1. Field of the Invention
This invention relates generally to an ultra-broadband ultraviolet (UV) catadioptric imaging microscope system, and more specifically to an imaging system that comprises a UV catadioptric objective lens group and a wide-range zooming tube lens group.
2. Description of the Related Art
Catadioptric imaging systems for the deep ultraviolet spectral region (about 0.19 to 0.30 micron wavelength) are known. U.S. Pat. No. 5,031,976 to Shafer and U.S. Pat. No. 5,488,229 to Elliott and Shafer disclose two such systems. These systems employ the Schupmann achromatic lens principle and the Offner-type field lens. Axial color and primary lateral color are corrected, but not higher order lateral color. This is the limiting aberration in these systems when a broad spectral range is covered.
The above-noted '976 Shafer patent discloses an optical system based on the Schupmann achromatic lens principle which produces an achromatic virtual image. A reflective relay then creates an achromatic real image from this virtual image. The system, reproduced here as
Longitudinal chromatic aberration (axial color) is an axial shift in the focus position with wavelength. The prior art system seen in
U.S. patent application Ser. No. 08/681,528, filed Jul. 22, 1996, is for a catadioptric UV imaging system with performance improved over the systems of the above-describe patents. This system employs an achromatized field lens group to correct for secondary and higher order lateral color, which permits designing a high NA, large field, ultra-broadband UV imaging system.
Zooming systems in the visible wavelengths are well-known. They either do not require very high levels of correction of higher-order color effects over a broad spectral region, or do require correction, but accomplish this by using three or more glass types. In the deep UV, there are very few materials that can be used for chromatic aberration correction, making the design of high performance, broadband optics difficult. It is even more difficult to correct for chromatic aberrations for ultra-broadband optics with wide-range zoom.
There remains, therefore, a need for an ultra-broadband UV microscope imaging system with wide-range zoom capability.
The present invention has an object to provide a catadioptric imaging system which corrects for image aberrations, chromatic variation of image aberrations, longitudinal (axial) color and lateral color, including residual (secondary and higher order) lateral color correction over an ultra-broad spectral range in the near and deep UV spectral band (0.2 to 0.4 micron).
Another object is to provide an UV imaging system, useful as a microscope or as micro-lithography optics, with a large numerical aperture of 0.9 and with a field of view of at least one millimeter. The system is preferably tele-centric.
The invention is a high performance, high numerical aperture, ultra-broad spectral region catadioptric optical system with zooming capability, comprising an all-refractive zooming tube lens section with one collimated conjugate, constructed so that during zooming its higher-order chromatic aberrations (particularly higher-order lateral color) do not change; and a hon-zooming high numerical aperture catadioptric objective section which compensates for the uncorrected (but stationary during zoom) higher-order chromatic aberration residuals of the zooming tube lens section.
These and other objects and advantages of the present invention will become apparent to those skilled in the art from the following detailed description and accompanying drawings.
The focusing lens group 11 in
The five lenses 23-27 of the main focusing subgroup consist of a thick strong negative meniscus lens 23, an opposite-facing strongly-curved negative meniscus lens 24, a strong bi-convex lens 25, a strong positive meniscus lens 26, and an opposite-facing strongly-curved, but very weak, meniscus lens 27 of either positive or negative power. Variations of this lens 23-27 subgroup are possible. The subgroup focuses the light to an intermediate image 13. The curvature and positions of the lens surfaces are selected to minimize monochromatic aberrations and to cooperate with the doublet 21-22 to minimize chromatic variations of those aberrations.
The field lens group 15 typically comprises an achromatic triplet, although any achromatized lens group can be used. Both fused silica and CaF2 glass materials are used. Other possible deep UV transparent refractive materials can include MgF2, SrF2, LaF3 and LiF glasses, or mixtures thereof. In addition to refractive materials, diffractive surfaces can be used to correct chromatic aberrations. Because the dispersions between the, two UV transmitting materials, CaF2 glass and fused silica, are not very different in the deep ultraviolet, the individual components of the group 15 have strong curvatures. Primary color aberrations are corrected mainly by the lens elements in the catadioptric group 17 in combination with the focusing lens group 11. Achromatization of the field lens group 15 allows residual lateral color to be completely corrected.
The catadioptric group 17 of
The first lens 39 has a hole 37 centrally formed therein along the optical axis of the system. The reflective coating 41 likewise ends at the central hole 37 leaving a central optical aperture through which light can pass unobstructed by either the lens 39 or its reflective coating 41. The optical aperture defined by the hole 37 is in the vicinity of the intermediate image plane 13 so that there is minimum optical loss. The achromatic field lens group 15 is positioned in or near, the hole 37. The second lens 43 does not normally have a hole, but there is a centrally located opening or window 47 where the coating is absent on the surface reflective coating 45. The optical aperture in lens 39 with its reflective coating 41 need not be defined by a hole 37 in the lens 39, but could be defined simply by a window in the coating 41 as in coating 45. In that case, light would pass one additional time through the refractive surfaces of lens 39.
