PROJECT VERTICON

MUMMIIMMIPMV ApprovecWrRelease2002/0SECRWRDP63-13Q13A000600150042-4 DEFENSE PRODUCTS DIVISION Fairchild. Camera and Instrument Corporation Robbins Lane, Syosset, New York PROJECT VERT ICON PROPOSAL NO. SNE-CA-80 1 February 1959 PHONGRAPHIC RECONNAISSANCE from VERTICAL FIRING ROCKETS This document contains information affecting the National Defense of .the United States within the meaning of the espionage Laws, Title 18, U.S.C. Sections 793 and 794, the transmission or revelation of which in any manner to an unauthorized. person is prohibited by law. NRO REVIEW CW/Iiitii?freTcMr Release 2002/ I. Copy No. / XRGW-RDP63-00313A000600150042-4 Approved For Release 2002/OttbatRDP63-00313A000600150042-4 "ftir Nair DEFENSE PRODUCTS DIVISION Fairchild Camera and Instrument Corporation TABLE OF CONTENTS Title Page Table of Contents Summary General Discussion Technical Discussion Ground Support Equipment Appendix List of Illustrations 1. Vertical Rocket Reconnaissance 2. Reconnaissance System for Ballistic Rocket. 3. 100" Rotary Panoramic Camera 4. Basic Rotary Panoramic Camera 5. Radius of Coverage vs. Altitude 6. 12" Rotary Panoramic for Rocket 7, Photographic Ground Coverage of Panoramic Camera 8. 12" Rotary Panoramic with Wobble 9. Multiple Camera Installation 10. Photographic Coverage from 100 11. Photographic Coverage from 600 120 Fairchild Four Lens Camera 13. Four Lens Camera Mockup 14. Four Lens Camera Mockup 15. Four Lens Camera Mockup 16. Four Lens Camera (Cut-away View) 17. Single Camera Installation. Proposal No. SHE-CA-80 1 February 1959 Page No, Unnumbered ii 1 3 10 Trajectory 12" Rotary Control Miles Altitude Mile Altitude Approved For Release 2002/02i2CM-RDP63-00313A000600150042-4 Approved For Release 2002/0wgbferRDP63-00313A000600150042-4 Awl" Nam DEFENSE PRODUCTS DIVISION Proposal No. SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 PROPOSED An adaptation of a simple and reliable scanning camera for use in small or intermediate size vertical firing rockets. APPLICATIONS Rapid and large area surveillance. Rapid meteorological surveys. Reconnaissance for geodetic control surveys. ADVANTAGES High information yield. Flexibility of usage. Low equipment cost and short delivery schedule. CAMERA DESCRIPTION The basic camera is a scanning rotary pan- oramic for use with spinning rockets and a compact array of miniature cameras for non-spinning rockets. Wide lateral angular coverage with 3600 azimuthal coverage. Approved For Release 2002/02eCREKIRDP63-00313A000600150042-4 Approved For Release 2002/01gberDP63-00313A000600150042-4 .8?? DEFENSE PRODUCTS DIVISION Proposal No. SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 VERTICAL FIRING ROCKET RECONNAISSANCE SYSTEM This proposal presents PROJECT VERTICON, a system for photographic reconnaissance from vertical firing rockets. Vertical firing rockets will be an ideal vehicle for relatively low cost, rapid reconnaissance for meteorological data, large area surveillance, and extremely accurate geodetic control surveys. Depending upon the nature of the mission and rocket selected as the vehicle, the camera installation can run from an extremely simple low cost unit using 16mm, 35mm, or 70mm film to more elaborate and sophisticated installations using special optics for extremely high information content in the case of long range surveillance or precisely calibrated mapping lenses and cameras for geodetic control. GENERAL DISCUSSION In the gathering of intelligence information utilizing photographic sensors for reconnaissance purposes in a high altitude vertical firing rocket two primary factors come under consideration - Scale of Photography and Ground Coverage. Dur- ing the determination of a suitable reconnaissance sensor from the vertical firing rocket two types of cameras have been con- sidered which in general are suitable to the two types of rockets, i.e., spinning rockets and non-spinning rockets. The scale of the photography is determined by the focal length of the camera selected (regardless of its type) and the altitude of the rocket at the time of exposure. Ideally, the scale would be solved by providing the longest focal length possible in the limitations set by the vehicle. The ground coverage of the reconnaissance system is deter- mined by the focal length of the camera, the size of the film platen (format) and the altitude of the rocket at the time of exposure. Ideally, the coverage would be horizon to horizon and 360? in azimuth providing complete ground coverage. The Approved For Release 2002/0E@C:RE4-RDP63-00313A000600150042-4 Approved For Release 2002/0t/gtearRDP63-00313A000600150042-4 ,????. ISM DEFENSE PRODUCTS DIVISION Proposal No. SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 same "ideal" coverage applies to the consideration of photographic sensors for meteorological or geodetic control surveys with a reduced emphasis on scale