VOLUME TWO PROJECT 9015 FINAL REPORT 1960-1964

Approved For Release 2000/04/12 : CIA-RDP67B0(U657R0000ef50d0Y1 SPECIAL HANDLING VOLUME TWO PROJECT 9015 FINAL REPORT 1960 -1964 SPECIAL HANDLING SHC65-9015-314/2 Copy No. /t% Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOO.657R000300150001-1 SPECIAL HANDLING This volume contains the appendixes to the 9015 Project Final Report Most of the appendixes are reports written on the project. The reports have not been updated to include later results or to reflect current thinking, but they have been reviewed and found to be essentially correct. The dates of the original work are as follows: Appendix I II III IV V VI VII VIII IX X XI XII XIII XIV XV March 1961 December 1964 February 1963 December 1964 November 1964 February 1963 May 1963 February 1964 June 1963 September 1964 February 1964 December 1964 Itek Document Number SHC65-9015-314/1, Volume One. SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Rete se 2000/04/12 : CIA-RDP67B00T67R000300150001-1 SPECIAL HANDLING I. DOCUMENTS II. INVESTIGATION INTO LIQUIDS SUITABLE FOR IMMERSION PRINTING III. EFFECTS OF FINITE BANDWIDTH IN THE LIGHT SOURCE IV. INSTALLATION REQUIREMENTS V. SPARE PARTS VI. DETERMINATION OF THE VELOCITIES OF MOVING TARGETS VII. APERTURE WEIGHTING VIII. INTERFERENCE PATTERN GENERATOR IX. STRAY LIGHT IN THE PROCESSOR X. CYLINDER LENS EFFECTS XI. FLIGHT TEST REPORT FORMS XII. EFFECT OF FILM EXPOSURE ON RECORDER / CORRELATOR PERFORMANCE XIII. COHERENT SLR RECORDER-CORRELATOR SYSTEM XIV. TWO DIMENSIONAL HOLOGRAMS XV. SPECTRUM AND OUTPUT FOR OPTICALLY CORRELATED CHIRP SYSTEM SPECIAL HANDLING .Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For ReI se 2000/04/12 : CIA-RDP67BOA657R000300150001-1 SPECIAL HANDLING Appendix I SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1 ,  Approved For Relfase 2000/04/12: CIA-RDP67B0Q7R000300150001-1 SPECIAL HANDLING Appendix I This is a list of the documents generated at Itek on the 9015 project. Project Reports Model 9015 Processor Final Report May 1964 SHC64-9015-310 9015 Project Final Report, Volume I June 1965 SHC65-9015-314/1 Appendixes, Volume II June 1965 SHC65-9015-314/2 9015 Project Report, Jan-June 1965 June 1965 SHC65-9015-315 These four volumes cover all phases of the project up to June 1965. The Pro- cessor report is often referred to in the Project report as reference 1. The latest report covering the period January to June 1965 covers specific studies on noise and stray light. Progress .Reports Progress Report November 1961 SHC61-9015-158G Progress Report December 1961 SHC62-9015-08 Progress Report January 1962 SHC62 -9015- 57 Progress Report February 1962 SHC62-9015-77 Progress Report March 1962 SHC62-9015-176 Progress Report April 1962 SHC62-9015-172 Progress Report May 1962 SHC62-9015-195 Progress Report June 1962 SHC62-9015-237 Progress Report July 1962 SHC62-9015-238 SPECIAL For Release 2000/04/12 : CIA RDP6~BB00657R000030015000'f-  Approved For RelVdse 2000/04/12 : CIA-RDP67BOO667R000300150001-1 SPECIAL HANDLING Progress Reports (continued) Progress Report Aug/Sept 1962 SHC62-9015-331 Progress Report October 1962 SHC62-9015-359 Progress Report November 1962 SHC62-9015-384 Progress Report December 1962 SHC63-9015-42 Progress Report January 1963 SHC63-9015-77 Progress Report February 1963 SHC63-9015 -103 Progress Report March 1963 SHC63-9015-159 Progress Report April 1963 SHC63-9015-190 Progress Report May 1963 SHC63-9015-250 Progress Report June 1963 SHC63-9015-312 Progress Report July 1963 SHC63-9015-342 Progress Report August 1963 SHC63-9015-385 Progress Report September 1963 SHC63-9015-433 Progress Report October 1963 SHC63-9015-478 Progress Report November 1963 SHC63-9015-535 Progress Report Dec/Jan 1964 SHC64-9015-81 Progress Report Feb/March 1964 SHC64-9015-219 Progress Report April 1964 SHC64-9015-267 Progress Report May 1964 SHC64-9015-329 Progress Report June 1964 SHC64-9015-432 Progress Report July 1964 SHC64-9015-441 Progress Report August 1964 SHC64-9015-503 Progress Report September 1964 SHC64-9015-582 Progress Report October 1964 SHC64-9015-666 Progress Report November 1964 SHC64-9015-770 SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For ReFfase 2000/04/12 : CIA-RDP67B0@657R000300150001-1 SPECIAL HANDLING 25X1A Progress Reports (continued) Progress Report December 1964 SHC65-9015-30 Progress Report January 1965 SHC65-9015-120 Progress Report February 1965 SHC65-9015-138 Progress Report March/April 1965 SHC65-9015-241 Progress Report May 1965 SHC64-9015-278 Proposals Proposal 6B -- Basic proposal submitted by Proposal 3155 July 1960 Itek proposal to cover work on 6B proposal 25X1A Added Task Submission June 1962 SHC61-9015-157 Change to processor necessitated by system changes. Auxiliary facilities and equipment. Proposal 3320 August 1961 SHC-209-61 Addendum October 1961 SHC61-9015-271 Test and Simulation Program Proposal 3334 F101 Flight Test Support August 1961 SHC61-9015-209 Added Scope Proposal January 1962 SHC62-9015-04 Revision January 1962 SHC62-9015-24 New Optical System to accommodate system changes. Film Drive modifications. Interface Engineering Program Recommendations June 1962 SHC62-9015-194 Added Scope Proposal July 1962 SHC62-9015-215 Further Test and Simulation Effort Special Purpose Optical Bench Processor Continuation of F101 Flight Test Support Follow-on Proposal April 1963 SHC63-9015-161 Installation of TV Viewing Station Continuation of F101 Flight Test Support Interface Engineering Experimental Processor Special Purpose Optical Bench for field use SPECIAL HANDLING 1-4 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Rel se 2000/04/12 : CIA-RDP67BOO 67R000300150001-1 SPECIAL HANDLING Proposals (continued) 9015 Follow-on Proposal March 1964 SHC64-9015-168 Field Service Test Support Correlator Modifications and Detail Correlator System Theory and Experiment Improved Correlator In addition, the following proposal was initiated in connection with this pro- gram; but it covered work concerned primarily with the recorder. Proposal for Optimum Parameters February 1962 SHC62-9015-38 The following proposals and work statements involved separate projects, but they are an outgrowth and continuation of the work on the 9015 system. Statement of Work July 1964 Proposed Study and Experimentation Efforts to further "Exploitation of Radar Imagery " SHC64-3529-388 Detail Correlation Configuration September 1964 SHC64-3529-506 and Performance Project 9015 Statement of Work January 1964 SHC65-9015-53 Miscellaneous Documents Preliminary Specification November 1960 SHC9015-60-1R Instruction Manual Volume I February 1963 not classified Instruction Manual Volume II February 1963 SHC63-9015-102 Program (Note: This document is superseded by the Project Final Report where the entire contents of SHC63-9015-143 is up dated and reproduced) Effect of Film Exposure on Re- June 1963 corder/Correlator Performance (This work is included in this volume as Appendix XII) Final Report, Test and Simulation April 1963 SFIC63-9015-143 SHC63-9015-544 Letter to Peter Hall September 1964 SHC64-9015-505 Subject: "Relocation of Correlation Activity" am SPECIAL HANDLING 1-5 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Rely se 2000/04/12 : CIA-RDP67B00667R000300150001-1 SPECIAL HANDLING Appendix II INVESTIGATION INTO LIQUIDS SUITABLE FOR IMMERSION PRINTING SPECIAL HANDLING II-1 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For ReI se 2000/04/12 : CIA-RDP67B0G 67R000300150001-1 SPECIAL HANDLING Appendix II INVESTIGATION INTO LIQUIDS SUITABLE FOR IMMERSION PRINTING In the selection of liquids to be considered, it was important that the following be taken into consideration: (1) Liquid must have an index of refraction close to 1.50, in that the cellulose tri-acetate films will average close to 1.48, with the estar base types averaging close to 1.58. (2) Liquid must be safe to handle, insofar as personnel are involved, or, non-toxic. (3) Liquid must not be flammable. (4) It must not affect the film adversely, neither emul- sion nor base, during or after the immersion. (5) It should have sufficient viscosity to maintain the film in the center of passage. (6) Liquid must dry quickly and easily, and leave no residue. (7) It should be readily obtainable. (8) Liquid cannot be absorbed into, either base or emulsion. In the SMPTE Journal of October 1957 a group of twenty solutions were listed. Inasmuch as many of these liquids could not be used for various MW SPECIAL HANDLING 11-2 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67B0M7R000300150001-1 SPECIAL HANDLING reasons, such as. dissolving the film plasticizers, being toxic or flammable, the following list was compiled. Several other compounds were tried (1) Trichlorethane . Index 1.48 (2) Orthodichlorbenzene 1.55 (3) Methanol (Methyl Alchohol) 1.33 (4) Carbon Tetrachloride 1.460 (5) GE Refractasil 1.46 (6) Tetrachlorethylene 1.504 (7) O-xylene 1.505 Preliminary tests consisted of soaking 1" x 10" strips of both the acetate and mylar films in small containers of the liquid, then drying normally, (drain and by air) and then also utilizing an improvised pair of rubber rollers, producing a squeegee effect. Following are the results. 1. 0 Trichlorethane This solution was discarded immediately, in that it is a solvent for the film plasticizer, particularly with the Mylar types. It also raised havoc with the plexiglass breadboards. Produced extreme curl and disfiguration of the film. 2. 0 Orthodichlorbenzene Although there was no apparent damage to the films, the liquid is most unpleasant to use and would require extreme venting. Dried normally in about 3 minutes, in about 30 seconds when roller squeegee was used. The film seems to retain the odor for an hour or longer following drying. Viscosity seems low, and the liquid is flammable. Dries very quickly SPECIAL HANDLING 11-3 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67B0O 57R000300150001-1 SPECIAL HANDLING and produced no bad effects other than slight curl following drying with the roller squeegee. 4. 0 Carbon Tetrachloride Dried very rapidly, both normally and with roller squeegee. Viscosity is low and would anticipate problem in complete wetting of the film. This solution also has property of slightly charging the film, thereby enhancing its dust gathering capabilities. 5. 0 Refractasil Dried very slowly by air methods, but quite rapidly by roller squeegee. However, the rollers do take up a considerable amount of the solution, which over a long length of film could conceivably affect its ability to remove the refractasil, a bath of carbon tetrachloride immediately following the refract- asil bath speeded up drying markedly with the roller squeegee system, and did not load up the rollers as badly. Printing properties are excellent, with no adverse affects of any kind. 6. 0 Tetrachlorethylene (Per chlorethylene) This solution has been used with success by the technicolor corp. , in a similar application, and results of tests here proved this to be worthy of serious consideration. No apparent ill effects on the films were noted, its viscosity is very good, it produces no curl or softening and dries most rapidly. 7.0 Summary On the basis of these findings, the refractasil and the tetra, chlorethylene were selected as the two most outstanding, and the following tests were con- ducted, now using the breadboard platen. SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Reese 2000/04/12 : CIA-RDP67B00467R000300150001-1 SPECIAL HANDLING Brass shims of .005", . 0075" and . 010" were prepared to be used as separators in the platen. The . 005" was quickly discarded as it did not provide adequate spacing, even with the . 004" Mylar film. With the . 010" shim it appeared that more bubbles occurred between negative and platen surfaces, so the . 0075" shim was used for following tests. 92" aerial film was used and it was quickly apparent that the best method of using this platen is to push the negative through the solution, with the sec- tions firmly bolted together. Trying to close the platen with either the re- fractasil or the tetrachlorethylene resulted in definite bubble formations that are virtually impossible to remove. Air trapped between the faces of the platen is responsible for this. Either a sliding system or an immersed hinge affair might solve this, but threading the negative through the slot definitely eliminates bubbles. Previous experience with this type of printing has proved that it is most difficult to remove bubbling by a sandwich pressure system. Apparently too much separation between faces can add to bubble trouble, while too little will bind. These tests seem to indicate that an approximate clearance of . 0025" is adequate, for the . 005" films. This report, originally written early in 1960, was reviewed in May 1965. No new materials or methods are available and the continued use of tetrachlor- ethelene is recommended. SPECIAL HANDLING 11-5 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Ret se 2000/04/12 : CIA-RDP67BOGS67R000300150001-1 SPECIAL HANDLING Appendix III SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Relfase 2000/04/12 : CIA-RDP67B0O057R000300150001-1 SPECIAL HANDLING Appendix III 1. 0 Introduction The focusing property of a hologram is dependent on the wavelength of the light, the focal length being inversely proportional to the wave- length. Thus a diffraction limited image can only be obtained with mono- chromatic light, such as that from a laser or a low pressure gas discharge lamp. An incandescent source such as a carbon arc produces white light which must be filtered before it can be employed for the correlation of holograms. For practical reasons light obtained from a filtered "white" source is never completely monochromatic. The fractional bandwidth T- may be small (0. 4% in the present system) but is nonetheless an im- portant factor in the performance of an optical correlator. 1. 