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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P2. Finally, since the object ray and dummy rays are parallel in object space, they must meet at the second focal plane in the image space. Therefore, we can trace the image ray to point P2, providing a complete definition of the path of the ray in image space.

Illustration of system focal lengths. Illustration of tracing the output path of any input ray.

      1.3.6 Angular Magnification and Nodal Points

Illustration of angular magnification and nodal points. The first nodal point is located in object space and the second nodal point is located in image space.

      1.3.7 Cardinal Points

      This brief description has provided a complete definition of an ideal optical system. No matter how complex (or simple) the optical system, this analysis defines the complete end-to-end functionality of an ideal system. On this basis, an optical designer will specify the six cardinal points of a system to describe the ideal behaviour of a design. These six cardinal points are:

       First Focal Point

       Second Focal Point

       First Principal Point

       Second Principal Point

       First Nodal Point

       Second Nodal Point

      The principal and nodal points are co-located if the two system focal lengths are identical.

      1.3.8 Object and Image Locations - Newton's Equation

      Referring to Figure 1.11 and by using similar triangles it is possible to derive two separate relations for the magnification h2/h1:

equation Illustration of the relationship between a generalised object and image.

      And:

      1.3.9 Conditions for Perfect Image Formation – Helmholtz Equation

      Thus far, we have presented a description of an idealised optical system. Is there a simple condition that needs to be fulfilled in order to generate such an ideal image? It is easy to see from Figure 1.11 that the following relations apply:

equation

      Therefore:

equation

      As we will be able to show later, the ratio f2/f1 is equal to the ratio of the refractive indices, n2/n1, in the two media (object and image space). Therefore it is possible to cast the above equation in its more usual form, the Helmholtz equation:

      One important consequence of the Helmholtz equation is that there is a clear, inextricable linkage between transverse and angular magnification. Angular magnification is inversely proportional to transverse magnification. For small θ, tan θ and θ are approximately equal. So in the small signal approximation, the angular magnification, α is given by:

equation

      Hence:

      (1.9)equation

      We have, thus far, introduced two different types of optical magnification – transverse and angular. There is a third type of magnification that we need to consider, longitudinal magnification. Longitudinal