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Line 1: [[File:Plot of the Anger function J v(z) with n=2 in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D.svg\|alt=Plot of the Anger function J v(z) with n=2 in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D\|thumb\|Plot of the Anger function J v(z) with n=2 in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D]] In [[mathematics]], the '''Anger function''', introduced by {{harvs\|txt\|authorlink=Carl Theodor Anger\|first=C. T.\|last=Anger\|year=1855}}, is a function defined as : <math>\mathbf{J}_\nu(z)=\frac{1}{\pi} \int_0^\pi \cos (\nu\theta-z\sin\theta) \,d\theta</math> with complex parameter <math>\nu</math> and complex variable <math>\textit{z}</math>.<ref name="EOM_Anger">{{springer\|id=A/a012490\|title=Anger function\|first=A.P.\|last= Prudnikov\|authorlink=Anatolii Platonovich Prudnikov}}</ref> It is closely related to the [[Bessel function]]s. ~~and is closely related to [[Bessel function]]s.~~ The '''Weber function''' (also known as '''[[Eugen von Lommel\|Lommel]]–Weber function'''), introduced by {{harvs\|txt\|authorlink=Heinrich Friedrich Weber\|first=H. F.\|last=Weber\|year=1879}}, is a closely related function defined by : <math>\mathbf{E}_\nu(z)=\frac{1}{\pi} \int_0^\pi \sin (\nu\theta-z\sin\theta) \,d\theta</math> Line 15 ⟶ 16: The Anger and Weber functions are related by :[[File:Plot of the Weber function E v(z) with n=2 in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D.svg\|alt=Plot of the Weber function E v(z) with n=2 in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D\|thumb\|Plot of the Weber function E v(z) with n=2 in the complex plane from -2-2i to 2+2i with colors created with Mathematica 13.1 function ComplexPlot3D]]<math> :<math>\sin(\pi \nu)\mathbf{J}_\nu(z) = \cos(\pi\nu)\mathbf{E}_\nu(z)-\mathbf{E}_{-\nu}(z)</math>▼ \begin{align} ▲~~:<math>~~\sin(\pi \nu)\mathbf{J}_\nu(z) &= \cos(\pi\nu)\mathbf{E}_\nu(z)-\mathbf{E}_{-\nu}(z)~~</math>~~, \\ ~~:<math>~~-\sin(\pi \nu)\mathbf{E}_\nu(z) &= \cos(\pi\nu)\mathbf{J}_\nu(z)-\mathbf{J}_{-\nu}(z)~~</math>~~,▼ \end{align} </math> so in particular if ~~ν~~ν is not an [[integer]] they can be expressed as linear combinations of each other. If ~~ν~~ν is an integer then Anger functions '''J'''<sub>~~ν~~ν</sub> are the same as Bessel functions ''J''<sub>~~ν~~ν</sub>, and Weber functions can be expressed as finite linear combinations of [[Struve function]]s.▼ ▲:<math>-\sin(\pi \nu)\mathbf{E}_\nu(z) = \cos(\pi\nu)\mathbf{J}_\nu(z)-\mathbf{J}_{-\nu}(z)</math> ==Power series expansion== ▲so in particular if ν is not an integer they can be expressed as linear combinations of each other. If ν is an integer then Anger functions '''J'''<sub>ν</sub> are the same as Bessel functions ''J''<sub>ν</sub>, and Weber functions can be expressed as finite linear combinations of [[Struve function]]s. The Anger function has the [[power series]] expansion<ref name=DLMF>{{dlmf\|id=11.10\|title=Anger-Weber Functions\|first=R. B. \|last=Paris}}</ref> :<math>\mathbf{J}_\nu(z)=\cos\frac{\pi\nu}{2}\sum_{k=0}^\infty\frac{(-1)^kz^{2k}}{4^k\Gamma\left(k+\frac{\nu}{2}+1\right)\Gamma\left(k-\frac{\nu}{2}+1\right)}+\sin\frac{\pi\nu}{2}\sum_{k=0}^\infty\frac{(-1)^kz^{2k+1}}{2^{2k+1}\Gamma\left(k+\frac{\nu}{2}+\frac{3}{2}\right)\Gamma\left(k-\frac{\nu}{2}+\frac{3}{2}\right)}.