of the photography for meteorological purposes and an increased emphasis on system distortion for geodetic control surveys. Figure 1 illustrates the general application of the photo- graphic reconnaissance sensor to a mission utilizing a vertically fired rocket and whose usage may include general reconnaissance or "looking over the fence", weather reconnaissance, or geodetic mapping. In the past, the combination of long focal length and wide or large coverage has been impractical since it means a large and bulky installation of a multiplicity of long focal length cameras. Today, however, the combination can be obtained by the use of a single camera installation which by its technique of operation can provide wide angular coverage. As applied to a spinning rocket, this single camera installation is a SIMPLE ROTARY PANORAMIC CAMERA The restriction placed on the installation to obtain this large information level is that the rocket itself or some part of it must spin about its longitudinal axis while rising in its trajectory before and/or after burn-out of the final stage. In the case of rockets which are designed to "Spin" this presents no problem. In the case of the frame by frame camera (or square format camera) applied to a spinning vertical firing rocket installation the large angular coverage which is required makes it mandatory to have either a multiplicity of cameras or fast cycling rate for a single camera with an extremely fast shutter speed required in either case to prevent photographic blur due to rocket rotation. Such an installation can be made using the shorter focal length lenses with the smaller format sizes. Considering the non-spinning rockets such as "ARCAS", "ARCON" and "IRIS" the photographic reconnaissance mission can be accomplished by a cluster of miniature cameras utilizing existing wide angle lenses such as the 1-1/2" Biogon and a 2-1/4 x 2-1/4" format. The decision as to the camera design to be used actually rests with the rocket design selected to carry out the mission and the type of reconnaissance mission. For a rocket with a 15" diameter such as the Aerobee-Hi a single camera housing utilizing four lenses can be mounted at the extreme lower portion of the rocket. Such an installation is discussed in the next section of this report. It should be noted here that this type of installation will provide reconnaissance from alti- 2 Approved For Release 2002/0SIECREWRDP63-00313A000600150042-4 Approved For Release 2002/0?gtrferRDP63-00313A000600150042-4 Now/ DEFENSE PRODUCTS DIVISION Proposal No, SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 tudes between the time of sustainer drop off and the peak of the trajectory. During this portion of the flight it can provide photography of the entire area visiblelhorizon to horizon through a full 3600. Based on the estimated performance data of the Aerobee-Hi this would be from altitudes of 26 miles to 168 miles. For a rocket of smaller diameter the "cluster" of cameras may be spread out along the longitudinal axis - making five individual miniature cameras and a single miniature to photo- graph from the bottom portion of the rocket. Where the par- ticular mission requirements permit, a delay in the operation of the vertical camera will permit oblique photography before sustainer drop off and, therefore, provide larger scale oblique photography with a minimum blind spot. The film footage required in any installation is dependent upon the length of time of the coasting phase and the duplication of photography desired. It is considered appropriate in the case of a "cluster" of cameras that several francs be exposed of the same (full coverage at each exposure station) area since the scale will be different at each exposure station and multiple observations will aid in the interpretation of data. It must be pointed out that although the specific applica- tion presented here is for the vertical firing rocket, the basic approaches may be used in other ballistic trajectory rockets as illustrated in Figure 2. In the accompanying discussions it is realized that the vehicle payload includes other equipments such as parachute and recovery beacon in addition to the photographic sensor. Characteristics of typical vertical firing rockets are appended hereto to provide the necessary technical data to aid in system selection and specification, TECHNICAL DISCUSSION This section is devoted to a technical discussion of the types of cameras and their application to a vertical firing rocket recon- naissance system. - 3 - Approved For Release 2002/0NC:14WPROP63-00313A000600150042-4 Approved For Release 2002/0gigtratRDP63-00313A000600150042-4 DEFENSE PRODUCTS DIVISION Proposal No, SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 a. Panoramic b. Frame by frame cluster of cameras c. Frame by frame single lens camera d. Frame by frame four lens camera A. Panoramic Cameras