Centration
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The mechanical axis and optical axis exactly coincide in a perfectly
centered lens. |
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Optical and Mechanical Axes |
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For a simple lens, the optical axis is defined as a straight line that
joins the centers of lens curvature. For a plano-convex or plano-concave
lens, the optical axis is the line through the center of curvature and
perpendicular to the plane surface. The mechanical axis is determined by the way in which the lens will be mounted during use. There are typically two types of mounting configurations, edge mounting and surface mounting. With edge mounting, the mechanical axis is the centerline of the lens mechanical edge. Surface mounting uses one surface of the lens as the primary stability for lens tip and then encompasses the lens diameter for centering. The mechanical axis for this type of mounting is a line perpendicular to the mounting surface and centered on the entrapment diameter. Ideally, the optical and mechanical axes coincide. The tolerance on centration is the allowable amount of radial separation of these two axes, measured at the focal point of the lens. The centration angle is equal to the inverse tangent of the allowable radial separation divided by the focal length. |
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Measuring Centration Error |
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Centration error is measured by rotating the lens on its mechanical axis
and observing the orbit of the focal point. The centration error (
qc) is then given by |
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where rorbit is the radius of
the focal orbit and f is the focal length
of the lens. |
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Centration and Orbit of Apparent Focus |
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Doublets and Triplets |
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It is more difficult to achieve a given centration specification for a
doublet than it is for a singlet because each element must be individually
centered to a tighter specification, and the two optical axes must be
carefully aligned during the cementing process. Centration is even more
complex for triplets because three optical axes must be aligned. The
centration error of doublets and triplets is measured in the same manner
as that of simple lenses. One method used to obtain precise centration in
compound lenses is to align the elements optically and edge the combination.
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Cylindrical optics can be evaluated for centering error in a manner
similar to simple lenses. The major difference is that cylindrical optics
have mechanical and optical planes rather than axes. The mechanical plane
is established by the expected mounting, which can be edge only or the
surface-edge combination described above. The radial separation between
the focal line and the established mechanical plane is the centering error
and can be converted into an angular deviation in the same manner as for
simple lenses. The centering error is measured by first noting the focal
line displacement in one orientation, then rotating the lens 180 degrees
and noting the new displacement. The centering error angle is the inverse
tangent of the total separation divided by twice the focal length. |
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| Optics Guide © 2004 Melles Griot Inc. |