1 Resolution Without Compensation The resolution obtained for a given value of L depends on the highest hologram frequency. If O1 = image diameter due to filter bandwidth alone. S2 = image diameter due to hologram bandwidth alone. S3 = image diameter due to all other causes, assumed constant. Then if the image functions are approximately Gaussian in form, SPECIAL HANDLING III-2 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Raise 2000/04/12 : CIA-RDP67B09657R000300150001-1 SPECIAL HANDLING bz,= 612 +622 +632 We will hold 63 constant, and will determine filter wavelength A millimicrons filter bandwidth AX millimicrons hologram bandwidth W cycles/inch (half power bandwidth of Gua s s ian pa s s band) Diffraction angle e = fH . A where fH = hologram frequency. Thus, A@ = fH AA If F is hologram focal length M is (azimuth) magnification 61 and 62 Then in the absence of any chromatic correction bl and 62 can be approximated by F, F. fHL X Ti . AO=- M 1 62=MW Figure 1 shows these quantities for AX= .004 X fH = (50 + w) i. e. 50 c/inch offset. SPECIAL HANDLING 111-3 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For ROO?q/12 : CORLIG00300150001-1 Filter Bandwidth Alone ~a = 0. 4% A = .640 0 200 300 400 500 0 100 200 300 400 500 0 10 20 00 300 460 500 fH 0 fH fH Hologram Aperture Effect. This is constant once W is fixed. 4 I I + T ++ i i ; 100 200 300 400 500 Max. Hologram Frequency (W + 50 c/inch) Figure 1 Ap SPECIAL HANDLING  Approved For Re1ftse 2000/04/12 : CIA-RDP67B0?67R000300150001-1 SPECIAL HANDLING If the aperture is now limited, i. e. fH. is limited, then bl improves and 62 gets worse. This is shown in Fig. 2, where the best overall resolution is obtained when the aperture is limited to 300 cycles/inch. The actual resolution obtained here depends on 63 and is drawn for 63 = 0, but the position of the minima along the frequency axis does not change if 83 is independent of the hologram aperture and light wave- length. 2. 0 Prism Compensation A possible method of compensating for the finite bandwidth of light is to insert a prism with controlled dispersion in the optical system. We have seen that the angular spread of light due to finite bandwidth is Ae = fH . ox. Thus the angular spread QA varies across the hologram getting progressively larger toward the high frequency end of the hologram. A prism inserted in the optical system will necessarily deviate all light of the same wavelength through the same angle. In this case, the best we can do is to design the prism to correct the angle exactly in the center of the hologram, and accept some over-correction at the low frequency end and an equal amount of under-correction at the high frequency end. This is equivalent to correcting the "lateral" spread and leaving some longitudinal spread along the axis through the center of the hologram. This is shown in Fig. 3. If fc is the center frequency of the hologram then no SPECIAL HANDLING III-5 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For R " "'.0 T/ t12 : C 5k 0 &00300150001-1 AA= .004 A Resolution mils --- .._.._ _ _ _ .+--_.__..._. _...__.}.. _ .....__...._ .4 _ _ _.._ _...+ 0 100 200 300 400 500 Max Hologram Filter Figure 2 Resolution Versus Aperture No Prism Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1 SPECIAL HANDLING 111-6  Approved FoAl rs~'1 OS /1,2b e'fR-'R 6TSOA&G R000300150001-1 Approved For5eleasePJlW%L- 11 ; GI/, -F Q 51!?ff&000300150001-1  Approved For Reuse 2000/04/12 : CIA-RDP67BOA6=57R000300150001-1 SPECIAL HANDLING Aec = fc ? Q Prism deviation 6 = a"(n - 1) where yr = prism angle n = refractive index Thus dA do the required dispersion 9c = f and a(. do = f ate, U-, pa c 41A c In any specific glass the dispersion Tx is a function of wavelength. The variation in ?n- can be reduced to a considerable extent by making a multiple prism using several different glasses. The actual angular spread at any hologram frequency fH after prism compensation will be A91 = L\X I f H - fc The image diameter after compensation 6 1 = FMX IfH d X If dn is constant with wavelength, then the image diameter will be proportional to 0X, which is generally proportional to the wavelength X. Thus using an "ideal" prism, 61 will vary both with wavelength and hologram frequency as shown in Fig. 4(a) which is based on a bandwidth W of 300 c/inch and offset of 500 c/inch. The uncompensated image size is shown again for reference at Fig. 4(b). With a practical prism, U7 will decrease with wavelength. The effect of this on bi is shown in Fig. 4(c) for a single-glass SPECIAL HANDLING 111-8 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 868W I AL -RCS tR G0150001-1 'I O U SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Reiftse 2000/04/12 : CIA-RDP67B086P57R000300150001-1 SPECIAL HANDLING prism of Z. 38? angle. The best that can be done here is to arrange the image size to be equal at the two extremes of 44 ,a, f = 50 cycles/ inch and X = . 64 ,co, f = 350 cycle s / inch. As discussed in Section 1.1 the overall resolution bT varies with bandwidth and has a minimum value. It is to be expected that with the inclusion of a compensating prism, the usable hologram bandwidth will be increased with a consequent im- provement in T' 2. 1 Practical Considerations The requirements for a prism to minimize the finite waveband are (1) Constant dispersion of . 01 radians per micron over . 440 to . 650 micron band. (2) Prism design must allow insertion in the optical system without major changes. (3) Transmission light loss to be minimal. (4) The prism must not introduce spherical aberra- tion into the optical system. After considerable investigation, it was found that these conditions could not simultaneously be met. Some of the problems encountered were: (1) A 2-element prism of nearly constant dispersion over the required band would be desired for inser- tion in the optical system just underneath the liquid platen, but such a prism would have a deviation of 20 0 which cannot be accommodated. A prism in SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Reuse 2000/04/12 : CIA-RDP67B09667R000300150001-1 SPECIAL HANDLING this position will also cause dispersion of the zero order. (2) Attempts to eliminate the residual deviation re- sulted either in causing great changes in disper- sion or in the use of impossibly large prism angles. This would lead to a very thick prism composed of a large number of sections cemented together which would take a great deal of space, be heavy, expensive and cause a large light loss. (3) If the prism were located nearer to the output plane where more space is available, then a greater dispersion would be required and spheri- cal aberration would be introduced because of the converging beam. As it was not possible to physically accommodate suitable prisms without redesigning the correlator mechanically, the possibility of in- troducing the required dispersion by means of a diffraction grating was next investigated. The intention was to replace one of the plane mirrors with a blazed reflectance grating. This idea is treated in the next section. 3. 0 Correction of Filter Bandwidth by Means of a Reflection Grating 3. 