now ${\displaystyle U_2}$ is set as the solution of the Helmholtz equation to find and ${\displaystyle U_1}$ is set as the spatial part of a complex-valued monochromatic spherical wave ${\displaystyle U_1=\frac{e^{iks}}{s}}$ where ${\displaystyle s}$ is the distance from an observation point ${\displaystyle P}$ in the closed volume ${\displaystyle V}$. Since there is a singularity for ${\displaystyle U_1=\frac{e^{iks}}{s}}$ at ${\displaystyle P}$ where ${\displaystyle s=0}$ (the value of ${\displaystyle \frac{e^{iks}}{s}}$ not defined at ${\displaystyle s=0}$), the integral surface must not include ${\displaystyle P}$. (Otherwise, the zero volume integral above is not justified.) A suggested integral surface is an inner sphere ${\displaystyle S_1}$ centered at ${\displaystyle P}$ with the radius of ${\displaystyle s_1}$ and an outer arbitrary closed surface ${\displaystyle S_2}$.

Then the surface integral becomes $${\displaystyle {{\displaystyle \oint }}_{S_1}(U_2\frac{\partial }{\partial \widehat{𝐧}}\frac{e^{iks}}{s}-\frac{e^{iks}}{s}\frac{\partial }{\partial \widehat{𝐧}}{U}_2)dS+{{\displaystyle \oint }}_{S_2}(U_2\frac{\partial }{\partial \widehat{𝐧}}\frac{e^{iks}}{s}-\frac{e^{iks}}{s}\frac{\partial }{\partial \widehat{𝐧}}{U}_2)dS=0.}$$ For the integral on the inner sphere ${\displaystyle S_1}$, $${\displaystyle \frac{\partial }{\partial \widehat{𝐧}}\frac{e^{iks}}{s}=\mathrm{\nabla }\frac{e^{iks}}{s}\cdot \widehat{𝐧}=(\frac{ik}{s}-\frac{1}{s^2})e^{iks},}$$ and by introducing the solid angle ${\displaystyle d\mathrm{\Omega }}$ in ${\displaystyle dS=s^{2}d\mathrm{\Omega }}$, $${\displaystyle {{\displaystyle \oint }}_{S_1}(U_2\frac{\partial }{\partial \widehat{𝐧}}\frac{e^{iks}}{s}-\frac{e^{iks}}{s}\frac{\partial }{\partial \widehat{𝐧}}{U}_2)dS={{\displaystyle \oint }}_{S_1}(U_2(\frac{ik}{s}-\frac{1}{s^2})e^{iks}-\frac{e^{iks}}{s}\frac{\partial }{\partial \widehat{𝐧}}{U}_2)s^{2}d\mathrm{\Omega }={{\displaystyle \oint }}_{S_1}(iks{U}_2-U_2-s\frac{\partial }{\partial \widehat{𝐧}}{U}_2)e^{iks}d\mathrm{\Omega }}$$ due to ${\displaystyle \frac{\partial }{\partial \widehat{𝐧}}{U}_2=\mathrm{\nabla }{U}_2\cdot \widehat{𝐧}=\frac{\partial }{\partial s}{U}_2}$. (The spherical coordinate system which origin is at ${\displaystyle P}$ can be used to derive this equality.)

By shrinking the sphere ${\displaystyle S_1}$ toward the zero radius (but never touching ${\displaystyle P}$ to avoid the singularity), ${\displaystyle e^{iks}\to 1}$ and the first and last terms in the ${\displaystyle S_1}$ surface integral becomes zero, so the integral becomes ${\displaystyle -4\pi U_2}$. As a result, denoting ${\displaystyle U_2}$, the location of ${\displaystyle P}$, and ${\displaystyle S_2}$ by ${\displaystyle U}$, the position vector ${\displaystyle 𝐫}$, and ${\displaystyle S}$ respectively, $${\displaystyle U(𝐫)=\frac{1}{4\pi }{{\displaystyle \oint }}_S(U\frac{\partial }{\partial \widehat{𝐧}}\frac{e^{iks}}{s}-\frac{e^{iks}}{s}\frac{\partial }{\partial \widehat{𝐧}}U)dS.}$$

• Kirchhoff's diffraction formula
• Vector calculus
• Integral
• Huygens–Fresnel principle
• Wavefront
• Surface integral

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