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Transcript
The calculation of focal length using the
nodal slide
University of Arizona
Yen-Te Lee
OPTI 521, Fall 2008
1
Optical Spaces
Each space (object or image) extends from -∞ to +∞ for
each optical surface being encountered.
Gaussian Imagery is a collinear transformation mapping the
object plane to the image plane. And Cardinal points
result.
Use paraxial analysis for the Gaussian properties of optical
system.
2
Cardinal points and planes
Completely describe the focal mapping and defined by
specific magnifications.
Focal length is the direct
distance from principal
plane to focal point.
3
Cardinal points and planes-continue
Nodal planes have the characteristic of identity angular
magnification.
When the optical system is in air, nodal points/planes
coincide with the principal points/planes.
Principal points/planes can be described using Newtonian
equations or Gaussian equations which measure the
distances from focal planes or principal planes
respectively. (Here the Gaussian equations are used)
4
Gaussian equations
Describe the focal mapping with respect to principal planes.
Use similar triangles to analysis the properties of the optical
system.
5
Locations of nodal points/planes
Ray 1 and 2 must be parallel in image space, since their
conjugate rays cross in the front focal plane.
The distances from principal planes to respect nodal planes
are equal due to similar and identical triangles.
6
Longitudinal magnification
The thickness magnification of pairs of conjugate planes is
the thickness in image plane, ΔZ’ divided by the
thickness in object plane, ΔZ.
For infinitesimal thickness, the longitudinal magnifications
is obtained. K=1 for the optical system in air.
7
Angular magnification of nodal
points/planes
Use the thickness magnification, the angular magnification,
mN is 1 for the optical system in air (K=1).
This is the mechanism to set up the experiment finding the
focal length of an optical system.
8
Nodal slide
Allows the principal planes and the focal length to be
experimentally determined.
When the system rotates about its rear nodal point, N’, the
rays will converge to the same point. Thus, the image
will not move.
9
Calculating the focal length
The focal length of the optical system can be determined by
f=f’R=BFD-d’
where BFD is the back focal distance of the system
d’ is the distance from rear vertex of the system
to the rear nodal point (rear principal point) of
the system.
10