Rayleigh distance

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Rayleigh distance in optics is the axial distance from a radiating aperture to a point at which the path difference between the axial ray and an edge ray is λ / 4. An approximation of the Rayleigh Distance is ${\displaystyle Z=\frac{D^2}{2\lambda }}$, in which Z is the Rayleigh distance, D is the aperture of radiation, λ the wavelength. This approximation can be derived as follows. Consider a right angled triangle with sides adjacent ${\displaystyle Z}$, opposite ${\displaystyle \frac{D}{2}}$and hypotenuse ${\displaystyle Z+\frac{\lambda }{4}}$. According to Pythagorean theorem,

${\displaystyle {(Z+\frac{\lambda }{4})}^2=Z^2+{\left(\frac{D}{2}\right)}^2}$.

Rearranging, and simplifying

${\displaystyle Z=\frac{D^2}{2\lambda }-\frac{\lambda }{8}}$

The constant term${\displaystyle \frac{\lambda }{8}}$ can be neglected.

In antenna applications, the Rayleigh distance is often given as four times this value, i.e. ${\displaystyle Z=\frac{2D^2}{\lambda }}$^[1] which corresponds to the border between the Fresnel and Fraunhofer regions and denotes the distance at which the beam radiated by a reflector antenna is fully formed (although sometimes the Rayleigh distance it is still given as per the optical convention e.g.^[2]).

The Rayleigh distance is also the distance beyond which the distribution of the diffracted light energy no longer changes according to the distance Z from the aperture. It is the reduced Fraunhofer diffraction limitation.

Lord Rayleigh's paper on the subject was published in 1891.^[3]

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