FIELD TEST AGENDA P-101B, COMMUNICATION SYSTEM, INFRARED

.1 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 DOCUMENT NO. NFIDENT1AL :NO 01-1;',NC.177!! Cli.SS. 0 0 DECLASSIFIED CLASS. CHANCED TO: TS NEXT REVIEW DATE: 'MTH: 70 DATE -EVIEWER? 010956 s 041,ttit,0 2 DeceMber 17)4 FIELD TEST AGENDA P4013? Communication System, Infrared I. Test Objectives A. Range Tests The primary Objective of the tests is to determine the performance of the equipment as a function of the range and to fix the approximate maximum ACW ranges for day and night operations. D. General Eojijent Performance Teats The secondarydbjective of the test is to determine the general equipment performance under typical operating conditions. Particular note will be made of these points: 1. Mechanical Features 4. APparent quattyof mechanical construction overall b. Waterproofing of equipment Closed and open c. Apparent resistance to shock and vibration d. Ruggedness and stability of tripod table e. Yoke mount performance and limitations (1) Maximum angular swing of equipment in owinin:th and elevation Presence of wobble, backlash, stickiness, etc. in the yoke mounting (2) (3) Accuracy of horizontal and vertical circles and the ease with which they may be read (4) Mechanical sweep mechanism performance f. Mechanical construction of the optical systems. (1) Quality of glass Objective mirror mounting (2) Ruggedness and stability of mount for the optical sight (3) Ruggedness and reliability of the bellows system Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 _ I I . Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 isitieTN ,n7 r. 11 I r LjeL,'J (4) StabiLity of the galvanometer system of Modulation (5) Protection for and mounting of the glass IR filter 2. Optical Feature? a. I. R. viewer Sensitivity (night and day ranges) Field of view Quality of reticle MI ease of sighting Optical quality of image Alignment of viewer with main optical system ' ity /(3) Al st sigh th main Electrical Features a. Amplifier noise level b. Signal intelligibility 0. Possibilities of voice recognition 4. Battery performance tional Feasibilit Tests en reFe test is to determine the feasibility of using the equipment under various operational conditions. Particular attention will be paid to the following items: 1. The ease of opening the Gear and assembling It, e.g., the time required to put the equipment into operation 2. The value of the controls provided and the ease with which they may be used 3. The suitability of the two foot high tripod for operations in varying terrain CONF1 ENT1AL Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5  11 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 SRC . CONFIDENTIAL D. 4. The suitability of the angular swinge in azimuth and elevation, relative to the tripod Uwe, made possible by the present equipment design 5. The operational procedures used and the time reqpired to accomplish the search-find operation using each procedure Cctplete Plx:rtotir ? ? c Co....terk of the Equiment in tion e fourth .? jaCtive Ue?tiir is o obtaiTa cturea of the equipmerct'in operation. It is felt that photographs of the terminal areas, both close ups and telescopic view's frau the other terminal, would be of interest to readers of a teat report, since such photographs +would give an excellent idea of field conditions, etc. Test Procedures A. Selection of Field Test Locations 1. Using the 1:62,500 1.1308 maps of the area, select e or 3 locations for line of-sight ranges of 1,2,4,6,8 sdlea approximately 2. Make elevation plots of each of these ranges to check for line-of-sitt.t6 j 3. Select, obab3,41 nj.ght and day l: irks from the map to facial te the location Of the terminal stations Note the respective bearings of each station from the other in azimuth iwilk-eimmiliMiee as obtained from the map. Also note the bearings of the landmarks. B. Field Test Procedures 1. Form two teams of two men each; one team for e station of the rangy, in question . eqa aA%-t-c - ---r1A-7!--V uP-signal plans for the range* selected in IIA including: a. Map overlay of both stotions b. Map 6. / ," ' 2 a #det N -414,a4NOtileaaiggete de 06--L,.-10 62,-,4-4fla awl-4 4. ,Bearing of each station from the other ) e. List of day and night landmarks and. their bearinge)et, a-4-2-1- / .0) per4IJ,a-4.4 f. Time to initiate search-find. procedure d.Antlelt, g? Time to discontinue search-find procedure failing contact 3 - CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5  JJL ,1_1? Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ,SEORETtONh LENTiAt_. Select a mile range from those of ti.A a. Send. one team to each station by daylig,at b. On this first visit to each station by de/light (1) Locate an operating area and set up gear. Record time required (2) (3) Locate position of other station by landmarks, compass bearing Using optical eight and mechanical sweep execute aearch..find procedure until contact is established. Record time required. Note the horizontal and vertical circle readings for various landmarks (5) Take photos of (a) The gear in operation and its surroundings (b) The other station with 50 and 1400 mm lenses (6) Review the General Equipment Performance Tests an& make pertinent comments (7) Recordlmeather condition*, visibility, temperature, etc. )3) 41,4) On the second visit to each station by night (I) (2) (3) Set up the gear in the previously located area. Record the time required Locate position of other station from bearings of landmarks previously noted Using infrared viewer and mechanical sweep execute sweep-find procedure. Establish contact. Record time required (4) Review General Equipment Performance Tests and. make pertinent comments (5) Record weather conditions aiyia ( -47--614) Report the procedure ottlined!under 3, 3 for other ranges, shorter or longer as required under different terrain conditions 5. Repeat B,3,c for a pzieviously =surveyed site CONFIDr:NTIAL Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ? .., I "Li__ I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 XIX. Test Results .6 EGRET Ai:JAJ -11 A. Alist of the ranges obt&tnd with the signal quality and weather conditions noted R. Descriptions of the operational situations involved, the search-find methods used for each situation, and the time required to establigh contact in each case C. A description of the overall equipment performance with suggested improvements 25X1 Distribution: Orig. - P401B. 3 - AOT V 2. - Chr ono .ASTtbb TBS/APD 5 CONF Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28 : CIA-RDP78-03300A001600020097-5 I I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 "., 07re- hilasi,)-tie)vy Amaii tocht) 4,7,414/ Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28 : CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 , = - Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ? Declassified in 0a-rt - Sanitized Copy 'Approved for Release 2011/12/28: CIA-RDP78-03300A06160062-009715 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Friend or foe? In pitch blackness the snooper. cope will tell whether stray noises ore cpused by a late-returning husband or a midnight prowler. make this SNOOPERSCOPE and see in total darkness By Harold Polies PICTURED above is only one of the pos- sible applications of the modified war- time sniperscope. This unit, called a snooperscope, is an enlarged version of the instrument used by GI riflemen to enable accurate fire power in total darkness. When the infrared light source is turned on, the user, by employing the special eyepiece, can see in the area covered by the light, although to the naked eye total darkness still prevails. A number of more practical applications have been developed with the snooperscope because of its ability to peer through any opaque material that passes infrared rays. Crime detection laboratories are now using similar equipment for reading through cer- tain types of material. Since the infrared reflection of pigments in paints and inks is different from that of white light, it is pos- sible to detect forged paintings and checks by the way the colors appear. You can demonstrate this by writing a message with India ink and then painting over it with a coat of ordinary fountain pen ink. Your eye will only see the blackened spot but the snooperscope will peer through the top Reprinted from llerhanil Illustrated llagazinc Copyight 19-31, Faucet; Publications, Is. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 1 111'1111 IP III '111 11 Id Mill I U Lii r1 rJ L LIL, LEL L, Li I LI I 11.11 I. II L Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified GRAPHITE COATING METAL RING 1' FOCAL LENGTH MAGNIFIER LENS (TRIPOD TYPE) PAINT WALLS FLAT BLACK NEAR INFRA RED ALTER IMAGE CONVERTER TUBE 31/2* FOCAL LENGTH EYEPIECE (OPTIONAL) 3 1/24 HOLE CUT IN CUP BOTTOM FOR MAGNIFIER LENS (SLOTS CLEAR TRIPOD STUBS) PLASTIC HANDLE BAR GRIP 1/8' PLASTIC ? DISK CUPS ARRANGEMENT OF UNITS INTO PLASTIC DRINKING CUP ONTO RIM layer of ink and reveal the writing just as ness. A converter tube has been used with clearly as if there were no top coating. This a microscope to study bacteriological and type of inspection can be made photo- botanical specimens under infrared rays. graphically if infrared film is used in the Certain large molecules may now be ex- camera. The electronic method hermits amined in a different way, since they be- instantaneous examination which often is come transparent under infrared light. a 'great convenience. Military