1. Spatial distribution of light intensity
To deduce the light intensity at any point in space, we need to know the total amplitude of the electric field . The aim here is to detail the reasoning that simplifies the calculation of this amplitude, and which forms the basis of all applications in Fourier optics.
1.1 Total intensity and amplitude of the light wave
Light propagates thanks to variations in electromagnetic potential, which create an electric field
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Spatial distribution of light intensity
Bibliography
Works
LAUG (M.) – Optical Signal and Image Processing. CEPADUES Éditions (1980).
MARAIS (B.) – Exercices d'optique de Fourier. Dunod Université (1980).
FRANÇON (M.) – Holography. Masson et Cie (1969).
Reviews
Numerous industrial applications in Fourier optics "Photonics https://www.photoniques.com/
Software tools (non-exhaustive list)
Imagej" image processing software https://imagej.nih.gov/ij/
A "Numerical wave propagation" plug-in in Imagej enables simulation of the very near and near-field transformation. An article is dedicated to this plugin: Piedrahita-Quintero P, Castañeda R, Garcia-Sucerquia, Numerical wave propagation in ImageJ,...
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