Hyperbolic Lenses: Abberation-Free?

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Hyperbolic lenses are not free of aberration, as they still exhibit chromatic aberrations, while spherical aberrations are nearly eliminated. Theoretical discussions suggest that no lens shape can be completely free of all aberrations, including spherical, coma, astigmatism, distortion, and curvature of field. Parabolic lenses can eliminate spherical aberration but do not address the others. Lenses can achieve diffraction-limited performance for specific object distances and wavelengths, and achromatic lenses can minimize chromatic aberration within certain ranges. Ultimately, while advanced lenses reduce aberrations significantly, complete aberration-free lenses do not exist for all conditions.
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Are hyperbolic lenses free of abberation?
 
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They still have chromatic abberations, but the spherical abberations are virtually non existant.
 
Theoretically speaking, what shape of a convergent lens (that focuses rays onto a single point) is free of abberation?

Does such shape/surface exist?
 
There are five 3rd order geometric aberrations; Spherical, Coma, Astigmatism, Distortion and Curvature of Field. A parabolic lens will eliminate spherical aberration, but not the others.

You can get lenses whose aberrations are less than the diffraction limited spot, in other words the lenses are so good that imperfections are washed out by diffraction. Such lenses are only optimised to a particular object distance and focal length, so you can't get lenses that are aberration free for an arbitrary object distance.

Chromatic aberrations are still present in the lens, you can get lenses called achromats (or achromatic lenses) that are virtually chromatic aberration free within a particular wavelength range.

To summarise, you can get diffraction-limited lenses, but only for a particular object distance and a particular wavelength range.

Claude.
 
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