The use of a panoramic camera permits the use of lens design techniques which result in a higher performance in terms of imgge quality than a lens design for a square format (frame by frame) camera within a given weight and cost. This advantage is attrib- utable primarily to the reduction in the 1/2 angle field of view of the lens since the panoramic camera format is a slit (a few thousandths of an inch the width of the film being used) as opposed to the diagonal of a square format camera (usually 1.414 times the width of the film). Using this advantage of design it is possible to increase the speed of the lens (within the same weight and cost) which permits faster shutter speeds. With modern large aperture lenses (together with improved transmission factors) and the high speed emulsions, very fast shutter speeds can be used to obtain accept- able exposures. In the panoramic camera where the exposure time is obtained as a junction of film transport velocity and slit width speeds upwards of 1/4000 to 1/5000 second are practical. Such exposure times go a long way towards reducing the amount of "smear" normally resulting from image motion. The determination of the correct film transport velocity across the exposure slit as a function of the rocket spin rate can be accomplished in at least three different ways as follows: 1. A small rate gyro can be installed within the rocket, the spin axis of the gyro being perpendicular to the spin axis of the rocket. An electrical signal can be derived which is pro- portional to the spin rate and thus becomes the input to a servo drive for film transport, Approved For Release 2002/06,42C:R:g4IRDP63-00313A000600150042-4 Approved For Release 2002/042gbferRDP63-00313A000600150042-4 'MOW '4111Ir DEFENSE PRODUCTS DIVISION Proposal No. SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 2. Depending upon the operational concept of the rocket reconnaissance the spin rate may be obtained by photo-electric means such as an input to a photo-electric sensitive surface from the sun. 3. launch. The spin rate of the rocket may be preset before Combinations of these may also be used, for instance, the determination of preselected spin rate just prior to the last stage burn out by photo-electric means after which the spin rate would have a minimum of change in the absence of atmos- phere to retard it. Figure 3 represents embodiment of a SINGLE ROTARY PANORAMIC .CAMERA in a 100 inch focal length showing an extremely long focal length lens in a minimum package and. serves to emphasize the major advantage of this type of camera: LARGE SCATg WIDE ANGULAR COVERAGE IN A SINGLE CAMERA. In this camera type the lateral angle is a matter of designer's choice. It is shown in its usual orientation; that is, with its optical axis para- llel to the ground plane, with a single reflecting surface in front of the lens to direct the optical axis vertically down- ward. The instantaneous field of view of the lens is limited to a rectangular area determined by the film width in one direc- tion and the width of an exposing slit in the other. The feature of flexibility of lateral angular coverage is accomplished as illustrated. in Figure 4. Exposure is made by drawing film past the slit as the entire camera including the magazine, rotates about its optical axis. This rotation is continuous in one direction, the angular -velocity normally being a function of V/H and. overlap requirements. Thus, it is possible to scan continuously, 360? around the longitudinal axis with all parts of the camera moving uniformly without inter- mittencies of any kind. Film velocity from. supply, through the exposing slit to take-up spool in this case would be constant. However, since scan angles greater than 180? (horizon to hori- zon) are seldom required in a vehicle with its axis horizontal it is necessary to move film across the slit during only part of the rotation. The spools, themselves, however, continue to turn, feeding and taking up film at an average rate which furnishes the amount required for the portion of the rotation during which photography occurs. Chambers for the slack film Approved For Release 2002/0812-C:RWPRDP63-00313A000600150042-4 Approved For Release 2002/SE2.Rep-RDP63-00313A000600150042-4 DEFENSE PRODUCTS DIVISION Proposal No. SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 are provided on each side of the slit. Referring to Figure 4, the transport cycle proceeds as follows: Film is drawn from the supply spool by a pair of pinch rollers turning at a speed which is integrally tied to the rotational speed of the camera, which in turn is proportional to V/H. The film then passes under a roller attached to the scan stop switch, thence through the pressure plate assembly around. the metering drive roller, and idler roller, and onto the take-up spool. The metering roller is mounted on a rock- ing member in such a way that it