1 Deviation Required to Correct Image Spread The angles of incidence and diffraction in a hologram are related by the following expression: sin i + sin w = M. A. f SPECIAL HANDLING III-11 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Rel ase 2000/04/12 : CIA-RDP67BO 657R000300150001-1 SPECIAL HANDLING where m = order of image i = incidence angle, to normal 41 = diffraction angle, to normal A = wavelength of light f = hologram frequency In the present case, i and Y are small angles and we are concerned only with first order images. Thus we can write: i=A.f. -W To correct lateral image spread, we require Y/ to be constant. Thus, the required condition is X f - i = constant Differentiating with respect to we get In other words, the required rate of correction in radians per inch is equal to the hologram frequency in lines per inch. A typical hologram contains a range of frequencies, and the correc- tion can only be perfect at one frequency. If we correct the frequency at the center of the hologram, then the low frequency edge is overcorrected and the high frequency edge is undercorrected, by the same amount. The result is to leave a residual longitudinal image spread. In spite of this, an improvement of at least 2:1 in image size is obtained this way. The improvement factor is fH2f H where #H = highest hologram frequency fL = lowest hologram frequency SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Reuse 2000/04/12 : CIA-RDP67B09657R000300150001-1 SPECIAL HANDLING Thus in a heavily squinted hologram where fL is large, a much greater improvement factor is possible. 3. 2 Reflection Grating If i is the incidence angle and /3 is the reflection angle measured to the normal of the macro surface of the grating, and if 91 'is the groove angle Groove angle cac' _ /3 2 Total reflection angle 0 = i +13 In a blazed grating, we require the light to be reflected from the grooves in the same direction that it is diffracted. Thus: a(sin 13- sin i) = M~ where a = groove spacing Angular dispersion d/3 = m dpi a cos Combining these equations, we cot of = tan 0 + 2 ~` dA MA 2 cos sin of Thus, given the total reflection angle 0, the wavelength A and the re- quired angular dispersion we can determine the grating frequency and blaze angle. The best position for a reflection grating appears to be in place of the bottom mirror. This is after the zero stop and so avoids any trouble due SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOQ657R000300150001-1 SPECIAL HANDLING to shifting the zero order image. Also the angular dispersion, here is greater, which requires a higher grating frequency making the grating more practical in this case. The angular dispersion required at any point in the system other than at the hologram itself will now be determined. Let the hologram focal length be F0 field lens focal length be Fl relay lens focal length be F2 cylinder lens focal length be F3 spacing of field and relay lens principle planes be A spacing of relay and cylinder lens principle planes be B The image formed by the hologram and field lens will be at a dis- tance xl given by Fo Fl Fo+ F1 The distance of this image from the relay lens F2 is The virtual image formed by the relay lens will be at a distance F2 x2 x3 _F 2- x2 Finally, this image will be at a distance x4 from lens F3 where x 4 = B + x 3 SPECIAL HANDLING 111-14 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOQ 57R000300150001-1 SPECIAL HANDLING Then if 90 is the angular deviation of the beam at the field lens F1, the angular deviation of the beam emerging from F3 will be 6 = X3 . xl . 9 3 x4 x2 0 If the mirror is situated a distance x5 from the lens F3 and the final image plane is a distance x6 from lens F3 then the deviation required at the mirror is e =e x6 4 3 x6-x5 xl x3 x6 E) - e . 4 x2 . x4 x6 - x5 0 3. 3 Calculations If the frequency at the hologram center f = 250 cycles the required correction at the hologram is di 250 d = 2 radians/micron = .0098 radians/micron per inch, then We will round this off to . 01 radians/micron. The angular deviation re- quired at the lower mirror position will be .01 . xl . x3 x6 radians/micron x2 x4 x6 - x5 where xl = 20. 6 inches x2 = 2.97 inches x3 = 3. 61 inches x4 = 12.31 inches x5 = 5. 5 inches x6 = 39 inche s SPECIAL HANDLING III-15 Approved For Release 2000/04/12: CIA-RDP67B00657R000300150001-1  Approved For RaLease 2000/04/12 : CIA-RDP67BOa657R000300150001-1 SPECIAL HANDLING Angular deviation required = . 01 20.6 3.61 39 0236 radians/ 2. 97 2. 31 33.5 micron. The total reflection angle 0 = 370 = 18.5, tan= = . 550 micron dT .335, cos d13 _ n.,36 a.---/ ; - r cot of = tan 0 + 2 dd dA = .335 + 55 x2.0 3 = 154. 3 Then groove angle os' = 0. 37? Groove spacing = m 2 cos 2 ? sin os .550 1.89 x . 00647 microns This is equivalent to 22.3 grooves/mm. 3. 4 Practical Considerations The effectiveness of a reflection grating in this application depends on the efficiency of the blazing; with efficient blazing all the incident energy is directed into a single diffraction order. In the present case, diffracted energy of the first order only is required: the presence of appreciable light in the zero and higher order images will cause SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For ReJoase 2000/04/12 : CIA-RDP67B00657R000300150001-1 SPECIAL HANDLING overlapping data. Data from Bausch & Lomb indicated that it was possible to rule gratings in which over 90% of the incident energy was directed into a single order, although they could not guarantee this with a grating of such low frequency. The main problem is in preserving the flatness of the reflecting surfaces of the groove. Test gratings were ordered from B & L on a best effort basis. It was found on testing these gratings that only about 50% of the incident energy was actually diffracted into the first order, making the gratings unusable for the intended purpose. This was apparently due to the difficulty of holding optical flatness in the reflecting surfaces of a coarse grating, due to the width of cutting tocl required. 4. 0 Conclusions The only feasible method of compensating an optical correlator for finite filter bandwidth appears to be the use of a prism in the collimated beam adjacent to the input film. This would introduce a bend in the opti- cal system, and cause dispersion of the zero order, both of which effects would have to be taken account of in the initial design of the optical system. SPECIAL HANDLING III-17 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOQ657R000300150001-1 SPECIAL HANDLING Appendix IV INSTALLATION REQUIREMENTS This appendix contains a few selected sections from the Operator's Manual. These are reproduced here for the convenience of personnel who may have to provide facilities for the Processor. If possible, recent log books and/or operating personnel should be consulted for further details. SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Re#sase 2000/04/12 : CIA-RDP67B0QA57R000300150001-1 SPECIAL HANDLING Appendix IV 1. 0 Introduction 1.1 General This manual contains operation and maintenance instructions for the Model 9015 Processor manufactured by Itek Corporation. Classified infor- mation pertaining to Sections III, IV, and V are contained in Volume two. The Model 9015 Processor (See Fig. 1) is used to enlarge one-half of a 92 inch wide input film and to expose the enlarged area onto a 92 inch wide output film. 1.2 Description 1.2.1 Physical The Model 9015 Processor consists of a carbon arc unit and an optical unit (see Fig. 1). The carbon arc unit contains the carbon arc lamp with its rectifier power supply and water circulator. The optical unit contains the optical system, the input and output film drives, and the film drive controls and power supplies. 