Optical: systems and elements – Lens – With support
Reexamination Certificate
2000-04-27
2001-09-18
Ben, Loha (Department: 2873)
Optical: systems and elements
Lens
With support
C359S819000, C126S571000, C126S700000
Reexamination Certificate
active
06292312
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to the field of optical lens systems, and specifically, to athermalized mounts for lenses to compensate for thermal image defects due to temperature changes.
2. Background Information
Typically, lenses are used in many applications such as in cameras and camcorders. However, lenses have a potentially serious limitation in those applications involving moderate changes in temperature. In particular, changes in temperature produce a shift of a lens image plane and can also modify the aberration balance of the lens from the nominal lens design at room temperature (referred to as “thermal image defects”). The ability to effectively compensate for thermal image defects (referred to as “athermalization”) opens the use of lenses to a large class of applications that do not permit active refocusing with variations in temperature.
The principal cause of these thermal image defects is the change in the refractive index of the lens material. The change in refractive index is called the dN/dT of the material and is typically −0.000120 per degree Centigrade for plastic lenses. For example, as the temperature increases, the refractive index for a plastic lens decreases which increases the focal length (since light is bent less) and the image plane of the plastic lens. Optical glasses, on the other hand, have dN/dT values in the +0.000003 per degree Centigrade range.
A secondary contributory factor for thermal image defects in lenses is due to the Coefficient of Thermal Expansion (“CTE”). As temperature increases, the radius of curvature of a lens becomes longer and its thickness increases. This causes the focal length to increase and thereby shift the image plane location further away from the lens. The CTE is much larger for plastic than glass. Consequently, thermal image defects is more severe in plastic lenses.
For optical systems that operate in the moderate to extreme temperature range, several solutions exist to athermalize for the degradation of image quality due to the change in the image plane location with temperature. Active athermalization involves using a motor to drive the lens or image plane as a function of temperature. As is apparent, this solution is undesirable because it requires power and adds to the cost of the lens system. Passive athermalization involves using a design that automatically corrects for the shift in the image plane with temperature.
One possible passive athermalization mechanism involves the combination of plastic materials and refractive power distributions in the lenses in a way that minimizes the thermal shift of focus and the change in aberration balance. This mechanism typically uses a hybrid glass/plastic lens design where most of the positive refractive power is vested in a glass element and the weakly-powered plastic elements are used for aberration balance. However, even for these hybrid glass/plastic lens designs, the thermal focal shift can be a serious concern and active focusing of the optical system is often the only real practical solution. Moreover, the use of a hybrid lens design requires a glass lens which increases cost.
FIG. 1
illustrates a simple singlet plastic lens element
10
. Referring to
FIG. 1
, the singlet plastic lens element
10
is made from acrylic (“PMMA”), has a f/2.0 relative aperture, and an effective focal length (“EFL”), L, to an image plane
12
, of 25.4 millimeters (“mm”). When the temperature is increased from +20° C. to +30° C., the distance of the image plane
12
from the rear vertex increases by &Dgr;L or +0.071 mm.
FIG. 2
illustrates a prior art athermalizing plastic lens element apparatus. Referring to
FIG. 2
, the plastic lens element
10
is the same as shown in FIG.
1
and is supported by a mechanical support element
14
which is made from a high expansive material (e.g., acrylic). As the temperature increases and the image plane shifts away from the lens element, the mechanical support element
14
expands axially in the −X direction (i.e., opposite to the shift of the image plane) to partially compensate for the movement of the image plane
12
. However, the compensation is almost always far from matching the image plane movement. For example, for a temperature increase from +20° C. to +30° C., the image plane increases by &Dgr;L or +0.071 mm and the mechanical support element expands axially in the −X direction by &Dgr;C or +0.019. The net result is an under compensation of 0.052 mm.
FIG. 3
illustrates another form of the prior art athermalized plastic lens element apparatus. In this embodiment, three nested cylindrical support elements are used to support the plastic lens element. Referring to
FIG. 3
, an inner cylinder
14
is made from a high expansive material (e.g., acrylic), a middle cylinder
16
is made from a low expansive material (e.g., Invar), and an outer cylinder
18
is made from a high expansive plastic. As temperature increases, the inner cylinder
14
expands axially in the −X direction as in FIG.
2
. The middle cylinder
16
has an almost zero CTE and does not expand with temperature. Similar to the inner cylinder
14
, the outer cylinder
18
expands axially in the −X direction to move the middle cylinder
16
in the −X direction which in turn further moves the inner cylinder
14
in the −X direction. In this embodiment, the inner and outer cylinders
14
and
18
both expand in an additive manner to effectively double the length of the axial expansion in the −X direction and provide greater compensation.
However, this embodiment usually cannot match the full image plane movement. For example, for a temperature increases from +20° C. to +30° C., this embodiment provides an axial compensation of &Dgr;C or +0.037 mm. The net result is still an under compensation of +0.034 mm. Moreover, as the inner cylinder
14
expands with temperature, it tends to lock up hard against the surface of the middle cylinder
16
. As the temperature decreases, the outer cylinder
18
contracts and tends to lock up against the surface of the middle cylinder
16
.
These comparisons were performed with only a +10° C. change in temperature. The results are even more dramatic with higher temperature changes. Thus, prior art solutions do not provide a sufficient compensation for thermal image defects. The problem is complicated by the fact that multiple lens systems typically tend to be very compact and there is not enough room between the lenses to provide a long enough mechanical support member to compensate for the thermal image defects.
Accordingly, there is a need in the art for a method and apparatus to effectively compensate for thermal image defects in lenses due to changes in temperature while maintaining a compact design.
SUMMARY OF THE INVENTION
The present invention is an athermalizing apparatus. In one embodiment, the athermalizing apparatus includes a lens element and a support member coupled to the lens element. The support member has a sloped outer surface and a first coefficient of thermal expansion (“CTE”). The athermalizing apparatus further includes a rib member having a sloped surface substantially complementary and adjacent to the sloped outer surface of the support member. The rib member has a second CTE.
REFERENCES:
patent: 4541415 (1985-09-01), Mori
patent: 4717227 (1988-01-01), Mori
patent: 4861137 (1989-08-01), Nagata
patent: 5283695 (1994-02-01), Ziph-Schatzberg et al.
patent: 5570238 (1996-10-01), Leary
patent: 6040950 (2000-03-01), Broome
Ben Loha
Blakely , Sokoloff, Taylor & Zafman LLP
Intel Corporation
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