Light from the source transmitted along the optical axis toward the intermediate image plane 13 passes through the optical aperture 37 in the first lens 39 and then through the body of the second lens.43 where it is reflected by the near planar (or planar) mirror coating 45 back through the body of the second lens 43. The light then passes through the first lens 39, is reflected by the mirror surface 41 and passes back through the first lens 39. Finally the light, now strongly convergent passes through the body of the second lens 43 for a third time, through the optical aperture 47 to the target image plane adjacent aperture 47. The curvatures and positions of the first and second lens surfaces are selected to correct primary axial and lateral color in conduction with the focal lens group 11.
For a flexible deep UV microscope system, it is important to provide various magnifications, numerical apertures, field sizes, and colors. In principle, an UV microscope system can comprise several catadioptric objectives, tube lenses, and zoom lenses. However, several problems are encountered when designing a complete microscope system. First, the microscope design needs to accommodate many large size catadioptric objectives to provide different magnifications and numerical apertures. Seconds, in order to maintain image quality, chromatic variation of aberrations of each tube lens must be corrected to the same degree as the objective itself. Third, the chromatic variation of aberrations of a zooming system must be corrected over the full range of zoom. These problems are addressed by the present invention.
An ultra-broadband UV microscope imaging system according to the present invention as illustrated in
The catadioptric objective section 128 is optimized for ultra-broadband imaging in the UV spectral region (about 0.20 to 0.40 micron wavelength). It has excellent performance for high numerical apertures and large object fields. This invention uses the Schupmann principle in combination with an Offner field lens to correct for axial color and first order lateral color, and an achromatized field lens group to correct the higher order lateral color. The elimination of the residual higher order chromatic aberrations makes the ultra-broadband UV objective design possible.
The catadioptric lens group 122 includes a near planar or planar reflector 123, which is a reflectively coated lens element, a meniscus lens 125, and a concave spherical reflector. Compared to the reflectively coated lens element 39 in
The achromatic multi-element field lens group 127 is made from two or more different refractive materials, such as fused silica and fluoride glass, or diffractive surfaces. The field lens group 127 may be optically coupled together or alternatively may be spaced slightly apart in air. Because fused silica and fluoride glass do not differ substantially in dispersion in the deep ultraviolet range, the individual powers of the several component element of the field lens group need to be of high magnitude. Use of such an achromatic field lens allows the complete correction of axial color and lateral color over an ultra-broad spectral range. In the simplest version of the design, only one field lens component need be of a refractive material different than the other lenses of the system. Compared to group 15 in
The present invention has a focusing lens group 129 with multiple lens elements, preferably all formed from a single type of material, with refractive surfaces having curvatures and positions selected to correct both monochromatic aberrations and chromatic variation of aberrations and focus light to an intermediate image. In the focusing lens group-129 a special combination of lenses 130 with low power corrects the system for chromatic variation in spherical aberration, coma, and astigmatism.
Design features of the field lens group 127 and the low power group 130 are key to the present invention. The zooming tube lens. 139 combined with the catadioptric objective 1.28 provides many desirable features. Such an all-refractive zooming lens ideally will allow the detector array 140 to be stationary during zooming, although the invention is not limited to this preferred embodiment. Assuming that the catadioptric objective system 128 does not also have any zooming function, there are two design possibilities open to the zooming tube lens system 139.
First, the zooming section 139 can be all the same refractive material, such as fused silica, and it must be designed so that primary longitudinal and primary lateral color do not change during zooming. These primary chromatic aberrations do not have to be corrected to zero, and cannot be if only one glass type is used, but-they have to be stationary, which is possible. Then the design of the catadioptric objective 128 must-be modified to compensate for these uncorrected but stationary chromatic aberrations of the zooming tube lens. This can be done, but a solution is needed with good image quality. Despite the limited image quality, this design possibility is very desirable since the whole combined microscope system is a single material, i.e., fused silica, except for the calcium fluoride or a diffractive surface in the achromatized Offner-type field lens.
Second, the zooming tube lens group 139 can be corrected for aberrations independently of the catadioptric objective 128. This requires the use of at least two refractive materials with different dispersions, such as fused silica and calcium fluoride, or diffractive surfaces. Unfortunately, the result is a tube lens system that, because of unavoidable higher-order residuals of longitudinal and lateral color over the entire zoom range, is not capable of high performance over a very broad UV spectral region. Compromises must then be made in the form of reducing the spectral range, the numerical aperture, the field size of the combined system, or some combination of these compromises. The result is that-the very high capabilities of the catadioptric objective cannot be duplicated with an independently corrected zooming tube lens.
