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4.8 Hierarchy of Aberrations
ОглавлениеFor some specific applications, such as telescope and microscope objective lenses, the field angles tend to be very much smaller than the angles associated with the system numerical aperture. In these instances, the off-axis aberrations, such as coma, are much less significant than the on-axis aberrations. Therefore, as far as the Gauss-Seidel aberrations are concerned, there exists a hierarchy of aberrations that can be placed in order of their significance or importance:
1 Spherical Aberration
2 Coma
3 Astigmatism and Field Curvature
4 Distortion
That is to say, it is of the greatest importance to correct spherical aberration and then coma, followed by astigmatism, field curvature, and distortion. This emphasises the significance and use of aplanatic elements in optical design.
Of course, for certain optical systems, this logic is not applicable. For instance, in both camera lenses and in eyepieces, the field angles are very substantial and comparable to the angles associated with the numerical aperture. Indeed, in systems of this type, greater emphasis is placed upon the correction of astigmatism, field curvature, and distortion than in other systems.
With these comments in mind, it would be useful to summarise all the aberrations covered in this chapter and to classify them by virtue of their pupil and field angle dependence. Table 4.1 sets out the wavefront error dependence upon pupil and field angle for each of the aberrations.
It would be instructive, at this point, to take the example of the 200 mm doublet and to plot the wavefront aberrations attributable to some of the aberrations listed in Table 4.1 against numerical aperture. Spherochromatism is expressed as the difference in spherical aberration wavefront error between the nF and nC wavelengths (486.1 and 656.3 nm). Secondary colour is expressed as the wavefront error attributable to the difference in defocus between the nF and nD wavelengths (486.1 and 589.3 nm). A plot is shown in Figure 4.28.
It is clear that for the simple achromat under consideration, at least for modest lens apertures, the impact of secondary colour predominates. If a wavefront error of about 50 nm is consistent with ‘high quality’ imaging, then secondary colour has a significant impact for numerical apertures in excess of 0.05 or f#10. With numerical apertures in excess of 0.2 (f#2.5), higher order spherical aberration starts to make a significant contribution. On the other hand the effect of spherochromatism is more modest throughout. In this context, the impact of spherochromatism would only be a significant issue if secondary colour were first corrected.
Table 4.1 Pupil and field dependence of principal aberrations.
Aberration | Pupil exponent | Field angle exponent |
Defocus | 2 | 0 |
Spherical aberration | 4 | 0 |
Coma | 3 | 1 |
Astigmatism | 2 | 2 |
Field curvature | 2 | 2 |
Distortion | 1 | 3 |
Lateral colour | 1 | 1 |
Longitudinal colour | 2 | 0 |
Secondary colour | 2 | 0 |
Spherochromatism | 4 | 0 |
5th order spherical aberration | 6 | 0 |
Figure 4.28 Contribution of different aberrations vs. numerical aperture for 200 mm achromat.
Of course, in practice, the design of such lens systems will be accomplished by means of ray tracing software or similar. Nonetheless, an understanding of the basic underlying principles involved in such a design would be useful in the initiation of any design process.