Approved For Release 2005/11/21 : CIA-RDP78B04770A0015000600 DESIGN OF DOUBLE GAUSS SYSTEMS USING ASPHERICS by May 1967 NGA Review Complete Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 DESIGN OF DOUBLE GAUSS SYSTEMS USING ASPHERICS by Submitted in Partial Fulfillment of the Requirements for the Degree Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  STAT Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 The author wishes to acknowledge for the assistance he has given throughout this study. The author is also deeply indebted to the for the use of their computer without which this project may not have been possible. The final form of this thesis was prepared under Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 Page I. Introduction ................................. 1 Ii. Background of the Double Gauss Design ........ 3 III. Original Lens ................................ 5 IV. Optimized Spherical System -- Lens 1 ......... 7 V. Aspherics on Outer Surfaces -- Lens 2 ........ 11 VI. Aspherics on Inner Surfaces -- Lens 3 ........ 15 VII. Aspheric Corrector Plate -- Lens 4 ........... 19 VIII. Another Double Gauss System .................. 23 IX. Image Evaluation Techniques .................. 25 X. Conclusions .................................. 28 XI. Bibliography ................................. 41 Appendix I .................................... 42 Appendix II .................................. 45 Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 Page TABLE 1 -- Design Specifications for Lens 1. 8 TABLE 2 -- Design Specifications for Lens 2. 13 TABLE 3 -- Design Specifications for Lens 3. 17 TABLE 4 -- Design Specifications for Lens 4. 20 TABLE 5 -- Kidger-Wynne Spherical Design. 24 TABLE 6 -- Comparative Resolution Limits for Various Double Gauss Designs. 30 TABLE 7 -- Image Errors Used in FLAIR. 42 Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 Page FIGURE 1 -- Lens 1 - Optimized Spherical Lens. 9 FIGURE 2 -- Lens 2 - Aspherics on Outer Surfaces. 14 FIGURE 3 -- Lens 3 - Aspherics on Inner Surfaces. 18 FIGURE 4 -- Lens 4 - Aspheric Corrector Plate. 21 FIGURE 5 -- Transverse Aberration Plots for Lens 1. 31 FIGURE 6 -- Geometrical Frequency Response for Lens 1. 32 FIGURE 7 -- Transverse Aberration Plots for Lens 2. 33 FIGURE 8 -- Geometrical Frequency Response for Lens 2. 34 FIGURE 9 -- Transverse Aberration Plots for Lens 3. 35 FIGURE 10 -- Geometrical Frequency Response for Lens 3. 36 FIGURE 11 -- Transverse Aberration Plots for Lens 4. 37 FIGURE 12 -- Geometrical Frequency Response for Lens 4. 38 FIGURE 13 -- Transverse Aberration Plots for Kidger-Wynne Spherical Design. 39 FIGURE 14 -- Geometrical Frequency Response for Kidger-Wynne Spherical Design. 40 Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 The following is a study of the use of aspheric surfaces in a Double Gauss photographic objective. In addition to gaining some general familiarity with the design of optical systems using large electronic com- puters, the author has attempted to determine the im- provement in image quality that might be realized through the use of one or two aspheric surfaces, and to make some recommendations regarding the optimum location of the aspherics in the lens. The Double Gauss lens was chosen because of its basic symmetrical shape, and most conclusions stated here would apply equally well to other objectives of similar form. Four major design efforts will be presented in this paper. These approaches differ in the use of the aspheric surfaces. In many designs, the aspheric surfaces are placed close to the aperture stop where they can be used to correct spherical aberration without affecting the off-axis aberrations. The four basic designs dis- cussed in this report include an optimized spherical lens and three lenses incorporating aspheric surfaces (a) on the outside surfaces of the lens, (b) on the inside surfaces surrounding the aperture stop, and (c) on one surface of an aspheric corrector plate at the stop. All design in this study has been aimed at achieving reasonably observable modulation at high frequencies. In Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 2 order to accomplish this, emphasis has been placed on the realization of an image with a tight core at the expense of having to accept some larger flare. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 BACKGROUND OF THE DOUBLE GAUSS DESIGN The Double Gauss lens is typical of many varieties of photographic objectives being generally symmetrical about an aperture stop in the center of the lens. The original design work was done early in the nineteenth century by C. F. Gauss, who "discovered that if a tele- scope objective is made with meniscus crown and flint elements separated by a small air gap having the shape of a negative lens, the variation of spherical aberration with wavelength could be eliminated."1 In 1888, A. Clark suggested combining together two similar Gauss objectives surrounding a central stop. Typical early examples were the Ross Homocentric, the Meyer Aristostigmat, and the Kodak Wide-Field Ektars, which operated at f/6.3 over a total field of 701. A great contribution to indoor photography was realized in 1920, when H. W. Lee designed the Opic lens, which covered a total field of 48? at f/2. This lens incorporated two additional cemented surfaces and, thus, a total of six elements. Examples of this type were the Zeiss Biotar, the Leitz Summar, and the Kodak Ektar. "With the advent of rare-earth glass having a very high refractive index, the type has been still further improved, 1Kingslake, R., Lenses In Photography, A. S. Barnes and Co., Inc., New York, 1963, p. 144. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 4 as in the 7" f/2.5 Aero Ektar; and the Kodak Cine Ektar f/1.4 of the same general type is excellent for 16 milli- meter motion picture photography. For taking 35 milli- meter motion pictures, such modern lenses as the Cooke Speed Pancho f/2 and the Bausch & Lomb Baltar f/2.3 are of this same fundamental type, and so are the best high aperture motion picture projection lenses such as the Super Cinephor f/2 and the Super Snaplite f/1.9."2 Very recently the Leitz Company of Wetzlar, West Germany have announced the production of a f/1.2, 50 millimeter focal length Double Gauss lens using aspheric surfaces.3 This lens, called the Noctilux, is the first high speed aspheric lens to be mass-produced. It is to be used with the Leica M2 or M3 body for 35 millimeter photography. Although no design specifications were re- ported, the lens is said to make use of new glasses of very high refractive index. The number or position of the aspheric surfaces was not given, but the lens is to be sold for $678.4 2Kingslake, R., Lenses In Photography, A. S. Barnes and Co., Inc., New York, 1963, p. 144. 3Crawley, Geoffrey, "The Aspheric f/1.2 50 mm Leitz Noctilux," The British Journal of Photography, October 7, 1966, pp. 882-885. 4Desfor, Irving, "No-Flash Nighttime Lens," Christian Science Monitor, February, 1967, p.7. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 sity of All design in this study was done using the Univer- lens design program FLAIR on the IBM 7044 computer at The starting point of the design was a six element Double Gauss system designed on the ORDEALS program. The system under consideration was a 10 centimeter focal length lens operating at f/2.1 and covering a total field of 42 degrees. It was specified to function at a magnifi- cation of -0.05, and a vignetting factor of 0.79 was allowed at the zone and 0.70 at the margin. This lens was typical of the Double Gauss type, basically symmetric, composed of two groups of three ele- ments centered about the aperture stop. Each group was composed of one single element and a cemented doublet. All surfaces were spherical in shape. The glasses used were not catalogue glasses, but were very close to the Schott glasses, SK 16, BAF14 10, SF 2, and F 2. Thus, these glasses have been used throughout the further design efforts. Note that the meniscus crown and flint elements, described by Gauss in his original design theory, are SK 16 and SF 2, in this design. BAFN 10 is a new glass with high refractive index. Both the ray trace curves and the geometrical fre- quency response show the lens to have poor resolution. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 6 The axial response suffers predominantly from spherical aberration, while the off-axis performance deteriorates from large coma and astigmatism. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 The first attempt at improving the original lens in- volved the use again of only spherical surfaces. All radii and thicknesses were allowed to vary. A trial run was made in which most of the group one and all the group two image aberrations5 were minimized. The program was successful in this effort as the merit function, composed of the sums of the squares of all these image aberrations, weighted evenly, was reduced by a factor of ten. The basic shape of the lens remained unchanged. Nevertheless, this design using minimization of the image aberrations had a great deal of spherical aberration and a curved tangential field which governed both the axial and off-axial response. The resolution of this lens was lower than that of the original lens. Thus, it could be concluded that this technique of straight minimization of all aberrations is not an adequate approach to the design of an improved system. In a second attempt at improving the spherical lens system, the mean square deviations of the wavefront from a perfect reference sphere were minimized. In addition, 5A11 aberration numbers refer to the FLAIR program. Group one aberrations, numbers 1-16, 18, and group two aberrations, 1-12,were minimized. Only certain color aberrations were omitted. Hereafter, image aberrations will be referred to in the form 1.5-8, where 1 represents the group number and 5-8, the aberration numbers in that group. An explicit interpretation of these image aber- rations is given in Appendix I. