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Series: ScattPort Series, Vol. 2 Wriedt, Thomas (Ed.) Light Scattering by Complex Particles epubli, Berlin 2015, Softcover 24,90 € ISBN: 9783737571937

Virtual Tissue Simulator
Virtual Tissue Simulator (VTS) is a modular and scalable computational platform, to provide an integrated suite of computational tools to define, solve, visualize, and analyze relevant forward and inverse radiative transport problems in biomedical optics. This is a beta release of a MATLAB interoperability package that works with the Windows version of MATLAB.

PAME
PAME (Plasmonic Assay Modeling Environment) by Adam Hughes is a graphical Python application for simulating plasmonic biosensors, particularly fiberoptic biosensors with nanoparticles.

NPL Simulations
This code by Giuseppe Toscano is an extension to the COMSOL 4.2a RF Module. It is based on the hydrodynamic model which incorporates nonlocal effects in the optical response of nanoplasmonic structures. The extension can only handle 2D structures.

for90-MoM2
for90-MoM2 by Jouni Mäkitalo is a Method of Moments electromagnetic wave scattering solver implemented in Fortran 90 for EM scattering from dielectric/lossy/plasmonic/PEC objects.

MAXDGTD by Hassan Fahs is a discontinuous Galerkin code for solving Maxwell's equations in the time-domain (DGTD). It is a Fortran code.

gprMax3D
Ground Penetrating Radar (GPR) is a non-destructive electromagnetic investigative tool used in many diverse applications across the fields of engineering and geophysics.

Mie Simulator GUI
This is a Mie Simulator GUI application. Mie Simulator GUI tool is capable of calculating - Scattering coefficient - Scattering cross section - Reduced scattering coefficient - Phase function - S1 and S2 - Average cosine of the phase function for a single or series of wavelengths
- Link (10 Aug 2015, offline)
- Link (6 Nov 2021)

VCRMEll2D
VCRMEll2D by Kuan Fang Renis the first realization of the Vectorial Complex Ray Model - VCRM developed by the author. By introducing the property of the Wavefront in the geometrical optics model, the VCRM can calculate very precisely the interaction of a wave of any form with a object of smooth surface and size much larger than the wavelength of the incident beam.

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