SMUTHI stands for 'scattering by multiple particles in thin-film systems'. The software allows to simulate light scattering by multiple particles near (or between) planar interfaces. It is based on the T-matrix method for the single particle scattering, and on the scattering-matrix method for the propagation through the layered medium.
Target group: Scientists and engineers in the field of optics and optoelectronics.
License: SMUTHI is provided under the MIT license.
Author: Amos Egel. Mail to [email protected] for support or to report a problem.
The following persons have contributed to the project:
- Dominik Theobald (functions for the simulation of rotated particles, plane wave based particle coupling for non-spherical particles with overlapping circumscribing spheres)
- Lorenzo Pattelli (logo)
- Konstantin Ladutenko (refactoring of code, handling of persistent NFMDS install)
We thank Adrian Doicu, Thomas Wriedt and Yuri Eremin for allowing us to use their NFM-DS Fortran code, and Ilia Rasskazov for bug reports and useful comments.
For a guide how to install and use the software, see the documentation.
Support for rotated particles, GPU support for the calculation of the near field.
Iterative solver (GMRES), lookup tables and GPU support were added for fast simulations including large particle numbers.
Dipole sources are supported as initial field.
Gaussian beams (more precisely: beams with transverse Gaussian footprint) are supported as initial field.
The data structure has been updated to a more consequent object oriented approach, including a PlaneWaveExpansion class and a SphericalWaveExpansion class. Smuthi's API is now also documented.
The software now allows to compute the electric near field. The fields can be plotted as png figure files and as gif animations. All generated output can be stored as figure files or as text files. The simulation object can be exported as binary file.
Finite cylinders were added.
In addition to spherical particles, spheroids can now be selected as scattering particles, too. Spheroids are ellipsoidal particles with one axis of rotational symmetry (which is currently fixed to be the direction perpendicular to the layer interfaces).
Things to be implemented next:
- plane wave based coupling for close non-spherical particles
- packages for the evaluation of bidirectional scattering distrubtion function and emission efficiency