uses are obvious. The sniper- As you might have thought, there are scope has already been mentioned. The several photographic applications. Using Germans used infrared-equipped tanks this device, you can take photographs with and trucks for driving during blackouts. no visible light source. (For instructions Under these conditions they could travel on this type of work, see Shoot 'Em In The almost as fast as during the day. Cars Dark, January, 1951, MI, pgs. 148-149.) equipped with a snooperscope would have One of the handiest uses is using the snoop- the advantage during fog. Certain types of erscope as a darkroom viewer. Difficult op- fog are transparent to infrared (depend- erations that have to be carried out in total ing on the particle sizes) and during such darkness can now be viewed clearly weather increased safety of the road could throughout the process. If you run into be obtained. The experimenter is cautioned trouble loading film tanks you will appre- about building a unit for this purpose, as ciate a viewer when the film becomes very good lenses are required as well as snarled. A test for fogging should be made powerful headlights. Such specialized con- before the viewer is used. Within the next struction is likely to prove difficult and few years every modern darkroom may be driving with makeshift equipment would equipped with infrared viewers, be dangerous. In scientific laboratories a modified unit In the actual construction of your snoop- such as this is used to study the behaviour erscope, your 13, ,e would be one of of small nocturnal animals in total dark- several British in. , which are available in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 11111'1.1 11111111'1 11111 1 11111 1111111111111 1 1111 1 1 ? Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Glass type Infrared filter To 115 v AC-DC 300-watt 115 volt outdoor type floodlight Plywood case UNIT FOR SUPPLYING LIGHT SOURCE on the surplus market. Two of these are type CRI 143 and CV 147. For op,eration at the highest voltages, the tubes should be carefully selected. Other electronic parts required are a 4,000 to 6,000-volt low cur- rent power supply (less than one milliam- pere), a light source and two filters. For indoor operation a 4,000 to 5,000 volt neon sign transformer operates the tube satisfactorily. Two 1-megohm resistors are used, one in series with each lead, to limit the current. Rectification is not necessary unless the objects are in motion (objects in motion cause a stroboscopic effect when AC is employed. For portable use either indoors or out- doors a handy-sized power supply may be constructedthat operates off three standard flashlight cells. For continuous operation leave the power supply on as long as re- quired. Very long battery life can be ob- tained by switching on the power supply only momentarily to charge the condenser. The condenser will then store this energy and continue to operate the tube for some ? time after the unit is turned off. Place a small piece of rubber tubing over toggle switch handle to help eliminate charge pickup. The high voltage is supplied by a model airplane ignition transformer with a vi- brator to interrupt the primary current. These transformers are available on the market with the vibrator already built in. Only two wires need be attached for op- eration. You can make up your own vi- brator coil arrangement by using the parts . of an old buzzer or bell. Some types of buz- zers can simply be connected in series with the primary of the transformer. Try yours - . _ Elements of the light source. Bulb employed Is a standard 100 to 300-watt lamp. Although this case is of metal, you may use plywood if so desired. to see if this is possible (11/2 volt buzzers). Caution: Avoid contact; these voltages are high and while not dangerous, can give you a rather uncomfortable shock. Construction of the snooperscope: The image converter tube is mounted in a plas- tic drinking cup 31/2 in. high by 21/2 in. in diameter. The optical system required de- pends upon your intended use. We used a small tripod type magnifier lens of 10 power (1 in. focal length) for the front lens and objects from three inches to one and a half feet can be focused. There is no reason why a greater range cannot be had with this lens by moving it closer or farther away from the tube. After selecting the lens system mount it in a hole cut into the bottom of the cup. A jeweler's saw or coping saw is ideal for cut- ting the hole. Paint the inside of the cup with black paint. Black airplane dope works fine. No light other than that from the lens must be permitted to hit the tube. Place an infrared filter between tube and lens to reduce effects of stray white light. The image converter