does not contact the film except during the scan period. This roller is continuously driven at a speed proportional to the camera rotation. It is brought into contact with the film by the solenoid (shown sche- matically) when the camera reaches the point selected for start- ing the scan. The film previously accumulated. in the supply chamber is then drawn. past the exposing slit at a speed which is synchronous with the image being swept across the slit by the rotating mirror. As the film runs out of the supply chamber it actuates the scan stop switch, which de-energizes the sole- noid, causing the rocker arm to tilt counter-clockwise, disen- gaging the driving roller and engaging a fixed. roller on the opposite side of the gate, which serves as a brake to hold the film from coasting or being fed across to the take-up spool when the latter takes out tle slack loop which has been trans- ferred into the take-up chamber. The take-up spool is simply overdriven sufficiently to take out all the slack film before the next scan. occurs. In a more refined version or where the mass of film is great, a second pair of pinch rollers would be used at the take-up side to meter the film to the spool at a rate which would. keep the spool turning continuously. Control of the supply loop by the above method prevents accumulative build-up, or loss by virtue of the fact that all the film (whether too much or too little) is withdrawn each cycle. The effect of a slight over or under supply is merely to add or subtract proportionately from the angle scanned- - 6 Approved For Release 2002/08NCRIURDP63-00313A000600150042-4 Approved ForRelease 2002/0getnit-RDP63-00313A000600150042-4 DEFENSE PRODUCTS DIVISION Proposal No. SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 Figure 4 indicates one way in which the entire camera can be rotated by a single drive motor. In this case a fixed sleeve which would be mounted to the aircraft structure or a mount as the case might be, supplies bearing support for the camera. A belt is used to couple the motor to the camera through a cut-out in the fixed. sleeve. Driving of the various rotating members in. the magazine is effected by a pinion which rolls on an internal ring gear fastened to the fixed sleeve. In order to maintain the shutter speed through variations in V/H the adjustable slit mechanism will, contain an overriding control, which will be actuated as a function of the rotational speed. Other functions such as remote exposure control involving iris and/or the slit width are readily adaptable by usual servo methods. The only difference here is that all these items will be rotating continuously about the optical axis. As used i:o a vertical firing spinning rocket the basic camera described above would, be oriented with its optical axis perpendicular to the ground plane with a single reflecting sur- face mounted so as to have a field view downward and outward, Although the camera housing is shown separate from the rocket shell it is pointed out that the camera and. shell rotate together at the rocket spin rate. If final installation considerations show it to be advantageous the camera housing and rocket shell can be combined, as one unit. Depending upon the vertical velocity and spinning rate of the rocket the field, of view of a continuously operating camera may result in a spiral coverage with a discontinuity of coverage in the radial direction. To prevent such an occurrence the reflect- ing surface may be programmed. to pivot about its midpoint as a function of the vertical, velocity and spin. rate. In order to determine the optimum exposure altitude for each panoramic sweep it is necessary to determine the coverage which can be made from a specific altitude. '-7 Approved For Release 2002/0a-KRURDP63-00313A000600150042-4 Approved For Release 2002/5MR1A-RDP63-00313A000600150042-4 Nor DEFENSE PRODUCTS DIVISION Proposal No, SME-CA-80 Fairchild Camera and instrument Corporation. 1 February 1959 Figure 5 is a plot of the ground. coverage (arc distance on the earth's surface) as a function of altitude for two angles off the vertical. In this case 64? and. 74? were selected since a panoramic camera of 12" focal, length using 5" wide film is under consideration- The optical axis is positioned. at 74?, therefore, providing a field of view from 63-1/2? to 84-1/2?, (Only a nominal angular value (64?) has been used. in the plot), Also shown is the radius (arc distance) to the horizon as a function of altitude. This plot provides a way of selecting the altitudes for exposures to be made Thus, if the first exposure is made at 25 miles, coverage is provided from a radius of 50 miles out to the horizon at 425 miles. Since the high oblique contains inform- ation which is not extremely useful for certain intelligence purposes, it may be necessary to provide overlap in. the radial direction. For purposes of illustration, consider 