</math> While the Weber function has the power series expansion<ref name=DLMF/> :<math>\mathbf{E}_\nu(z)=\sin\frac{\pi\nu}{2}\sum_{k=0}^\infty\frac{(-1)^kz^{2k}}{4^k\Gamma\left(k+\frac{\nu}{2}+1\right)\Gamma\left(k-\frac{\nu}{2}+1\right)}-\cos\frac{\pi\nu}{2}\sum_{k=0}^\infty\frac{(-1)^kz^{2k+1}}{2^{2k+1}\Gamma\left(k+\frac{\nu}{2}+\frac{3}{2}\right)\Gamma\left(k-\frac{\nu}{2}+\frac{3}{2}\right)}.</math> ==Differential equations== The Anger and Weber functions are solutions of ~~inhomogenous~~inhomogeneous forms of Bessel's equation :<math>z^2y^{\prime\prime} + zy^\prime +(z^2-\nu^2)y = 0 .</math>~~. More precisely,~~ the Anger functions satisfy the equation▼ More precisely, the Anger functions satisfy the equation<ref name=DLMF/> :<math>z^2y^{\prime\prime} + zy^\prime +(z^2-\nu^2)y = \frac{(z-\nu)\sin(\pi \nu)}{\pi} ,</math> ▲and the ~~Anger~~Weber functions satisfy the equation<ref name=DLMF/> :<math>z^2y^{\prime\prime} + zy^\prime +(z^2-\nu^2)y = -\frac{z+\nu+(z-\nu)\cos(\pi \nu)}{\pi}.</math> ==Recurrence relations== The Anger function satisfies this inhomogeneous form of [[recurrence relation]]<ref name=DLMF/> :<math>z\mathbf{J}_{\nu-1}(z)+z\mathbf{J}_{\nu+1}(z)=2\nu\mathbf{J}_\nu(z)-\frac{2\sin\pi\nu}{\pi}.</math> While the Weber function satisfies this inhomogeneous form of [[recurrence relation]]<ref name=DLMF/> :<math>z\mathbf{E}_{\nu-1}(z)+z\mathbf{E}_{\nu+1}(z)=2\nu\mathbf{E}_\nu(z)-\frac{2(1-\cos\pi\nu)}{\pi}.</math> ==Delay differential equations== The Anger and Weber functions satisfy these homogeneous forms of [[delay differential equation]]s<ref name=DLMF/> :<math>~~z^2y^~~\mathbf{J}_{\~~prime~~nu-1}(z)-\~~prime~~mathbf{J} ~~+ zy^~~_{\~~prime~~ nu+1}(z^)=2-\~~nu^2)y~~dfrac{\partial}{\partial ~~= (~~z-}\~~nu)~~mathbf{J}_\~~sin~~nu(~~\pi~~ z)~~/\pi~~,</math> :<math>\mathbf{E}_{\nu-1}(z)-\mathbf{E}_{\nu+1}(z)=2\dfrac{\partial}{\partial z}\mathbf{E}_\nu(z).</math> ~~and~~The ~~the~~Anger and Weber functions also satisfy ~~the~~these inhomogeneous forms of [[delay differential equation]]s<ref name=DLMF/> :<math>z~~^2y^~~\dfrac{\~~prime\prime~~partial} ~~+ zy^~~{\~~prime~~partial +(z~~^2-~~}\mathbf{J}_\nu~~^2)y = -(~~(z+)\pm\nu\mathbf{J}_\nu(z)=\pm ~~+ (~~z-\mathbf{J}_{\nu)\~~cos~~mp1}(~~\pi~~ z))/\pm\frac{\sin\pi.\nu}{\pi},</math> :<math>z\dfrac{\partial}{\partial z}\mathbf{E}_\nu(z)\pm\nu\mathbf{E}_\nu(z)=\pm z\mathbf{E}_{\nu\mp1}(z)\pm\frac{1-\cos\pi\nu}{\pi}.</math> ==References== {{Reflist}} {{Refbegin}} {{AS ref\|12\|498}} C.T. Anger, Neueste Schr. d. Naturf. d. Ges. i. Danzig , 5 (1855) pp.  1–29 {{springer\|id=A/a012490\|title=Anger function\|first=A.P.\|last= Prudnikov}} {{springer\|id=W/w097320\|title=Weber function\|first=A.P.\|last= Prudnikov}} [[G.N. Watson]], "A treatise on the theory of Bessel functions" , 1–2 , Cambridge Univ. Press (1952) H.F. Weber, Zurich Vierteljahresschrift , 24 (1879) pp.  33–76 {{Refend}} [[Category:Special functions]]