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 8 the distortion at full field (1.9), the axial color at 0.7 of the aperture (1.16), and the lateral color at 0.7 of the field (1.18) were corrected to zero. Again all the radii and both glass and air thicknesses were allowed to vary. In order to force more correction off axis, rela- tive weightings of 0.75, 1.0, and 1.0 were given to the axial case, the 0.7 field, and the edge, respectively. The resulting design was again similar in shape, although it became somewhat shorter. The lens, however, showed great improvement in image quality. The ray trace curves (see Fig. 5, page 31) showed none of the large coma present in the original design and much less field curvature. The lens, in general, is well corrected except for the spherical aberration, which limits the axial resolution and some astigmatism evident at off-axis points. The geometrical frequency response corresponding to this design is shown in Fig. 6, page 32. SURFACE CURVATURE THICKNESS GLASS 1 0.1999 0.626 SK 16 2 0.0790 0.010 AIR 3 0.3106 1.020 BAFN 10 4 0.0261 0.171 SF 2 5 0.4377 1.394 AIR 6 S 0.0000 1.427 AIR 7 -0.3843 0.160 F 2 8 0.0094 0.901 BAFN 10 9 -0.2866 0.008 AIR 10 -0.0041 0.540 SK 16 11 -0.1523 6.559 AIR OBJECT DISTANCE 208.24 FOCAL LENGTH 9.9328 BACK FOCAL LENGTH 6 .559 AXIAL LENGTH OF LENS 6.26 TABLE 1 -- Design Specifications for Lens 1. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 FIGURE I. LENS I - OPTIMIZED SPHERICAL DESIGN Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 10 This technique of minimizing the mean square wave- front deformations tended to produce a superior lens by balancing the image aberrations rather than trying to reduce the aberrations first and then perhaps trying to balance their effect. In following designs, then, the approach adopted was that of introducing aspheric sur- faces in order to reduce the spherical aberration, while trying to maintain approximately the same balance of the off-axis aberrations present in this design. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 In this design the first and last surfaces were made aspheric. In addition to all radii and thicknesses, the fourth, sixth, and eighth order aspheric coefficients were allowed to vary. Again the mean square wavefront devia- tions were minimized while the distortion at full field (1.9) and the axial (1.16) and lateral color (1.18) were corrected to zero. The same weighting factors of 0.75, 1.0, and 1.0 were used across the field. The lens produced by this design had an improved axial resolution as would be expected. The zonal sagit- tal resolution was increased at higher frequencies due to the fact that the lens had a tighter core (there is much less image aberration at small values of the aper- ture). The zonal tangential resolution, however, and especially the marginal tangential resolution was much worse due to the introduction of a large amount of linear coma and also oblique tangential coma. In the following design attempts, this large coma was reduced to approximately the same value as in the spherical system. It was found that it was quite easy to control the linear coma (1.6), producing the design given below. The resolution obtained with this lens is better than that for the lens using all spherical sur- faces (See Fig. 7, page 33). Further attempts at trying Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 to reduce the oblique tangential and sagittal spherical aberration led to no improvement and seemed only to disrupt the balance of image aberrations already obtained. Better correction of the tangential field curvature as well as the astigmatism at the zone and the margin was possible, but only at the expense of the axial resolu- tion. The lens again had the same basic configuration as the original spherical lens. Listed below are the design parameters for this lens. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 13 1 0.2015(1) 0.711 SK 16 2 0.0770 0.010 AIR 3 0.3076 1.152 BAFN 10 4 0.0050 0.118 SF 2 5 0.4448 1.431 AIR 6 S 0.0000 1.441 AIR 7 -0.3989 0.247 F 2 8 0.0351 0.983 BAFN 10 9 -0.2925 0.004 AIR 10 0.0109 0.572 SK 16 11 -0.1357(11) 6.390 AIR (i) Z=Z (4) +Z (6) +Z (8) =aspheric sag Z(4)=aY4=-.001895 Z(6)=bY6=+.002658 Y=2.94 Z(8)=cY8=-.000983 (ii) Z (4) =aY4=+.008123 Z(6)=bY6=-.005875 Y=2.57 Z(8)=cY8=+.002430 OBJECT DISTANCE 209.93 FOCAL LENGTH 10.0071 BACK FOCAL LENGTH 6.390 AXIAL LENGTH OF LENS 6.67 TABLE 2 -- Design Specifications for Lens 2. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 FIGURE 2. LENS 2 -ASPHERICS ON OUTER SURFACES Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 In this design, the surfaces surrounding the stop (numbers five and seven) were aspherized. Again all radii, thicknesses, and three aspheric coefficients for each aspheric surface were varied. The preliminary de- sign effort made use of the minimization of group one and group two image aberrations, choosing the proper weights so as to achieve a reasonable balance between them. Important points in this design were the introduc- tion of large positive tangential oblique spherical aberration (2.2-3) and the maintaining of slightly posi- tive tangential field curvature (1.12). The design ob- tained in this manner showed good sagittal and tangential frequency response. The circular response, however, was considerably lower due to coma still present in the lens. In later design attempts, a better balance of the coma terms (2.10-12) was achieved, thus yielding a higher circular frequency response. The next design attempts involved the use of the mean square wavefront deformation (MSWD) minimization technique. Due to the fact that the frequency response on-axis was much greater than that off-axis, relative weights of 0.2, 1.0, and 1.0 were used for the axial case, 0.7 field, and full field, re- spectively. The MSWD technique did little in regard to Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 shifting the emphasis of correction from the axial to off-axial points. Nevertheless, it did?find a different balance of aberrations which produced a tighter core at full field. The final design obtained using aspheric surfaces surrounding the aperture stop is basically similar to that using aspheric surfaces on the outer surfaces. The main difference, however, is the way in which resolution varies across the field in the two cases. In the former lens, the axial resolution is very high, while coma limits the off-axis correction. The latter lens does not exhibit such a pronounced comatic effect and its resolution is more uniform across the field. See Figs. 9 and 10 on pages 35 and 36 for ray trace and modulation transfer curves, respectively. Table 3 on the following page gives design specifications for this lens. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 17 1 0.1944 0.653 SK 16 2 0.0705 0.001 AIR 3 0.2963 1.166 BAFN 10 4 -0.0315 0.283 SF 2 5 0.4390(i) 1.185 AIR 6 S 0.0000 1.444 AIR 7 -0.3877(ii) 0.160 F 2 8 -0.0032 1.061 BAFN 10 9 -0.2899 0.005 AIR 10 0.0286 0.550 SK 16 11 -0.1135 6.295 AIR (i) Z=Z (4)+Z (6)+Z (8) =aspheric sag Z(4)=aY4=+.004546 Z(6)=bY6=-.002348 Y=1.73 Z(8)=cY8=+.003722 (ii) Z(4)=aY4=-.005239 Z(6)=bY6=+.002828 Y=1.87 Z(8)=cY8=+.011646 OBJECT DISTANCE 210.24 FOCAL LENGTH 10.0088 BACK FOCAL LENGTH 6.295 AXIAL LENGTH OF LENS 6.51 TABLE 3 -- Design Specifications for Lens 3. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 FIGURE 3. LENS 3 - ASPHERICS ON INNER SURFACES Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 The final lens design attempt involved the use of an aspheric corrector plate placed in the aperture stop. The thickness and plane back surface of the plate were held constant, while the fourth, sixth, and eighth order aspheric coefficients on the first surface of the cor- rector plate were allowed to vary. In addition all other curvatures and thicknesses were used as variables. As a starting point for this design effort, a thin plane parallel plate was inserted at the stop into the spherical lens (lens 1) designed earlier. With the above mentioned degrees of freedom, the mean square wavefront deviations were minimized using weights of 0.0, 1.0 and 1.0 for the axis, zone, and edge, respectively. Further- more, the spherical aberration (1.1-2) as well as the distortion (1.9) and the axial (1.16) and lateral color (1.18) were controlled. The lens obtained in this man- ner had good axial correction, but the field curvatures were large, and thus the off-axis response was poor. In further design attempts, emphasis was placed on the correction of field curvature and astigmatism; it was relatively easy to achieve a good balance of the coma terms. In the last designs the oblique tangential spheri- cal aberration (2.2-3) was reduced yielding a well cor- rected lens. Note also that the stop position was allowed Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/212:0CIA-RDP78B04770A001500060082-1 to vary, but with little further improvement in image quality. The resolution obtained in this lens was much better than in all other designs and could be attributed to the attainment of good field curvature, producing an image with a tight core. See Figures 11 and 12 on pages 37 and 38 for ray trace and modulation transfer curves, respectively. 