1.2.2 Functional The Model 9015 Processor provides a 92 inch wide output film showing an image area that is a 2X enlargement of one half of the image area of its 9? inch input film. During this process, the equipment performs the follow- ing functions: (1) Drives the film at constant speed. SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Rb1ees'lbbr02 :CIA-"R~~~T~'0t#6F~000300150001-1 Figure 1 Model 9015 Processor Approved For Raeasp.2 PIR4112 : CJA- eAfff ?0f R&0300150001-1 IV-3  Approved For Rele 2000/04/12 : CIA-RDP67B00457R000300150001-1 SPECIAL HANDLING (2) Maintains the film at the proper tension through- (3) out the operation. Stops the film drive mechanism upon the occur- rence of the following: a. Failure of certain mechanical components. b. End of film. (4) Provides for automatic operation (once the unit is started). (5) Enlarges one-half the input film and exposes the enlargement on output film having the same width as the input film. 1.3 Equipment Characteristics The physical and electrical characteristics of the Model 9015 Processor are as follows: (1) Input power requirements: a. 120 volts, 15 amperes, 60 cps, 1 phase, 3 wire. b. 208 volts, 60 amperes, 60 cps, 3 phase, 3 wire. (2) Temperature limits: 70 + 5?F, relative humidity at 40 + 10 percent. (3) Mounting: a. Arc unit: on frame fitted with jackscrews and casters. Floor moutning provided by lifting the frame and casters off the floor by the jackscrews. b. Optical unit: self-contained cabinet fitted with SPECIAL HANDLING IV-4 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOGS67R000300150001-1 SPECIAL HANDLING (5) operating or servicing the Model 9015 Processor. jackscrews and casters. Floor mounting provided by lifting the cabinet and casters off the floor by the jackscrews. (4) Overall dimensions (arc unit plus optical unit): 100 inches high, 114 inches wide, 482 inches deep. Fuse complement: a. Two type 3AG, SLO-BLO, 0. 5 ampere. b. Two type 3AG, SLO-BLO, 0. 6 ampere. c. One type 3AG, 3 amperes. d. One type 3AG, 6 amperes. 2. 0 Accessory Test Equipment 2. 1 General Table 1 lists the accessory test equipment and special tools used when Table 1 Test Equipment Manuf. & Model No. Application Volt-ohm milliammeter Simpson Electric Co. Voltage measurements Model 260 continuity checks Theodolite (with auto- Wild, Model T-2 Alignment of optical unit collimating eyepiece) Mirror (7 inches square) Libbey Owens Ford Glass Co. (high quality plate glass) Centering fixture Itek Corp. (drawing Centering Fl & F2 lenses 9015-0523) Centering fixture Itek Corp. (drawing Centering relay lens 9015-0522) Test film Itek Corp. (drawing Focusing of optical unit 9015-0521) Lamp house draft gage Strong Electric Corp. Draft measurements for (for lamps using 75- carbon arc exhaust duct 100 amperes) SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOQ&57R000300150001-1 SPECIAL HANDLING 3. 0 Installation 3. 1 Site Slection 3. 1. 1 Power Requirements The Model 9015 Processor requires the following sources of external power: (1) 208 volts, 60 amperes, 60 cps, 3 phase, 3 wire terminating in a fuse box with 60-ampere fuses in each line. (2) 120 volts, 5 amperes, 60 cps, 1 phase, 3 wire ter- minating in a standard grounding type outlet. (3) 120 volts, 10 amperes, 60 cps, 1 phase, 3 wire terminating in a standard grounding type outlet. The power listed in tems (1) and (2) of paragraph 3. 1. 1 is required by the arc unit that in item (3) by the optical unit. 3. 1. 2 Temperature and Humidity The Model 9015 Processor is designed to operate at a temperature of 70 + 5?F and a relative humidity of 40 + 10 percent. 3. 1. 3 Intake System Requirement The arc unit requires an 8-inch diameter intake duct. No blower should be used. 3. 1. 4 Exhaust System Requirements The carbon arc lamp of the arc unit requires an 8-inch diameter exhaust duct. The exhaust blower in the lamp hood removes exhaust gases from the arc. An additional blower in the upper stack is required to remove the ex- haust gases from the exhaust system. This blower should have an air SPECIAL HANDLING IV-6 Approved For Release 2000/04/12 ,: CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOQ657R000300150001-1 SPECIAL HANDLING velocity of approximately 700 linear feet per minute. If the upper stack blower is inadequate, the exhaust gases will back up into the Processor area and into the lamp house. The optical unit requires an exhaust system capable of exhausting 250 cubic feet of air per minute. A 6 inch diameter duct is required for this purpose. A 4 inch diameter duct is also required to exahust the condenser cooling system. The optical unit exhaust ducts must exhaust independently into the atmosphere. Their outlets must not be located near the intakes of any system, including those of the Model 9015 Processor. 3.1.5 Darkroom The installation area must include a darkroom for loading and unloading the output magazine. 3. 1. 6 Dust and Dirt Control The importance of controlling dust and dirt within the area assigned to the Model 9015 Processor cannot be overemphasized. Accumulation of dust and dirt on the internal lens of the equipment causes not only loss of illumi- nation, but, what is even more important, loss of reproduction resolution due to the scattering of collimated light rays. Although the ideal area, which has a sterile, dust-free atmosphere, is impossible in view of personnel activity and the materials used, areas which approximate the ideal should be seriously considered in preparing to install the equipment. The main source of dirt is the outside air, which generally contains dirt SPECIAL HANDLING IV-7 idw Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67B0Q&57R000300150001-1 SPECIAL HANDLING in the form of dust or cinders. Common types of open-air contamination and the common methods for the removal of each type are listed in Table 2. Per- sonnel introduce dirt through their activities or through their clothing. Equipment also introduces dirt in the form of metal particles from moving parts, oil deposits from bearings, and dust particles from carbon arcs. Most dirt can be removed from the air by ordinary commercial air filters. The best of these, however, only cuts down the amount of cleaning required. Some electrostatic filters have proven advantageous in photographic practice. Filters made of bundles or mats of soft crepe or cotton pads give good results and require less maintenance. Since no filter is perfect, some smoke and dirt deposits accumulate on the walls and ducts. These deposits are usually dis- lodged later by vibration or an accidental blow. Dirt from this source is serious in photographic work. It can be substantially reduced by viscous filters on the ends of long runs of duct work. Ducts should be made of smooth material and constructed so that they can be easily and thoroughly cleaned. The air movement associated with air conditioning causes more dirt to collect on the films and lenses, thereby increasing the need for air filtration. However, the ducts and fans of existing air conditioning systems can be uti- lized for systems which filter dust from the laboratory air. The preparation of the assigned area for dust and dirt control should be supplemented by thorough dirt inspection and cleaning routines. SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOO657R000300150001-1 SPECIAL HANDLING Scale of Atmospheric Impurities Particle Type Heavy industrial dust Size Range, microns 100 and up Method of Removal Cyclone separators General dust 1 - 100 Dynamic precipitators Fly ash 3 - 70 Water spray; air filters Fog 1 - 40 Air filters Pollen 20 - 60 Air filters Plant spores 10 - 30 Air filters Bacteria 1 - 15 Air filters Fumes Air filters and. electrical Pigments 7 precipitators Electrical precipitators Smoke 0. 