Helmholtz equation
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The Helmholtz equation, named for Hermann von Helmholtz, is the elliptic partial differential equation
- [(\nabla^2 + k^2) A = 0]
Motivation and uses
The Helmholtz equation often arises in the study of physical problems involving partial differential equations (PDEs) in both space and time. The Helmholtz equation, which represents the time-independent form of original equation, results from applying the technique of separation of variables to reduce the complexity of the analysis.
For example, consider the wave equation:
- [\left(\nabla^2-\frac\frac^2}\right)u(\mathbf,t)=0]
- [u(\mathbf,t)=A (\mathbf) \cdot T(t)]
- [\nabla^2 A + k^2 A = ( \nabla^2 + k^2) A = 0 ]
- [\frac}^2} + \omega^2T = \left( + \omega^2 \right) T = 0,]
We now have Helmholtz's equation for the spatial variable [\mathbf] and a second-order ordinary differential equation in time. The solution in time will be a linear combination of sine and cosine functions, with angular frequency of ω, while the form of the solution in space will depend on the boundary conditions. Alternatively, integral transforms, such as the Laplace or Fourier transform, are often used to transform a hyperbolic PDE into a form of the Helmholtz equation.
Because of its relationship to the wave equation, the Helmholtz equation arises in problems in such areas of physics as the study of electromagnetic radiation, seismology, and acoustics.
Solving the Helmholtz equation using separation of variables
The general solution to the spatial Helmholtz equation
- [ ( \nabla^2 + k^2 ) A = 0 ]
Vibrating membrane
The two-dimensional analogue of the vibrating string is the vibrating membrane, with the edges clamped to be motionless. The Helmholtz equation was solved for many basic shapes in the 19th century: the rectangular membrane by Siméon Denis Poisson in 1829, the equilateral triangle by Gabriel Lamé in 1852, and the circular membrane by Alfred Clebsch in 1862. The elliptical drumhead was studied by Emile Mathieu, leading to Mathieu's differential equation. The solvable shapes all correspond to shapes whos dynamical billiard table is integrable, that is, not chaotic. When the motion on a correspondingly-shaped billiard table is chaotic, then no closed form solutions to the Helmholtz equation are known. The study of such systems is known as quantum chaos, as the Helmholtz equation and similar equations occur in quantum mechanics.
If the domain is a circle of radius a, then it is appropriate to introduce polar coordinates r and θ. The Helmholtz equation takes the form
- [ A_ + \frac A_r + \fracA_ + k^2 A=0. \,]
- [ A(a,\theta) = 0. \,]
- [ A(r,\theta) = R(r)\Theta(\theta), \,]
- [ \Theta'' +n^2 \Theta =0, \,]
- [ r^2 R'' + r R' + r^2 k^2 R + n^2 R=0. \,]
- [ \Theta = \alpha \cos n\theta + \beta \sin n\theta, \,]
- [ R(r) = \gamma J_n(\rho), \,]
- [ \rho^2 J_n'' + \rho J_n' +(\rho^2 + n^2)J_n =0, \,]
- [ k_ = \frac \rho_. \,]
- [ \sin(n\theta) \, \hbox \, \cos(n\theta), \, \hbox \, J_n(k_r). ]
Three-dimensional solutions
In spherical polar coordinates, the solution is:
- [ A (r, \theta, \phi)= \sum_ \sum_^\infty \sum_^l ( a_ j_l ( k r ) + b_ n_l ( k r ) ) Y ^ m_l ( ) ]
- [ Y^m_l ( )]
Paraxial form
The paraxial form of the Helmholtz equation is:
- [\nabla_T^2 A - j 2k = 0 ]
- [\nabla_T^2 = + ]
This equation has important applications in the science of optics, where it provides solutions that describe the propagation of electromagnetic waves (light) in the form of either paraboloidal waves or Gaussian beams. Most lasers emit beams that take this form.
In the paraxial approximation, the electric field complex magnitude E becomes
- [E(\mathbf) = A(\mathbf) e^ ]
The paraxial approximation places certain upper limits on the variation of the amplitude function A with respect to longitudinal distance z. Specifically:
- [ \bigg| \bigg| << | kA | ]
- [ \bigg| \bigg| << | k^2 A | ]
- [\sin(\theta) \approx \theta \qquad \mathrm \qquad \tan(\theta) \approx \theta ]
References
- M. Abramowitz and I. Stegun eds., Handbook of Mathematical functions with Formulas, Graphs and Mathematical Tables, National Bureau of Standards. Washington, D. C., 1964.
- Riley, K.F., Hobson, M.P., and Bence, S.J. (2002). Mathematical methods for physics and engineering, Cambridge University Press, ch. 19. ISBN 0-521-89067-5.
- McQuarrie, Donald A. (2003). Mathematical Methods for Scientists and Engineers, University Science Books: Sausalito, California, Ch. 16. ISBN 1-891389-24-6.
- Chapter 3, "Beam Optics," pp. 80–107.
- A. Sommerfeld, Partial Differential Equations in Physics, Academic Press, New York, New York, 1949.
External link
- [Helmholtz Equation] at EqWorld: The World of Mathematical Equations.
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