The theory and design of zoom lenses
Abstract
This thesis contains a new approach to the paraxial and
third order design and theory of zoom lenses, especially those consisting
of thin elements. Equations describing the paraxial and
third order behaviour of zoom lenses are derived and are used to
design a series of three element zoom lenses.
In the paraxial theory the derivatives, with respect to the
axial separations, of the paraxial coefficients are required.
Optimization processes for the automatic design of lenses require the
availability of the derivatives, with respect to axial separations and
curvatures, of the third and fifth order aberration coefficients.
These derivatives can be calculated from formulae given herein and
these form the basis of a FORTRAN programme for calculating such
derivatives.
The derivatives, with respect to axial separations, of the
paraxial coefficients, occur in the formulae describing the paraxial
properties as functions of the zoom parameter. These formulae may be
solved to obtain the powers and initial (z = 0) separations of the
elements of the zoom lens. For two and three element zoom lenses the
equations are solved analytically. Formulae are obtained for the third order aberration coefficients
as functions of the zoom parameter. Using the thin lens
approximation the shapes of the individual elements are introduced and
from the resulting expressions sets of simultaneous equations are
obtained in the particular case of the three (thin) element zoom lens.
The solutions of these sets of equations give zoom systems for which selected third order aberrations are substantially corrected over the
whole zoom range. Whereas optimization processes give one solution to
a particular problem, the present method gives all possible solutions
by a simple analytic or semi-analytic approach.
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