Codes for electromagnetic scattering by spheres - this article list codes for electromagnetic scattering by a homogeneous sphere, layered sphere, and cluster of spheres. Some of the source codes may be available on [1].
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Majority of existing codes for calculaton of electromagnetic scattering by a single sphere is based on Mie theory which is an analytical solution of Maxwell's equations in terms of infinite series. Other approximations to scattering by a single sphere include: Debye series, ray tracing (geometrical optics), ray tracing including the effects of interference between rays, Airy theory, Rayleigh scattering, diffraction approximation. There are many phenomena related to light scattering by spherical particles such as resonances, surface waves, plasmons, near-field scattering. Even though Mie theory offers convenient and fast way of solving light scattering problem by homogeneous spherical particles, there are other techniques, such as discrete dipole approximation, FDTD, T-matrix, which can also be used for such tasks. [1]
The compilation contains information about the electromagnetic scattering by spherical particles, relevant links, and applications. [2]
Year | Name | Authors | References | Language | Short Description |
---|---|---|---|---|---|
1983 | BHMIE | Craig F. Bohren and Donald R. Huffman | [1] | "Mie solutions" (infinite series) to scattering, absorption and phase function of electromagnetic waves by a homogeneous sphere. | |
2002 | MiePlot [3] | Philip Laven | [4] | Visual Basic | MiePlot offers the following mathematical models for the scattering of light by a sphere: Mie solutions, Debye series, ray tracing (based on geometrical optics), ray tracing including the effects of interference between rays, Airy theory, Rayleigh scattering, diffraction, surface waves. In addition to single-wavelength calculations, MiePlot can also perform calculations for a number of wavelengths, thus approximating a continuous spectrum (such as sunlight) to produce simulations of atmospheric optical effects such as rainbows, coronas and glories. |
2003 | Mie_Single etc[5] | Gareth Thomas and Don Grainger | [6] | IDL | The Sub-Department of Atmospheric Oceanic and Planetary Physics in the University of Oxford maintains an archive of Mie scattering routines for both single spheres and populations of particles in which sizes follow a log-normal distribution. Code is also available for calculating the analytical derivatives of Mie scattering (i.e. the derivative of the extinction and scattering coefficients, and the intensity functions with respect to size parameter and complex refractive index). The routines are written in IDL, but a Fortran based DLM version (which substantially reduces runtime) of the single-sphere code is also available. |
Algorithmic literature includes several contributions [7] [8] [9] [10]
Year | Name | Authors | References | Language | Short Description |
---|---|---|---|---|---|
1981 | DMILAY | Owen B. Toon and T. P. Ackerman | [9] | Fortran | Scattering by a stratified sphere (a particle with a spherical core surrounded by a spherical shell. |
1983 | BHCOAT | Craig F. Bohren and Donald R. Huffman | [1] | Fortran | "Mie solutions" (infinite series) to scattering, absorption and phase function of electromagnetic waves by a homogeneous concentring shells. |
1993 | IFCS, LSCCS | Thomas Kaiser and G. Schweiger | [11] | Fortran | Computes an internal field inside a coated sphere and the scattered field of a sphere with 0, 1 or 2 coatings. |
1997 | BART [12] | A. Quirantes | [13] | Fortran | Based on the Aden–Kerker theory to calculate light-scattering properties for coated spherical particles |
2004 | [14] | M. Jonasz | GUI/Windows | This program calculates the scattering, absorption, and attenuation parameters, as well as the angular scattering patterns of a single coated sphere according to Aden-Kerker theory. | |
2007 | L. Liu, H. Wang, B. Yu, Y. Xu, J. Shen | [15] | C | Light scattering by a coated sphere (extinction efficiency, scattering efficiency, light scattering intensity) |
Year | Name | Authors | References | Language | Short Description |
---|---|---|---|---|---|
1998-2003 | GMM | Yu-lin Xu and Bo A. S. Gustafson | [16] | Fortran | Codes which calculate exactly electromagnetic scattering by an aggregate of spheres in a single orientation or at an average over individual orientations. |