50% radial overlap or the next exposure at such time as the blind spot becomes approximately 100 miles (see 25 mile altitude at 74? curve on plot). Such an exposure will extend from approximately 100 miles to the horizon at 625 miles. By following this sequence, the exposure stations can be determined. Figure 7 with the overlays illustrates the coverage of this type of operational technique with the following conditions: Exposure No. Altitude Extent of 360? Coverage I (red) 25 miles 104 to 886 miles 2 (green) 40 " 170 to 1120 3 (black) 75 i, 344 to 1530 " 4 (blue) 140 " 624 to 2076 " 5 (yellow) 275 " 1380 to 2870 " 6 (orange) 345 " 1894 to 3194 " - 8 - Approved For Release 2002/08NCOIMIDP63-00313A000600150042-4 Approved For Release 2002/0K2ER1f-RDP63-00313A000600150042-4 DEFENSE PRODUCTS DIVISION Proposal No. SNE-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 The coverage as shown is predicated on the use of a 12" focal length lens and 5" film configured into a Fairchild Rotary Panor- amic Camera as shown in Figure 6. To make full consideration of the rocket performance, Figure 8 illustrates the application of a 12" panoramic camera with a rotatable mirror used to overcome wobble which is experienced in the rocket during sustainer firing and after sustainer fall off. The foregoing descriptions of specific panoramic cameras and coverage also applies to panoramic cameras using 35mm or 70mm film. These smaller sizes are quite ideal for weather reconnaissance using the smaller diameter rockets. B. Frame by Frame Cameras For application to non-spinning rockets the same coverage as indicated above can be obtained utilizing 5 cameras set in an oblique position as indicated in Figure 9. As can be seen the five oblique cameras have been "stacked" along the longitudinal axis of the rocket to fit into a 6 inch rocket such as the ARC0N0 Similar installations using other cameresand film sizes can be made for the 12 inch diameter IRIS, the 4-1/2" diameter ARCAS, the 8" diameter instrumentation chamber of the AEROBEE-300 (SPAEROBEE) or in the case of weather reconnaissance even smaller rockets. Specifically consideration has been made for a 16mm rotary panoramic camera using a 25mm lens to provide 360? cover- age from up to 38 different altitudes in a two inch diameter rocket. Figures 10 and 11 indicates the coverage obtainable from such an array of cameras from altitudes of 100 miles and 600 miles respectively. Fairchild Camera and Instrument Corporation has recently completed a preliminary design of a four lens camera for use as a reconnaissance camera from high altitude. The application of this camera to a vertically fired rocket is shown in Figure 12. This camera provides an angular coverage of 156? "lateral" or 78? from vertical in all directions (360? coverage in azimuth). As illustrated in Figure 12, it is obvious that such an instal- lation is applicable to rockets of 15" diameter and larger, - 9 - Approved For Release 2002/0SKRIAIRDP63-00313A000600150042-4 Approved For Release 2002/0gECKETRDP63-00313A000600150042-4 DEFENSE PRODUCTS DIVISION Proposal No. SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 whose sustainer is ejected. It is not impossible in the larger rockets to make provisions for retracting the camera (or take-up spools) to allow for recovery techniques required such as seal- ing the end of the nose cone. This installation will photograph the entire earth's surface (horizon to horizon - 3600 in azimuth) from altitudes of 110 miles and above. Figures 13, 14 and 15 are photographs of the mockup made of this camera. Figure 16 is an artist cutaway view of the four lens camera showing the relationships of formats, film supplies, drive package and the automatic exposure control sensing element. GROUND SUPPORT EQUIPMENT The intelligence obtained from the photographic record will depend to some extent upon the ground support equipment furnished. This equipment falls into two major categories, each identified with the type of camera; panoramic and frame by frame. For general reconnaissance each category must provide a rectification of the photographic record to a useable datum. In the case of the panoramic camera, this rectification may be done in several ways. The most direct approach would be an autofocusing enlarger which would rotate to cause an ex- posure of a narrow field of view and simultaneously increase its height above the datum to compensate for the rocket increase in altitude during a single panoramic exposure. The relationship between the rate of rotation and translation will depend On the vehicle selection (rate of spin and velocity at the time of exposure). Other types of rectification may be possible for certain types of intelligence to be obtained such as point location, contin- uous charting of a single feature such as river, coast line or transportation network. In this type of intelligence, point