001 0. 3 Electrical precipitators Tobacco smoke 0. 01 - 0. 15 Electrical precipitators Oil smoke 0. 03 - 1 Air filters and electrical precipitators SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Relase 2000/04/12 : CIA-RDP67BOQ667R000300150001-1 SPECIAL HANDLING Appendix V SPECIAL HANDLING V-1 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOW&57R000300150001-1 SPECIAL HANDLING Appendix V Qty. Description 5 AGC 3 Amp Main power sup- F203 Fuse 5 AGC 6 Amp Little Fuse ply TV control Fuse 5 AGC 10 Amp Little Fuse TV control Fuse 5 AGC 4 Amp Little Fuse TV control F9 01 F903 F904 5 AGC Slo Blo Little Fuse Loop controller F302 5 .6 Amp AGC Slo Blo Little Fuse Loop controller F301 Circuit 1 .5 Amp AM-12 Heineman Power input CB201 Breaker Lamp 2 No. 1820 General Electric Panel light DS405 Lamp 10 T-34 NE-51 Cleveland, Ohio Dialight Corp. Panel lights DS401 Relay 1 MH17D 24 VDC Brooklyn, N. Y. Potter & Brum- Loop controllers K301 4 PDT field, Princeton, K302 Ind. K304 Relay 1 MH17D 115V Potter & Brum- Loop controller K303 Relay AC.A field, Princeton, Ind. Potter & Brum- Loop controller K101 field, Princeton, Ind. ow SPECIAL HANDLING V-2 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For ReJase 2000/04/12 : CIA-RDP67B04657R000300150001-1 Item Qom. Light 1 Light 2 Switch Relay 1 SPECIAL HANDLING Description 25 watt 120 V frosted No. 47 mini- ature 90326 Switch Switch Switch 1 1 5 Drive Wheel 1 Drive Wheel 1 Motor 1 Motor 1 Motor 1 Motor 1 138866A3L 138867A3L DTZRVZ-A7 9015-0689 9015-0652 N29GMW B8194E-120m ALPJRE NSH-12R Where Used Part No. General Electric Cleveland, Ohio General Electric Cleveland, Ohio Strong Electric Toledo, Ohio Strong Electric Toledo, Ohio Arc Unit 19039 Arc Unit Arc Unit Control panel S401 S403 S101 silo S114 Ucinite Control panel Sill Ucinite Control panel S112 Micro switch Safety circuit S209 S212 S215 S219 Haydon Switch Loop control (many) Waterbury, Conn. switches (inter- changeable with No. 5227) Itek Corp. Lexington, Mass. Itek Corp. Lexington, Mass. Input film drive Output film drive Main drive motor B201 Bodine Elec. Co. Condenser cooling B212 Chicago, Ill. Electric Indicator Reel torque motor B209 Stamford, Conn. Bodine Elec. Co. Loop drives #1 & 2 B204 Chicago, Ill. B205 SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  tion Descri Manufacturer Where Used Part No. R~y, p Motor 1 20-02 - IN Inland Motor Film torque motor B202 T1231B Northampton, Motor 1 2114C Inland Motor Northampton, Reel torque motor B210 Motor 1 KC1-23 IN Bodine Elec. Co. Loop controller B206 Chicago, Ill. B207 Rheostat 1 H500-562 shilo Ohmite Intensity control R201 Chicago, Ill. R203 Resistor 1 lOW 50 ohm Ohmite Intensity control R204 Chicago, Ill. R202 Capacitor 1 T30ZN 34 - Aerovox Input supply motor C202 400 VDC 3. 0 mfd Capacitor 1 T30ZN 34 - Aerovox Blower motor C21Z 400 VDC 4. 0 mfd Capacitor 2 VC 1164B Aerovox Loop control C206 C207 Loop controller 1 9015-1038 Itek Corp. Lexington, Mass. Electronic chassis 9015-1076 Itek Corp. Lexington, Mass. Main drive SPECIAL HANDLING Approved For Rase 2000/04/12 : CIA-RDP67BOQ657R000300150001-1 SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67B09657R000300150001-1 SPECIAL HANDLING Appendix VI DETERMINATION OF THE VELOCITIES OF MOVING TARGETS SPECIAL HANDLING VI-1 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For ReWase 2000/04/12 : CIA-RDP67B0W57R000300150001-1 SPECIAL HANDLING Appendix VI DETERMINATION OF THE VELOCITIES OF MOVING TARGETS 1. 0 Introduction A coherent radar system records the radar return in such a manner that moving targets can be identified. The signal histroy left by a moving target will be slightly different from that for a stationary target. These differences would lead to a slight image blur and/or image displacement in a correlator such as the one used on the IR & D program 5271. However, a correlator of the proper calibration could detect the differences and determine the velocity. The velocity of the target is the geometrical sum of two perpendicular components: one component parallel to the path of the airplane, and the other component normal to the path. The former would appear as a change in the focal plane, and the latter as a lateral displacement, of the correlated image. Each of these components would be measured separately in the correlator, and each is treated separately below. 2.0 Analysis The following analysis considers first-order effects only. It is assumed furthermore that the velocity of the target is constant while it is in the antenna beam. The expression for the focal length of radar data is SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Rejpase 2000/04/12 : CIA-RDP67BOQ657R000300150001-1 SPECIAL HANDLING V 2 R r r F H = where V = film velocity Vr = vehicle velocity R r = range = radar wavelength r = correlator illumination wavelength. 0 In the case of a parallel moving target, only Vr, in effect, will change. Let subscript m denote a moving target, and let Vmx denote the target velocity component parallel to the vehicle path. Then the focal length of the data re- lating to the moving target is F =F m H where positive Vmx is taken to be the same direction as the vehicle's motion. The change in data focal length is LF = Fm - FH F = FH V r V r 2 - Vmx/ Finally, target speed in terms of iF is given by FH Vmx = Vr (1?FH J Since we assume that the target velocity will be less than the vehicle velocity, only the minus sign in the above expression need be used. SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Figure 2 Approved For Reuse 2000/04/12 : CIA-RDP67BOGS57R000300150001-1 SPECIAL HANDLING It is well to remember that in this expression FH is the focal length of the data itself; correlator optics have not yet been considered. 2. 2 Perpendicular Motion Analysis of perpendicular motion requires an understanding of the Doppler shift. The Doppler return from a stationary target is shown in Fig. 1. Figure 1 This frequency appears as a modulation of the radar carrier frequency fr. The carrier is normally heterodyned down to zero so that the modulation ranges from zero cycles out to its high-frequency limit fD max' as shown in Fig. 2. Carrier Highest Doppler return freq. (fr frequency (f D max + f r frequency No (a) Modulated return ,~Z (b) Return with carrier removed OW SPECIAL HANDLING VI-4 Range of Doppler modulations Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOO657R000300150001-1 SPECIAL HANDLING Target motion in the normal direction will produce a change in the Doppler spatial frequencies. Suppose a target is moving at a constant velocity Vmy; 2Vm the shift in frequency will then be . Let positive Vmy denote motion away from the vehicle path, and negative Vmy motion towards it. In Fig. 3 the solid line represents the normal spectrum of the data, and the broken line 2Vm represents the spectrum of moving-target