Add to ORKGThe theoretical and numerical models for simulation of light propagation process through a turbid medium with randomly-positioned circular particles with a statistical variation in their diameters has been derived based on Finite-Difference Time-Domain (FDTD) method for direct solution of Maxwell’s equations. The results of numerical simulations for propagation of continuous-wave radiation and short laser pulses are compared with other scattering models for typical biological tissues
In this paper we focus on the discussion of two recent unique applications of the finite-difference ...
Finite-Difference Time-Domain method (FDTD) is based on numerical solution of Maxwell's equations, n...
International audienceAn important issue in tissue optics and Optical Tomography is to have an effic...
The scattering and absorption of electromagnetic waves by irregularly shaped particles and arbitrary...
Biological cells can be considered as dielectric objects with a given refractive index distribution....
Biological cells can be considered as dielectric objects with a given refractive index distribution....
Abstract—Scattering of electromagnetic waves from a red blood cell is simulated using the finite-dif...
The usual, highly efficient, modelling tools for planar optical devices are generally not suitable f...
The usual, highly efficient, modelling tools for planar optical devices are generally not suitable f...
The effect of cell morphology on light scattering is investigated using computer sim-ulations. A par...
In this invited paper we focus on the discussion of two recent unique applications of the Finite-Dif...
Scalar diffraction theory is not applicable to electromagnetic problems in which structural (light s...
The theoretical and numerical models for simulation of light propagation through a system of coupled...
The ®nite difference time domain method is used as a tool to model non-linear optical devices. Foll...
The Finite-Difference Time-Domain method has been applied to microwaves with successfully results. T...
In this paper we focus on the discussion of two recent unique applications of the finite-difference ...
Finite-Difference Time-Domain method (FDTD) is based on numerical solution of Maxwell's equations, n...
International audienceAn important issue in tissue optics and Optical Tomography is to have an effic...
The scattering and absorption of electromagnetic waves by irregularly shaped particles and arbitrary...
Biological cells can be considered as dielectric objects with a given refractive index distribution....
Biological cells can be considered as dielectric objects with a given refractive index distribution....
Abstract—Scattering of electromagnetic waves from a red blood cell is simulated using the finite-dif...
The usual, highly efficient, modelling tools for planar optical devices are generally not suitable f...
The usual, highly efficient, modelling tools for planar optical devices are generally not suitable f...
The effect of cell morphology on light scattering is investigated using computer sim-ulations. A par...
In this invited paper we focus on the discussion of two recent unique applications of the Finite-Dif...
Scalar diffraction theory is not applicable to electromagnetic problems in which structural (light s...
The theoretical and numerical models for simulation of light propagation through a system of coupled...
The ®nite difference time domain method is used as a tool to model non-linear optical devices. Foll...
The Finite-Difference Time-Domain method has been applied to microwaves with successfully results. T...
In this paper we focus on the discussion of two recent unique applications of the finite-difference ...
Finite-Difference Time-Domain method (FDTD) is based on numerical solution of Maxwell's equations, n...
International audienceAn important issue in tissue optics and Optical Tomography is to have an effic...