by point rectification may be considered adequate. - 10 - Approved For Release 2002/00BEIMARDP63-00313A000600150042-4 ANS awl Approved For Release 2002/0SECM-RDP63-00313A000600150042-4 NNW DEFENSE PRODUCTS DIVISION Proposal No, SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 In the case of a frame by frame camera where each frame of a cluster of cameras may be considered as a single recti- fication the problem is simple. The overall picture, however, that of transferring from detail in one frame to detail in another frame taken from the same exposure station becomes somewhat more involved. Here it is presently considered appropriate that the ground support equipment would be based on an analytical solution relating each frame to the vertical as a "zenith angle" and "azimuth angle". From such analytical data) adjustments may be made as multiple observations are made of the same points in subsequent exposures. Approved For Release 2002/0SECR11IDP63-00313A000600150042-4 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 , g q' 0 LI Ce 1PCI 11 1 it -N\ I ---\ RECOVERY I \ I I I plawraar LAUNCH--\ 1 1 WATER off 1:41'44 ? t" 4F?17,7 BURN OOSTER BURN OU I POLITICAL BOR PE:R. USAGE I, LOOKING OVER THE FE 2. WEATHER 3 GEODETIC MAPPING. FIGURE I. Approved For Release S811d891f. m_wisb_Fozwisnimuivoc4E4 ? ? Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 ? COMPLETE PHOTO COVERAGE ott ? ? ? WATER - ? 41- RECOVERY J WATER _ ? FIGURE 2 RECONNAISSANCE SYSTEM FOR BALLISTIC TRAJECTORY ROCKET Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042BEGRET Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 TYPICAL OPE-MA 7-10/4 I1ACH 2. AL7777.1DE _ _ _ _ _ _ _ 40 000 pr ...72cAL L.r.V.77W _____ /00 /.../ SCAN 77mtE _ _ . 4/6 .5a-C. - PILN PIER SCAN__ __ /04.7" 40,7-ZR GROZINV COVERAQR PER sCAW - .12 0.554) *MA-5 ove.fti-A,. IPZSOLWWW- - 6Fr cts-recr 04/ mettv.hvo. .ttia'av r-/LAI CA.WEAMI SPEED _ 24 RP/4 / , 40? ? SC41./ ? Frey Rau /000.1: MLA! CA/R4eK FIXED DI2IVX MOM! Oe'Rt77211770IV 100;0E-ENS l'AXIAIXYGVAIWITYPX) CIIMISX SMELL CAMEIPA AXIS I2C7ATIAIG FIXED FIKK.0 Dier720011461EZ, NordiriAtes, rizair Aolammtvz- PIVIELOAaXD BAAL AlEARIAWS POO 'ROTARY PANORAMIC CAMPirleA . 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CIA-RDP63-00313A000600150042-4 ; --T T Approved For Release 2002/0593ENCIA-RDp63gp313A000600150042-4 Niori DEFENSE PRODUCTS DIVISION Fairchild Camera aid Instrumet Corporation .s-74.7-,/a/v/74'r-- ,4-7/4',4"arr Proposal No. SME-CA-,j) 1 February 1959 .") i It 1 14. i.. I I ' I i' II ..1- ,i, i , /49 " /Fornyek- nv.2,7er/r/v e Ai /a /7- z / 7-'2)e 4'0 C 6' r / 7" , Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 SECRET e) ',/: _ Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 Approved_ For Release 2002/0?THR.1q1A-RDP63-14013A000600150042-4 vc DEFENSE PRODUCTS, DIVISION Proposal No. SME-CA-80 Fairchild Camera and. Instrument Corporation 1 February 1959 ?I C /1///424-/VX/9 7//tia C one 2-/ra,z, 1 I ' (i--- - -1, ? 0 /I I fili (4t-Iiiiiii lc 11 . . I. III 17..---:K---''S II I \ ,/ L-- ( l_f 1 11 ii .?-?.,..6.- '",,x-/z, 4,/," \ , .11 ?.--?.--,.,1_Q, ) _ 11 ...re/.00,.''e .k" "/W A - 7:. II _LI IIJ_. _ , ..,,, f , / 7: :11/// h '.-- I 1 \ I ''',.. , 1 -447-erec"Gxe.,vie I , I 1 \ I I i \ 1 I ,I I II _ t _ '\11 f- H F/ 61 8 / "Re) 7/742 VRiv/vcm-..7A.7/4-- Cr74,74,--/r,ov WI 77/ w 61 /5. x? 4. 41. c N r/70 Approved For Release 2002/08/HcAkek-RDP63-00313A000600150042-4 /6' 78 Approved For Release 2002/08/23E031C-RDP63-(4013A000600150042-4 . .._ ,,-- -?:) DEFENSE PRODUCTS JflrISION Proposal No. SM-CA-i0? Fairc hi ld , Came ::.a ildfr In:St I brAt Cokp . 1 Felyimalv. 1959 , I I. ? i \I! I 0 \ \ I I \ 1 I \ --- /V/YaZ 7/PC e- CR4-7E/ph, /A0'.,r7WLr/aN 1 1 \ ......--_?......_. i \ / i ,c-e),,ii- /7/'? C ON /Pac A-4,- r ,/ -/( ,/ I i ..,-... ,,,, ---.-- ,.,.F.. , 1 / l'-' ii.._... 1.1 -.!-// I 1 I ,1i I'. 11.1, / /I? - . // '1.\?:I i! I I/ P 1'' 11-4 I 1 I /1 I 1 i l / I I '--- FO/r4,7/9 J./. '`.. '''... le ?-- - 1. I I i / / ( V:;- ' oc7Z ,4,7 C ..9/0?..9C / r Y :' / ' I 1,..,. / i v4, ? ?.. cyr 70 1- AI "r; A- a /VI . ? . ? ? _ /. I ' - " /c-/C_ .9 Approved For Release 20102/08/23 : CIA-RDP63-00313A000600150042-4 /6. 6., 7 .7 SECRET P-Zi70091.009000VCI?C00-?9dati-VI3 MBOMOU aseeieu JOd 130A0iddV L thobosha r n A4BE TA " hu"hill; R. '.? Edoz,ii?,o4?,SASKATCFIEW AN MA ITOBA/ Pr op , ',i4tP11 .Pop,1 --MeTho Po pocatepilfict o p-Zi70091.009000VCI?Car-C9dati-VI3 MBOMOU aseeieu JOd 130A0-IddV Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 SECRET Approved For Release 2002/08/23: CIA-RDP63-00313A000600150042-4 ????? DEFENSE PRODUCTS DIVISION Fairchild Camera and Instrument Corporation 1 February 1959 Proposal No. SME -CA -80 i 1--' ---- ` If( ) j1/4. ..-s-,,,,,., 1) --- I Cps-(-1--1' L / 1 J. , - I \ 1 -- 1 / _ .-? < - '-- _ I '' . ( : --\ 1 '.