data which has been shifted by frequency No Figure 3 The correlation appears relative to where the zero frequency of the Dop- pler modulation appears on the data film, for the modulation is a hologram, which acts like a lens: if the optical axis moves, the image moves. Thus a shift in the Dopper return causes an azimuth offset of the correlation. This offset can easily be calculated by reference to Fig. 4. FH Figure 4 SPECIAL HANDLING VI-5 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67B0W7R000300150001-1 SPECIAL HANDLING The axis represents zero frequency, and the frequency at any other point on the hologram is denoted by the variable fD, the Doppler frequency. From previous studies we know that g = FH Xo fD' where g is the distance from the axis to the point where the frequency fD ap- pears, and A o is the wavelength of the correlator illumination. The offset can be denoted by Ag, and the Doppler shift by A fD. We have then Ag = FH X0 AfD. 2v We know though that AfD is simply m , so r Og=2V F my H This gives the correlation offset distance at the natural focal length of the data. Finally, Vmy = Xr A g. ZFH o / 3.0 Measurement The following discussions assume a correlator without range compensa- tion. With compensation the need for the range-variable graphs will be obviated. 3. 1 Parallel Motion A change in the data focal-length results in a change in the position of the output plane, which can be readjusted to focus by means of a cylinder SPECIAL HANDLING VI-6 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Re4&ase 2000/04/12: CIA-RDP67B011657R000300150001-1 SPECIAL HANDLING lens. It is difficult to calculate from system parameters the amount of move- ment required by the cylinder lens; therefore a means has been devised to calibrate the correlator. Test holograms of known focal length can be inserted in the system, and the position-at-focus of the cylinder lens noted. From these points a curve of data focal-length vs. cylinder lens position can be constructed, and from the curve one can convert a change-in-cylinder-position to a change-in-data- focal-length. Since we have seen that a change in focal length is proportional to velocity, there must also be a curve by which a change in data focal-length can be converted to velocity. 3. 2 Perpendicular Motion In this case the correlator can be calibrated by successively inserting the test holograms and moving each by a known amount. The resultant off- set can be noted for each, and a graph constructed. One picks the appropri- ate value of FH, then reads the corresponding ratio of Qg , where At is the amount of offset in the correlator output. Since At can be measured, Ag can be found and substituted in the equation for V m Y . There is, however, a problem involved in finding the offset distance, namely: from where is the correlation offset? Most ground vehicles travel on predetermined paths: automobiles on highways, trains on tracks, etc. One simply decides where the target was probably traveling, and measures the offset distance from that point. Another class of targets is more difficult: ships at sea, sports cars on sand flats, etc. There are no predetermined detectable paths for these tar- gets, so assuming the target is relatively isolated one can measure its MW SPECIAL HANDLING VI-7 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For RWpase 2000/04/12 : CIA-RDP67BO 657R000300150001-1 SPECIAL HANDLING spectrum and compare it to the spectrum of the complete data. The difference between the two is then the Doppler shift, as was shown in Fig. 3; and the appropriate equation is Vmy = 2r QfD? This method is, of course, applicable to any type of moving target so long as the target can be effectively separated from its environment in such a manner that AfD can be measured. SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Re#oase 2000/04/12 : CIA-RDP67BOQ7R000300150001-1 SPECIAL HANDLING Appendix VII SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BOO667R000300150001-1 SPECIAL HANDLING Appendix VII 1. 0 Introduction The signal-to-noise ratio and diffraction ring ("side lobe") suppres- sion of an aperture-limited system can often be improved by use of aperture weighting. Investigations of the detail correlator were begun about a year ago. The first finding was that photographic film, on which filters are normally made, was insufficiently flat, and impaired the resolution of the relay lens. Obviously optical-quality glass was required for the filter. Another difficulty arose from the granularity of the photographic emulsion, which tended to scatter too much light. Deposited aluminum filters were chosen finally because they offer much better scattering characteristics, although such filters are more difficult to fabricate. The varying transmission is obtained by depositing the aluminum through a narrow slit which oscillates in front of the surface to be coated. Gradations in density are controlled by the velocity of the slit, since the evaporation rate is constant. A cam of a certain profile is required to drive the slit in the proper manner. The cam operates through a linkage which can be adjusted for any desired bandwidth. SPECIAL HANDLING VII-2 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67B00667R000300150001-1 SPECIAL HANDLING 2. 0 Determination of Cam Profile The nomenclature in this section is as follows: d = rate of evaporation D = density V = slit velocity s = slit width N = number of revolutions t = time/revolution 0 = angle of cam revolution x = distance traveled by the slit Now we can formulate the basic equations. First, D = dNt (rate of evaporation x total time) D=dN(2Vs) V = D (where k = 2dNs). And second, d9 = w (a constant), at dx = at v (a variable). Substituting and integrating, do w ax = v x 0 = k D dx. SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For ReIse 2000/04/12 : CIA-RDP67BOO467R000300150001-1 SPECIAL HANDLING This last equation means that one must construct a graph of the desired density-displacement function and integrate, presumably by direct measure- ment. For each value of displacement x there will be a unique 9, so the shape of the cam is now completely specified. 3. 0 Designing the D-x Curve The optical system is represented in Fig. 1. Figure 1 frequency plane relay lens (magnification of . 646) g = m AfF, as shown in Fig. 2, where f and g are the variables. The frequency plane F grating of frequency f frequency plane Figure 2 displays the spectrum of the input material. SPECIAL HANDLING VII-4 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12 : CIA-RDP67BO 6557R000300150001-1 SPECIAL HANDLING By calculation, in the optical system of Fig. 1, g = m XfF _ (. 646) (2. 5 x 10-5) (24) f f = 3. 88 x 10-4 = . 388 miles per cy./inch f g = 2. 58 cy. /in. per mil By actual measurement on the system itself, R = 3. 94 mils per cy./in. f f = 2. 