Optical Engineering Science. Stephen Rolt. Читать онлайн. Newlib. NEWLIB.NET

Автор: Stephen Rolt
Издательство: John Wiley & Sons Limited
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Жанр произведения: Отраслевые издания
Год издания: 0
isbn: 9781119302810
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href="#ulink_958fe369-d396-51d2-9522-b8cfc042d6de">Eq. (4.2) using the binomial theorem. In the meantime collecting terms we get:

equation

      Before deriving the third order aberration terms, we examine the paraxial contribution which contain terms in h up to order r2.

      As one would expect, in the paraxial approximation, the optical path length is identical for all rays. However, for third order aberration, terms of up to order h4 must be considered. Expanding Eq. (4.2) to consider all relevant terms, we get:

      (4.5b)equation

      4.2.1 Aplanatic Points

Geometrical illustration of aplanatic points for refraction at single spherical surface.

      To be a little more rigorous, we might suppose that refractive index in object space is n1 and that in image space is n2. The location of the aplanatic points is then given by:

      (4.7)equation

      Fulfilment of the aplanatic condition is an important building block in the design of many optical systems and so is of great practical significance. As pointed out in the introduction, for those systems where the field angles are substantially less than the marginal ray angles, such as microscopes and telescopes, the elimination of spherical aberration and coma is of primary importance. Most significantly, not only does the aplanatic condition eliminate third order spherical aberration, but it also provides theoretically perfect imaging for on axis rays.

      Using the hyperhemisphere, we wish to create a ×20 microscope objective for a standard optical tube length of 200 mm. In this example, it is assumed that two thirds of the optical power resides in the hyperhemisphere itself; other components collimate the beam. In other words:

equation Geometrical illustration of a hyperhemisphere consisting of a sphere that has been truncated at one of the aplanatic points that also coincides with the object location.

      For a tube length of 200 mm, a ×20 magnification corresponds to an objective focal length of 10 mm. As two thirds of the power resides in the hyperhemisphere, then the focal length of the hyperhemisphere must