The present invention straddles the two situations just described. The zooming tube lens 139 is first corrected independently of the catadioptric objective 128, using two refractive materials (such as fused silica and calcium fluoride). Lens 139 is then combined with the catadioptric objective 128 and then the catadioptric objective is modified to compensate for the residual higher-order chromatic aberrations of the zooming tube lens system. This is possible because of the design features of the field lens group 127 and the low power lens group 130 of the catadioptric objective described earlier. The combined system is then optimized with all parameters being varied to achieve the best performance.
One unique feature of the present invention is the particular details of the zooming tube lens. If the higher-order residual chromatic aberrations of this zooming system change during zoom, then the catadioptric objective cannot exactly compensate for them except at one zoom position. It is easy to design a zooming tube lens system where the low-order chromatic aberrations do not change during zoom, and are corrected to zero as well. But it is very difficult to find a zooming tube lens design where the higher-order chromatic aberration residuals (which are uncorrectable to zero, in that system by itself) do not change during the zooming.
A tube lens section can be designed such that its higher-order chromatic aberrations do not change by any significant amount during zoom. If the detector array 140 is allowed to move during zoom, then the design problem becomes much easier, but that is not nearly as desirable as having an image position fixed relative to the rest of the system.
The imaging system of the invention provides a zoom from 36.times. to 100.times. and greater, and integrates objectives, turret, tube lenses (to provide more magnifications) and zoom optics into one module. The imaging system reduces optical and mechanical components, improves manufacturability and reduces production costs. The imaging system has several performance advantages such as: high optical resolution due to deep UV imaging, reduced thin film interference effects due to ultra-broadband light, and increased light brightness due to integration of ultra-broad spectral range. The-wide range zoom provides continuous magnification change. The fine zoom reduces aliasing and allows electronic image processing, such as cell-to-cell subtraction for a repeating image array. By placing an adjustable aperture in the aperture stop of the microscope system one can adjust the NA and obtain the desired optical resolution and depth of focus. The invention is a flexible system with an adjustable wavelength, an adjustable bandwidth, an adjustable magnification, and an adjustable numerical aperture.
There are three possible embodiments of zoom lenses. The first embodiment provides linear zoom motion with a fixed detector array position. The second embodiment provides linear zoom motion with a moving detector array position. The third embodiment, in addition to zoom lenses, utilizes folding mirrors to reduce the physical length of the imaging system and fix the detector array position.
The first embodiment of zoom lenses provides linear zoom motion with a fixed detector array position.
Lens Data for the First Embodiment 0.90 N.A., fixed detector, 36.times.-100.times. zoom, 1.0 mm field size
The second embodiment of zoom lenses provides linear zoom motion with a moving detector array position and
Lens Data for the Second Embodiment 0.90 N.A., moving detector, 36.times. to 100.times. zoom, 1.0 mm field size
The third embodiment of zoom lenses provides linear zoom motion with a fixed sensor position by using the same lens design as the second embodiment and incorporating a “trombone” system of reflective elements so that the detector array does not move.
Module Transfer Function curves (not shown) indicate that the
The exemplary embodiments described herein are for purposes of illustration and are not intended to be limiting. Therefore, those skilled in the art will recognize that other embodiments could be practiced without departing from the scope and spirit of the claims set forth below.
This application is a continuation in part of co-pending U.S. patent application Ser. No. 09/046,814, entitled “High NA System for Multiple Mode Imaging,” filed on Mar. 24, 1998, which is a continuation in part of U.S. Pat. No. 5,999,310, entitled “Ultra-Broadband UV Microscope Imaging System with Wide Range Zoom Capability,” filed on Aug. 7, 1997, which is a continuation in part of U.S. patent application Ser. No. 08/681,528, entitled “Broad Spectrum Ultraviolet Catadioptric Imaging System,” filed on Jul. 22, 1996, all of which are hereby incorporated by reference.
Number | Date | Country | |
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Parent | 10282592 | Oct 2002 | US |
Child | 10958242 | Oct 2004 | US |
Parent | 09571109 | May 2000 | US |
Child | 10282592 | Oct 2002 | US |
Number | Date | Country | |
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Parent | 09046814 | Mar 1998 | US |
Child | 09571109 | May 2000 | US |
Parent | 08908247 | Aug 1997 | US |
Child | 09046814 | Mar 1998 | US |
Parent | 08681528 | Jul 1996 | US |
Child | 08908247 | Aug 1997 | US |