54 cy. /in. per mil, g which is in excellent agreement with the calculated values. The spatial frequency spectrum of the input film was measured and found to be as in Fig. 3. It agrees with values that had been calculated 200 cy. /sec. r--z- - __ -~- 200 400 600 800 cycles/second Figure 3 SPECIAL HANDLING VII-5 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Release 2000/04/12: CIA-RDP67B007R000300150001-1 SPECIAL HANDLING some time ago. The bandwidth at the half transmission points is 125 cy./sec. (The cy. /sec. designation incorporated the film speed factor of 1.2 in. /sec. } Now the D-x curve can be drawn, for we know the bandwidth of the data, the location of peak data response, and where this frequency appears on the Fourier plane of the optical system. A model of the curve for 250 cy. band- width appears in Fig. 4. 0.4 0.8 0.12 Displacement x in inches Figure 4 One assumption was made in the construction of this curve. If the center were actually zero density the velocity of the slit would be infinite. This is clearly impossible so a minimum density of 0. 3 was chosen, which led to a maximum density of Z. 0. The final specifications for the cam are at- tached. 4. 0 Cam Profile Tolerance The controlling factor on film accuracy is the cam-follower velocity, i. e. the slope of the cam profile. At the filter center let us assume a SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Rel.ase 2000/04/12 : CIA-RDP67B097R000300150001-1 SPECIAL HANDLING maximum allowable tolerance of +20% of the transmission. The fractional density variation is then + log10 1. 2 = +. 075. The center density is 0. 3, so the permissable change in density is + ' 075 5 = +. 25. Because density is in- versely proportional to velocity the tolerance on velocity is +25%. The cutting stations on the cam profile are spaced 4 mils in radius. Thus a 25% error in slope corresponds to an error of one mil between cutting points, or an error of 0. 5 mil in each cutting point in the worst case. SPECIAL HANDLING VII-7 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Rese 2000/04/12 : CIA-RDP67B00667R000300150001-1 SPECIAL HANDLING Appendix VIII INTERFERENCE PATTERN GENERATOR SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Reesese 2000/04/12 :_CIA-RDP67B0W7R000300150001-1 SPECIAL HANDLING Appendix VIII INTERFERENCE PATTERN GENERATOR 1.0 Summary This report contains an analysis and design information for an optical device that generates an area interference pattern using a photographic trans- parency as input. An area containing patterns of any desired length, frequency and focal length can be generated by this method. The problem of obtaining a pattern of varying focal length in one dimension to simulate range has not yet 25X1A been solved. The method was first proposed by in memoran- dum ED-M-510 dated 12 December 1962. 2. 0 Basic Principle 2. 1 Radar Pattern The pattern we wish to simulate is that due to the phase shift of a radar signal emitted from a vehicle at A, reflected from a target T and received back at A as shown in Fig. 1. The vehicle velocity is assumed negligible compared with the propagation time of the radar signal. The phase shift is given by 0 __ ZAT 2 R ~ R ~R where XR = radar wavelength R0 = offset range x = distance along vehicle track SPECIAL HANDLING Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For R E; OQ/ L2 : "AqqB (q00300150001-1 Figure 1 Radar Geometry and Interference Pattern Figure 2 Simulator Geometry Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1 SPECIAL HANDLING VIII-3  Approved For Release 2000/04/12 : CIA-RDP67BOO657R000300150001-1 SPECIAL HANDLING The spatial frequency produced by this phase shift is F = dO 2 x 2 sin 9R R UT A R o + x2 The pattern frequency gradually drops to zero at the point opposite the target as shown in Fig. 1. 2. 2 Simulated Patterns Figure 2 shows the essential geometry of the simulator. Consider a wave emitted from A in the direction AX, and a second wave coherent with the first travelling in the direction XB. The phase difference between wavefronts at point X is AX+ BX OS - 0 If the point X lies on the axis and AX = BX then 2AX = _ S Pattern frequency 0 F = 2 x = 2 sin 90 s Xo d2 + x2 Ao Thus a pattern with similar properties to the radar pattern is generated. Note that it is essential for the wavefronts to be travelling in the directions indicated, away from A and toward B, or vice versa, This can be seen from Fig. 3(a) and (b) which show the interference patterns produced by two spherical waves centered on focal points a short distance apart. In Fig. 3(a) both points are radiating coherently to produce an interference pattern at plant P. This is not the pattern required. If the direction of one of the SPECIAL HANDLING VIII-4 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For R2`904/J*L : CA- A qWtPMFJ00300150001-1 Movement of wave crest Figure 3(a) Figure 3(h) Approved For M150001 - fl`~~Q~'n l~FR6?65d08fl0 SPECIAL HANDLING Interference Pattern with Both Sources Radiating Si P Movement c wave cres S N Direction ofwavefronts  Approved For Release 2000/04/12 : CIA-RDP67B04657R000300150001-1 SPECIAL HANDLING wavefronts is reversed as in Fig. 3(b) the required pattern is produced along the plane P. In practice an opaque film would be placed at P and both waves would impinge from the same side as indicated in the diagram. 2. 3 Optical System The optical system necessary to implement this idea is shown in Fig. 4. The transparency is illuminated with collimated, monochromatic light from source S. In the range dimension the transparency is imaged directly onto the film plane by the spherical lens L1. In the azimuth dimension, in which the interference pattern is required, the lens L1 would normally image the transparency in the same plane. How- ever, two addition cylindrical lenses L2 (positive) and L3 (negative) split this into two images at points A and B. The two wavefronts produced by these lenses form the desired interference pattern between points C and D as shown. The lens stop is vital to operation of the system. It is essential that the two wavefronts exactly overlap to produce the pattern. Any spillover will re- sult in the film being fogged. Exact overlap is achieved when the two sides of the lens have apertures in proportion to their focal lengths, as shown. The zero stop must be of suf- ficient width to give the desired pattern offset frequency. Design formulae for the optical system are developed in the next section. 3. 0 Analysis of Pattern Simulator The following analysis is based on a single point T on the transparency. It is equally applicable to an ensemble of points. Referring to Fig. 5, let the phase angle of the wave reaching Al be 00 SPECIAL HANDLING VIII-6 Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1  Approved For Re~ l64ljkLCIA-Ffj*fQ7ljppp 00150001-1 sua-r T'eo -T.IPUTTAO 4tTds do3s suaZ suet Teot.zaqds Approved For Release 2000/04/12 : CIA-RDP67B00657R000300150001-1 SPECIAL HANDLING  Approved For R a cJcI%LII 2 : 11A W- 1 Figure 5 Optical Geometry Approved For R a e A412 : 04~~OfIV fJ00300150001-1 VIII-8  Approved For Release 2000/04/12 : CIA-RDP67B@9657R 00300150001-1 SPECIAL HANDLING and let the phase of the wave reaching B1 be 0o + upper wave at D1 is 1 1 0.U = 0o + A D Phase angle of lower wave at D1 is OL=0o+0l - D1B1 01' Then phase angle of - l wavelengths. AO=0U-0 =A1 D1+D1B1 Cb A1Dl = 1/a2 + (PC1 + x)2 PC1 = a tan ar .'. A1D1 = a` + (a tanor + x) Similarly D1B1 +(btanof-x)2 Qo_ Vd2+(atanoc+x)2 + - \ / b 2 x ,LO b the spatial frequency F = d Scx x + a tan of + x - a tan of A (x + a tan oc)2 + (a tan oc - x) = 1 sin (a