6: Scalar diffraction optics

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6.1: What you should know and be able to do after studying this chapter
6.2: Introduction
6.3: Angular Spectrum Method
6.4: Rayleigh-Sommerfeld Diffraction Integral
6.5: Intuition for the Spatial Fourier Transform in Optics
6.6: Fresnel and Fraunhofer Approximations
6.7: Fraunhofer Diffraction Revisited
Fraunhofer diffraction patterns can qualitatively explained by considering directions in which destructive and constructive interference occurs
6.8: Fourier Optics
In this section we apply diffraction theory to a lens. We consider in particular the focusing of a parallel beam and the imaging of an object.
6.9: Super-resolution
It should be clear by now that beating the diffraction limit is extremely difficult. Nevertheless, a lot of research in optics has been and still is directed towards realising this goal. Many attempts have been made, some successful, others not so, but, whether successful or not, most were based on very ingenious ideas. To close this chapter on diffraction theory, we will give examples of attempts to achieve what is called super-resolution.

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