------ ) 1) 4,-- /A/ s C/74-7e47,9 A-6yr ,4'/N /CZ 77 72/Dif /Po CA/IT .5" 4,7 70 /6 "-A7 1/A/ /TA- 0 /51 T'r-- F/ I A/7 A-7 a /2 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 SECRET 8 0 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 Approved.For Release 2002/08/23 : CIA-RDP63-0e313A000600150042-4 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 FIGURE 14 Approved-For Release 2002/08/23 : CIA-RDP63-0'0313A000600150042-4 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 FIGURE 15 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 FIGURE 16 Masa' Approved,for Release 2002/08/23 : CIA-RDP63-0.013A000600150042-4 DEFENSE PRODUCTS DIVISION Proposal No. SME-CA-80 Fairchild Camera and Instrument Corporation 1 February 1959 1 . 1 f,wce CAP/weir.? /N.1-2-A4 z 7/ON C o A/ ,fc? e 7' zc 'ric-74 -1-6/00,,z ENS 2 "X 2 A--o/e4-779 r - 0 To 6 c pv/w z7 0 w Approved For Release 2002/08/23 : CIA-RDP63-00313A00060015G0412-4, SECRET Approved For Release 2002/ONC:RWRDP63-00313A000600150042-4 A EMET UPPER ATMOSPI/ERE SOUND/Na ocitErs AERO BEE 75 AERO BEE 100 AEROBEE 150 AERO BEE 300 NO BOOSTER DUAL-THRUST SOLID 100 LB 75 MILES SOLID BOOSTER RFNA JP-"4 40 LES 100 MILES SOLID BOOSTER RFNA-ANFA 120 LB 190 MILES SOLID BOOSTER RFNA-ANFA (151 5T4 &E) rt e"rA SOLID 11, 2 14 r-t 65 LB FIN STABIL/ZED - NO 011/017NCE 300 MILES 17-Z1700 91.009000W I?n0-C9dCla763110/ZOOZ eseeieu Jag PeAoiddv P-Zi70091.009000VCI?C00-?9dati-VI3 : MBOMOU aseeieu JOd 130A0iddV Weights, lb Inert Propellants Launching weight (excluding payload) Dimensions Length, overall, in. Body diameter, in. Available payload volume, ft3 Sounding-Rocket Performance, 100-lb Payload UNCLASSIFIED SPECIFICATIONS AND PERFORMANCE PARAMETERS 515 628 943 205 14.0 up to 4.0 Zenith altitude, ft Zenith altitude, 1111 Sustainer burnout altitude, ft Sustainer burnout velocity, ft/sec Stability Calibers, 100-lb Payload Launching Booster burnout Sustainer burnout Launching Sea Level 358,500 68 77,130 4,327 Elevation 11..000 ft 3.7 3.5 1.5 423,000 80 86, !too 4,670 Ca AT SUSTAINER BURNOUT OPTIONAL NOSE CONVIGER AT ION ASSUMED PAYLOAD 100 LBS. Ca. AT BOOSTER BURNOuT 72 00 92.58 123.: 27.4 175.13 198.98 AEROBEE - 75 til4C LASS! FIED AEROBEE - 75 Approved For Release 2002/08/23 : CIANRINM-00313A000600150042-4 Name 90 r.? 4 Bo 70 6o Burnout Altitude vs Payload for Sea-Level and 4000-ft Launching Altitudes ft Sea Level 7 100 120 140 160 180 200 Payload, lb Burnout Altitude vs Payload m for Sea-Level End 4000-ft Launching Altitudes Zenkth Altitude vs Payload for Sea-Level and 4000-ft Launching Altitudes 14000-ft Launch 5e-Level Launch 120 140 160 180 200 Payload, lb Zanith Altitude vs Payload For Sea Level and 4000-Et Launching Altitudes ,9 100 90 80 14000 ft 90 70 AEROBEE - 100 Sea Level 60 A 50 60 A 1L4 AEROBEE - 150 AEROBEE - 300 130 Payload;.16 So 60 Bo 100 Burnout hit, lb 326 346 366 386 Burnout Altitude vs Payload for See-Level and 4000-ft Launching Altitudes 4 -ft lat ch Sea-Level Lau ch .r? 120 140 160 180 200 220 Payload, lb Burnout Altitude vs Payload ? 130 ^ 120 11D 100 10 20 30 40 50 60 70 go 90 100 110 120 Payload, lb 180 170 140 480 500 ? 350 300 250 200 I-- COO-ft launch Sea Level Launch Payload, lb 40 60 80 100 Burnout wt, lb 326 346 366 386 Zenith Altitude va Payload for Sea-Leval and 4000-ft Launching Altitudes 4000-Pt Launch Sea-Level Launch -7 120 140 160 180 200 220 Payload, lb Zenith Altitude vs Payload --E?i 20 30 40 50 60 70 eo 90 laylead, lb Approved For Release 2002/08/23 : 07-M1515613-00313A000600150042-4 110 110 120 130 Approvec, jeFor Release 2002/08/23 : CIA-RDP634p313A000600150042-4 ATLANTIC RESEARCH CORPORATION ALEXANDRIA,VIRGINIA C ONFIDENTIAL Preliminary Dcaip Characteristics tot: iris RocKet CalulpAt9d I,. Dimensions A. 'Lengths (inches) 1. Oyer-all 2. Components a. Motor b. Nozzle (extension) c. Nose Cone 3. Grain Length Mod 2 Cylindrical 225.3 137.5 6.3 80.0 136.0 Mud 3 Tapered 225.8 137.5 d.3 80.0 136.0 NozIc Head B. Diameters (inches) I. Motor OD 12.128 12.128 12.128 2. Motor ID 12.000 12.000 12.000 3. Insulation OD 11.995 11.995 11.995 4. Insulation.ID 11.600 11.600 13.900 5. Grain OD, inhibited 11.585 11.585 11.385 6. Grain OD, uninhibited 11.500 11.500 21.800 C. Thicknesses (inches) 1. Motor 0.064 0.064 0.064 2., Insulation 0.200 0.200 0.050 3. Inhibitor 0.050 0.050 0.050 D. Volume (cubic feet) L. Nose Cone 4.14 4.14 II.atighps (pounds) A. Motor 1. Motor Case and Head 113.73 113.78 2. Nozzle 29.91 29.91 Ami 3. Insulation 59.69 30.25 B. Components 1. Fin Assembly 34.75 34.75 2. Nose Cone 12.10 12.10 C. Propellant 1. Propellant Grain 867.91 897.35 41,1 2. Inhibitor 10.44 10.58 0. Payload 1. Payload Weight 100,_00 100.00 Total 1228.58 1223.72 Mass Ratio (Motor) 0.1:"1 0.829 Mass Ratio (total) 0.707 0.730 NFIDEFITIAL Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 I. tool Approvad,or Release 2002/08/23: CIA-RDP6341,0613A000600150042-4 mid ATLANTIC RICISiCAPICH ALCKANORIA,VIRGINIA ILL CORPORATION CWIDEN'TIAL .lud Mod 3- Tatered Oneratine, Parameters 1200 46.6 1200 13Tj 45.9 A. Pressure psi. B. &Amiga:lime sec C. Thrust lbs i 160 41W 4510 D. Mass DLscharge Rates lbs/scc 18.7 18.7 20.2 E. ProRellarkt 1. Type Arcite 368 Arcito 368 2. Density lbs/ft3 0.062 0.062 3. Specific Impulse lb-sec/lb 223 4. Burning Rate in/sec 2.92 2.92 3.0C 5. Number of Wires 37 37 4110 F. Nozz4 1. Throat Area in2 2.19 2.1'4 2. Exit Area Ln2 22.06 22.06 3. Expansion Rats 10 10 4. Expansion To psi 14.7 14.7 15.9 IV. Performance A. Maximum Altitude 1. Miles 161.49 188.6 2. Feet 852,667 995,808 B. 2...s.2.11.1xiimpl_AWS.0.9. sac 274.53 289.2 C. Altitude at Burnout ft 113,491 120,663 ant D. Maximum VO.ocity ft/sec 6,791 7,286 E. Initial Acceleration 2.38 2.38 ' F. Final Acceleration 11.45 12.82 C ONF.IDENTI-A L 4-23-58 Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 Approved For Release 2002/Mbket-RDP6W313A000600150042-4 fris Sounding Rocket Outline Dimensions 45" 18.8' SECRET Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 ago ApprovvjeFor Release 2002/08/23 : CIA-RDP6329313A000600150042-4 ATI.ANTIC RESEARCH CORPORATICIN ALEXANDRIA VIRGINIA CONFIDENTIAL Design Characteristics of Arcon Rocket igtilagylpAA 40-lb Payload I. Dimensions (inches) Over-all Components 134 134 A. Lengths 1. 2. it. Motor 99 99 b. Nozzle (Extension) 5 5 c. Nose Cons 30 30 3. Grain Length 96.5 96.5 B. Diameters (inches) 1. Motor OD 6.094 6.094 2. Motor ID 6.000 6.000 3. Insulation OD 5.975 5.975 4. Insulation ID 5.685 5.685 5. Grain OD, inhibited 5.665 5.665 6. Grain OD, uninhibited 5.500 5.500 C. Thicknesses (inches) 1. Motor 0.047 0.047 2. Insulation 0.145 0.145 3. Inhibitor 0.082 0.082 D. Volume (cubic feet) 1. II.Weights Nose Cone (*Measured) 450 450 A. Motor 1. Motor Case (integral head) 30.34* 30.34* 2. Nozzle 8.40* 8.40* 3. Motor Insulation 13.97* 13.97* B. Components 1. Fin Assembly (total) 11.50 11.50 2. Boattail 1.50* 1.50* 3. Nose Cone 1.85* 1.85* C. Propellant 1. Propellant Grain 139.25* 139.25* 2. Inhibitor 6.25* 6.25* D. Payload 1. Payload Weight 10,00 40.00 Total (lbs) 223.06 253.06 Mass Ratio (Motor) 0.702 0.702 Mass Ratio (total) 0.595 0.552 CONFIDENTIAL Approved For Release 2002/08/23: CIA-RDP63-00313A000600150042-4 ApproverofForRelease 2002/08/23 : CIA-RDP6340313A000600150042-4 ATLANTIC RESEARCH ALEXANURIA,VIRGINIA III. CORPORATION CONFIDENTIAL 9.U.S.P....4118..Mala..e..t.9.Ls 10-21LID2122i 40-lb Payload A. Pressure Psi 1200 1200 B. Burning Time sec 33.0 33.0 C. Thrust lbs 945 945 D. Mass Discharge Rates lbs/sec 4.24 4.24 E. Propellant 1. Type Arcite 368 Arcite 308 2. Density lbs/ft3 0.062 0.062 3. Specific Impulse lb-sec/lb 223 223 4. Burning Rate in/sec 2.92 2.92 5. Number of Wires 19 19 F. Nozzle 1. Throat Area in2 0.545 0.545 2. Exit Area in2 5.45 5.45 3, Expansion Ratio 10 10 4. Expansion To psi 14.7 14.7 .1V. Ferformance A. Maximum Altitude 1. Miles 100.1 61.1 . 2. Feet 528,565 322,384 B. Time to Maximum Altitude sec 203.9 162.5 C. Altitude at Burnout ft 71,682 57,900 D. Maximum Velocity ft/sec 5,426 4,194 E. Initial Acceleration g 3.26 2.75 F. Final Acceleration 10.51 7.30 CONFIDENTIAL Approved For Release 2002/08/23: CIA-RDP63-00313A000600150042-4 Approv,w1 For Release 2002/Mt3RElp-RDP630313A000600150042-4 Arcon Sounding Rocket Outline Dimensions ' nominal 102.88" 14-0.9" 5.2" 133.81" SECRET Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 tad soil aro Approve*For Release 2002/f8KREIRDP631t4313A000600150042-4 ATLANTIC RESEARCH CORPORATION ALEXANDRIA,VIRGINIA Preliminary Design Characteristics For Areas Rocket I. Payload A. Total (pounds) 1. Sonde 2. Parachute 3. Nose Cone and Parachute Housing 12 6.5 3.5 2.0 II. Dimensions A. Lengths (inches) 1. Overall 73 2. Components a. Motor 46 b. Nozzle 4 c. Parachute Housing 14 d. Nose Cone 9 3. Grain 44 B. Diameters (inches) 1. Motor OD 4.5 2. Motor ID 4.4 3. Insulation OD 4.4 4. Insulation ID 4.1 5. Grain OD, inhibited 4.1 6. Grain OD, Uninhibited 4.0 7. Parachute ilylar (ft) 24 C. Thicknesses (inehed) 1. Motor Wall 2. Insulation 3. Inhibitor D. Volume (cubic inches) 1. Parachute Container 200 2. Nose Cone 0.05 0.15 0.05 112 Weights (pounds) A. Metal Parts 1. Motor Case -10.0 2. Nozzle, 3.2 B. Insulation 5.6 C. Propellant 35 D. Inhibitor 1.2 E. Fins 1 F. Nose Cone and Payload (incl Parachute) 12 Total 68 SECRET Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4 ApprovsfleFor Release 2002/SEEREIE-RDP63110313A000600150042-4 ATLANTIC RESEARCH CORPORATION ALEXANDRIA,VIRGINIA owl - 2 - Iv. Operating Parameters A. Pressure (psi) Boo B. Burning Time (secs) 25 C. Thrust (lbs) 375 D. Propellant Type rcite 373 E. Nozzle 1. Throat Area (in2) 0.255 Exit Area (in2) 2.55 3. expansion Ratio 10 V. Performance A. Maximum Altitude 1. Miles 38 2. Feet 200,000 B. Time to Max Altitude (secs) 100 C. Altitude at Burnout (ft) 20 F. Typo of Launch Closed Breech SECRET Approved For Release 2002/08/23 : CIA-RDP63-00313A000600150042-4