1 0.2016 0.671 SK 16 2 0.0796 0.005 AIR 3 0.3212 1.118 BAFN 10 4 0.0192 0.116 SF 2 5 0.4631 1.442 AIR 6 S 0.0000 0.069 AIR 7 0.0000(1) 0.303 BK 7 8 0.0000 1.108 AIR 9 -0.4420 0.159 F 2 10 -0.0185 0.830 BAFN 10 11 -0.3267 0.008 AIR 12 -0.0113 0.542 SK 16 13 -0.1666 6.614 AIR (i) Z=Z (4) +Z (6) +Z (8) =aspher is sag Z(4)=aY4=-.000363 Z(6)=bY6=+.002462 Z(8)=cY8=+.001963 Y=1.57 OBJECT DISTANCE 210.24 FOCAL LENGTH 10.0039 BACK FOCAL LENGTH 6.614 AXIAL LENGTH OF LENS 6.38 TABLE 4 -- Design Specifications for Lens 4. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 FIGURE 4. LENS 4 - ASPHERIC CORRECTOR PLATE Approved For Release 2005/11/21: CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 22 Some additional design was done with the thickness and the back curvature of the aspheric plate also allowed to vary. In optimizing this lens the thickness of the plate got quite large and the curvature of the back sur- face became positive. This had the effect of putting an extra negative lens behind the stop. The most inter- esting observation noted in this design was that the large thickness, in conjunction with the positive curva- ture following it, had reduced the oblique sagittal spheri- cal aberration (2.5) by a factor of two. This aberra- tion is normally one of the most difficult to reduce in any design. In spite of this reduced oblique sagittal spherical aberration, the resolution with this thick element in the stop was no better than that for lens 4. The general method followed throughout the design using the aspheric corrector plate was that of starting with the minimization of the wavefront deviations and then adding to the merit function certain specific geo- metrical aberrations until the lens was controlled to an adequate degree. This technique was found to give good results and to give the designer a means of slowly con- structing a desired merit function. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 M. J. Kidger and C. G. Wynne have recently published their analysis of the design of Double Gauss systems con- taining spherical surfaces.6 Their report includes sev- eral Double Gauss lenses optimized at f/2 with a 401 total field. Chromatic aberration was balanced for the C-F spectral region, and vignetting of 65% was allowed at full field. Some of these designs were done for sys- tems with a focal length of unity and with the object at infinity. For purposes of comparison, one of these optimized designs, scaled to a 10 centimeter focal length, was evaluated on the FLAIR program. Note that the shape of this spherical lens is similar to those designed on FLAIR except that the fifth element is thicker and biconvex in this design. Note also that the choice of glass types is different in this design. Kidger and Wynne allowed the glass type to vary during the design, resulting in the use of glasses very similar to the Schott glasses, LaK 9, F 1, and SF 10. Ray Trace curves and geometrical frequency response for the Kidger-Wynne design are given in figures 13 and 14, on pages 39 and 40, respectively. In comparison with 6Kidger, M. J. and Wynne, C. G., "The Design of Double Gauss Systems Using Digital Computers," Applied Optics, Vol. 6, March, 1967, pp. 553-563. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 24 1 0.1534 1.244 LaK 9 2 0.0428 0.000 AIR 3 0.2698 0.977 LaK 9 4 0.1517 0.300 F 1 5 0.4007 2.235 AIR 6 S 0.0000 0.899 AIR 7 -0.2364 0.300 SF 10 8 0.1791 2.283 LaK 9 9 -0.1987 0.000 AIR 10 0.0690 1.258 SF 10 11 -0.0627 6.008 AIR OBJECT DISTANCE FOCAL LENGTH 10.0011 BACK FOCAL LENGTH 6.008 AXIAL LENGTH OF LENS 9.50 TABLE 5--Kidger-Wynne Spherical Design the optimized spherical lens, Lens 1, the Kidger-Wynne lens shows much better correction of spherical aberration and, thus, a better axial response. The off-axis re- sponse, however, deteriorates quickly due to very large astigmatism. Although both the .7 field and full field tangential ray plots show a reasonably tight core, the sagittal curves are poor and, thus, the circular fre- quency response is low. Note that a better balance of resolution across the field could be attained by choosing a slightly different back focus. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 IMAGE EVALUATION TECHNIQUES Among the most common techniques of predicting image quality is the optical or modulation transfer function. The modulation transfer function (MTF) represents the contrast at which a lens transmits spatial frequencies. Since the frequency response of a lens is governed by both diffraction and geometrical aberration considera- tions, the precise evaluation technique must include both of these effects. If the lens is corrected to the degree that the spot size due to geometrical aberration consid- erations is smaller than the Airy disk diffraction pat- tern of the lens, then it is diffraction limited, and its frequency response is well known. In terms of wavefront error, which may be associated directly with geometrical aberration analysis, the tolerance for this case is X/4. On the other hand, when the wavefront deformation becomes X or 2X or greater, the geometrical image is larger than the diffraction image, and the geometrical optical modu- lation transfer function gives a good approximation to the actual frequency response. Note also that if there is an error, the geometrical response tends to differ from the actual response on the pessimistic side at high frequencies.7 Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 26 Validity of the Use of the Geometrical Optical Frequency Response The image evaluation presented in this report is of two forms: (1) image aberration ray plots and. (2) geo- metrical optical frequency response curves. The image aberration ray plots show the actual transverse ray dis- placements from the actual intersection point of the chief ray and the image plane in the tangential and sagittal fans for various field points. From these plots one may get an approximate idea of the image spot size. If the diameter of the image core at full field is approximately 50 microns, it may be seen that the lens is still far from its diffraction limit (the diameter of the Airy disk diffraction pattern is about 2.5 microns). The calculation of optical path difference (OPD) for the extreme ray at full field in lens 2 is given below. (p Ymax I OPD = TA'(P)dp At p = .7, X _ .5u, OPD = 2.5 (.0025) _- .006 z 12A 10 Again it may be seen that the lens is far from being dif- fraction limited. The geometrical optical frequency response is thus reliable and has been used throughout this study. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21: CIA-RDP78B04770A001500060082-1 27 Geometrical Optical Frequency Response The geometrical optical frequency response subrou- tine, as incorporated into the FLAIR program, calculates the frequency response of a lens on-axis and off-axis at the .7 zone and at full field. At each off-axis point, the response is computed in both the sagittal and tan- gential directions. In addition an averaged circular response is also given (only the circular responses have been included in this report). Each of these responses is calculated for d, F, and C light and then averaged with the weights 1.0, 0.25, and 0.25, respectively, for the white light response. The average circular frequency response is an aver- age over all target orientations. This circular aver- aging technique involves counting the number of rays which intersect the image plane within a small circle centered about the Gaussian image point. Since each ray represents the light energy passing through an elemental area of the aperture, by counting the fraction of the total number of rays the fraction of the total light energy passing through the system is found.8 This in- formation, known as the radial energy distribution, is then used in calculating the average circular frequency response. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 Three aspheric double Gauss lenses have been designed in this study in an attempt to improve upon the spheri- cal lens. All lenses were designed with the same cri- teria: f-number - 2.1, focal length - 10 centimeters, total field of view - 42 degrees, and magnification - -0.05. The designs differ primarily in the position and number of aspheric surfaces. Upon inspection of Table 6 on page 30, it is appar- ent that the off-axis resolution limits given for Lens 4 are superior to those of the other lenses. An equal amount of effort was put into achieving each of the de- signs. It must be noted, however, that this fourth system was the last one designed, and it is entirely possible that the experience gained in the previous design work gave the author a better understanding of the techniques involved and, therefore, facilitated the design task. Lens 3 has very good axial correction and further design effort could perhaps produce a better balance of correc- tion across the field. The conclusion to be drawn, then, is that well corrected double Gauss lenses can be designed with an aspheric plate in or near the aperture stop, but that additional investigation is necessary before any definite preference of position for the asphere can be determined. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21: CIA-RDP78BO477OA001500060082-1 29 Further investigation should be made regarding the ability to achieve similar image quality with fewer than three aspheric coefficients as variables. In any case, the comparison of the resolution obtained with designs 1 and 4 shows the marked improvement attainable through the use of aspheric surfaces. It may be assumed that as such systems are designed, better techniques for their fabrication will be found, and there will be more fre- quent use of aspheric refracting systems. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 30 Relative Field Height Lens 1 Lens 2 Lens 3 Lens 4 Kidger-Wynne 0.0 20 60 100 70 65 0.7 20 27 29 70 9 1.0 18 50 29 50 7 Maximum % Distortion .05% .07% .10% .05% .230 Lens 1 - Spherical Design Lens 2 - Aspherics on Outside Surfaces Lens 3 - Aspherics on Inside Surfaces Lens 4 - Aspheric Corrector Plate Near Stop Kidger Wynne - Spherical Design TABLE 6 -- Comparative Resolution Limits for Various Double Gauss Designs. (Resolution limit was determined by a modulation of 0.1 and is given in Q/mm.) Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 31 H-1.0 0.01 H =0.7 -0.01 0.01 H=0 -0.01 FIGURE 5. TRANSVERSE ABERRATION PLOTS FOR LENS I Approved Fq gas%38Qfll'/2.~QrIA- gRDP78B04770A001150006'00$2Sf_ed  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 1.0 0.8 0 0.6 0.2 0 I0 20 30 40 50 60 70 80 FREQUENCY (lines/mm) FIGURE 6. GEOMETRICAL FREQUENCY RESPONSE FOR LENS 1 Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 0.01 H = 0 7 . -0.01 0.01 H=0 -0.01 FIGURE 7. ((TRANSVERSiiE.r{l ABERRATION PLOTS FOR LENS 2 Approved Fgr Rgktie ~505/1 1y2T :r8rMRD148 1W81do6br60492 d line to sagittal fan)  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 10 20 30 40 50 60 FREQUENCY (lines/mm) 70 80 FIGURE 8. GEOMETRICAL FREQUENCY RESPONSE FOR LENS 2 Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  pproved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 H= 1.0 H = 0.7 0.01 H=0 -0.01 FIGURE 9. TRANSVERSE ABERRATION PLOTS FOR LENS 3 l Approved(IFR6 P)ight; solid line 5r1 / : CIA RDP78BO4770A001f5 b66082=? d  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 1.0 0.8 Z 0.6 H J D 00.4 2 0.2 0 I0 20 I I I I 1 30 40 50 60 70 FREQUENCY (lines/mm) 80 FIGURE 10. GEOMETRICAL FREQUENCY RESPONSE FOR LENS 3 Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21: CIA-RDP78BO477OA001500060082-1 -0.01 0.01 0.01 / 100, H =0.7 H=0 -0.01 FIGURE II. TRANSVERSE ABERRATION PLOTS FOR LENS 4 (D light; solid line refers to tangential fan, dashed line to sagittal fan) Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 1.0 0.8 z 0 0.6 I -- J D 0 0.4 2 0.2 0 10 20 30 40 50 60 FREQUENCY (lines/mm) 70 80 FIGURE 12. GEOMETRICAL FREQUENCY RESPONSE FOR LENS 4 Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 39 0.01 -0.01 0.01 -0.01 = 1.0 H=0 FIGURE 13. TRANSVERSE ABERRATION PLOTS FOR KIDGER- WYNNE DESIGN (D light; solid line refers to tangential fan, dashed line to sagittal fan) Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 0.81--I WHITE LIGHT H =0 11.0c" H= 1.0 f I I I I 0 10 20 30 40 50 60 70 80 FREQUENCY (lines/mm) FIGURE 14. GEOMETRICAL FREQUENCY RESPONSE FOR KIDGER-WYNNE DESIGN Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 1. Buzawa, John. W., "Notes on the Design of Double Gauss (Biotar) Lens Systems," 2. Crawley, Geoffrey, "The Aspheric f/1.2 50 mm Leitz Noctilux," The British Journal of Photography, October 7, 1966. 3. Desfor, Irving, "No-Flash Nighttime Lens," Christian Science Monitor, February, 1967. 4. FLAIR User's Manual, 5. Kidger, M. J. and Wynne, C. G., "The Design of Double Gauss Systems Using Digital Computers," Applied Optics, Vol. 6, March, 1967. 6. Kingslake, R., Lenses in Photography, A. S. Barnes and Co., Inc., New York, 1963. Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 TABLE 7 -- Image Errors Used in FLAIR Relative Relative Group I: Aperture Field 1. Transverse Spherical Aberration at 0.4 2. Transverse Spherical Aberration at 0.7 3. Transverse Spherical Aberration at 1.0 4. Linear Coma 0.416 5. Linear Coma 0.7 6. Linear Coma 1.0 7. Distortion 8. Distortion 9. Distortion 10. Tangential F ield Curvature 11. Tangential F ield Curvature 12. Tangential F ield Curvature 13. Astigmatism (T-S) 14. Astigmatism (T-S) 15. Astigmatism (T-S) 16. F-C Axial Chromatic Aberration 0.7 17. F-C Axial Chromatic Aberration 1.0 9FLAIR User's Manual, 10Extrapolation without the vignetting factor has been taken into account for 4, 5, 6, 10 to 15. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 43 Relative Relative Aperture Field 18. F-C Chief Ray Lateral Color 19. F-C Chief Ray Lateral Color 20. F-D Axial Chromatic Aberration 0.7 21. F-D Axial Chromatic Aberration 1.0 22. F-D Chief Ray Lateral Color 23. F-D Chief Ray Lateral Color Group II: 1. Oblique Tangential Spherical (Pure) 0.7*VFZ 0.7 2. Oblique Tangential Spherical (Pure) 1.0*VFZ 0.7 3. Oblique Tangential Spherical (Pure) 1.0*VFE 1.0 4. Oblique Sagittal Spherical (Pure) 0.7 0.7 5. Oblique Sagittal Spherical (Pure) 1.0 0.7 6. Oblique Sagittal Spherical (Pure) 0.7 1.0 7. Oblique Tangential Coma (Pure) 0.7*VFZ 0.7 8. Oblique Tangential Coma (Pure) 1.0*VFZ 0.7 9. Oblique Tangential Coma (Pure) 1.0*VFE 1.0 10. Oblique Saggital Coma (Pure) 0.7 0.7 11. Oblique Saggital Coma (Pure) 1.0 0.7 12. Oblique Saggital Coma (Pure) 0.7 1.0 13. Primary (i.e. F-C) Chromatic Aberrations of "outer" rays 0.7*VFZ 0.7 Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 44 Relative Aperture Relative Field 14. Primary (i.e. F-C) Chromatic Aberrations of "outer" rays -0.7*VFZ 0.7 15. Primary (i.e. F-C) Chromatic Aberrations of "outer" rays 1.0*VFZ 0.7 16. Primary (i.e. F-C) Chromatic Aberrations of "outer" rays -1.0*VFZ 0.7 17. Primary (i.e. F-C) Chromatic Aberrations of "outer" rays 1.0*VFE 1.0 18. Primary (i.e. F-C) Chromatic Aberrations of "outer" rays -1.0*VFE 1.0 Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1 DISCUSSION OF DESIGN PARAMETERS FOR In a paper entitled "The Design of Double Gauss (Biotar) Lens Systems,"ll John Buzawa discusses the con- struction, design parameters, and design approach of Double Gauss systems. Buzawa's study was done primarily on the LGP 30 and IBM 7074 computers, the latter using the ORDEALS program, where surface contributions to the particular third and fifth order aberrations are avail- able. Listed below are several of his suggestions and mention of how the spherical and aspheric designs pre- sented in this paper agree with them. A. The outer convergent elements should be of ap- proximately equal power unless there are restrictions on back focus which require otherwise. This yields a more symmetrical solution which is more easily corrected for distortion and lateral color.12 Note that this is usually accomplished in systems operating close to unit magnifi- cation. For systems in which the object is at infinity, the first element is usually a weak meniscus while the last is biconvex.13 In the four designs discussed in this 11Buzawa, John W., "Notes on the Design of Double Gauss (Biotar) Lens Systems," 12lbid. p. 5. 13lbid. p. 6. STAT 45 Approved For Release 2005/11/21 : CIA-RDP78B04770A001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 46 report, the last element was always stronger (by about twenty percent) than the first. These lenses were de- signed to operate at twenty to one conjugates. B. For uniform performance over a wide field, the use of thin doublets with strong outer curves is sug- gested. In such systems, the surfaces tend to be more concentric about the stop yielding smaller variations in image quality from the axis to the edge of the field. Baker, in his patent #2532751, defines A as the ratio of the distance between convex surfaces of the doublets to the focal length. For f/2 systems with a total field of view of 40?, A should be approximately 0.5. Longer values of A, or thick doublets surrounding the stop, result in larger high order astigmatism.14 Lenses 1-4 presented in this study have values of A ranging between 0.506 and 0.541; the astigmatism in these lenses is reasonably well corrected. In the design by Kidger and Wynne, however, the second doublet contains a thick positive element, indicated by the fact that A = 0.699. This system is limited in off-axis resolution by large astigmatism. Again the power of the two doublets should be ap- proximately equal with the exception of the case of 14Buzawa, John W., "Notes on the Design of Double Gauss (Biotar) Lens Systems," F Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1 47 unusual back focus requirements.15 In each of the de- signs discussed in this study, the first doublet is con- siderably stronger (almost twice as strong for lens 3) than the second doublet. C. The central airspace should be greater than the shorter of the two adjacent radii. A large central ar- space tends to reduce the oblique spherical aberration due to the fact the angle of incidence of the chief ray at the surfaces surrounding the stop is reduced.16 This effect was observed in the aspheric corrector plate de- sign when the corrector plate was allowed to become thick, yielding a design with greatly reduced oblique sagittal spherical aberration. 15Buzawa, John W., "Notes on the Design of Double Gauss (Biotar) Lens Systems," 161bid. p. 3. Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060082-1