tube is inserted with the graphite side toward the front lens and the metal ring toward the mouth of the cup. A thin flexible lead from the metal ring connects to the positive side of the power supply. Some tubes were manu- factured without this lead, in which case a piece of spring metal pressed against the metal ring will work just as well. The front end of the tube has a graphite ring around it. This is the end where the infrared image is to be focused. The graphite coating is the cathode or negative lead. Connect this lead to the B minus side of the power supply. A piece of spring Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Hill 11" l" Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Top view of simplified power supply for portable The snooperscope itself. For indoor use a small use. Cells are the ordinary flashlight type. The en- neon sign transformer (right) may be used to tire unit is mounted on a 3/4-in, plywood baseboard, power the infrared tube within the plastic cup. Model airplane Ignition transformer with vibrator To graphite coated ring on tube High tension lead 1/2 megohm resistor '...44414114141/411110:bifj ? , Condenser .1 mfd 600 v For 1X2A tube, use 'pins 2 & 6 For 1B3GT/8016 tube, use 2 & 7 Three -"D" 1.5 volt flashlight tells PORTABLE POWER SUPPLY UNITS ON WOOD PANEL Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 .I _ Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 brass or even the flat sheet metal carefully removed from a tin can should be formed with the fingers so it fits snugly around the cathode terminal. The rear viewing lens is optional as it is only required if yOu wish to view the images closely with the eye. It should have about three power and a focal length between 21/2 and 4 in. This lens is mounted and cemented to a piece of plastic or wood. The material should be opaque and have good insulating qualities. The handle is a plastic bicycle han- dlebar grip which is cemented over a hole drilled into the side of the 'drinking cup for the high voltage leads. The lead wire can be the plastic type of zip cora, over which is placed plastic insulating tubing. Light source: The main limit to the view- ing distance is the power and type of light source. Greater intensity means greater dis- tance. For the direct viewing of glowing objects this imposes little difficulty. Such ob- jects as the moon and extra bright stars may be viewed directly. A small flashlight with a plastic filter may be detected at quite a dis- tance. Reflected light from objects requires the use of heat lamps, photofloods or standard 100 to 300-watt lamps to illuminate them. Of course these lights are filtered so that no visible light is seen. The light source shown on page 100 consists of a 300 watt sealed beam outdoor type floodlight (115 volt), a glass type infrared filter and a 10x10 in. recessed lighting box. Outdoor applications involving greater distances require a bulb with a sharply fo- cused reflector. Gold-plated reflectors give very good results. The sniperscope used a 30 watt, 6 volt bulb similar to the type used in auto headlights. This was operated on a small rechargeable storage battery. Good substi- tutes are auto spotlights of the sealed beam type such as Westinghouse type 4535 or the General Electric 4524. Standard type flash- lights with small dry cells will not provide ample infrared for viewing by reflection. Never point your snooperscope at extremely bright light sources like the sun. Damage to the tube may result. Infrared filters: Experimental filters can be made by sandwiching several layers of dark red and blue cellophane between two sheets of clear plastic. Both plastic and glass types are available from photographic and scientific supply houses. The latter type is to be used whenever heat is involved. Infrared filters cut out all or most of the visible radiation and allow the heat rays to pass through unob- structed. Since a tungsten lamp produces much more infrared than it does visible light, the action of a filter reduces its strength only slightly, while to our eyes it now becomes total black. Don't forget that it is possible to overheat even glass filters, so light sources shotild not be left on longer than necessary. ? SNOOPERSCOPE PARTS LIST Light Source: , Sealed beam light or standard 100 'to 300- watt lamp and reflector Metal housing for above items Infrared filter Snooperscope (Eyepiece unit): Image converter tube Plastic drinking cup Plastic handlebar grip ? Jeweler's eye loupe (approximately 2 to 4-in. focal length) Tripod magnifier, approximately 10x, I-in, focal length Five ft. plastic-insulated cord (do not use cord with rubber or cloth insulation) Near infrared filter Black paint or airplane dope Power Supply, AC: Neon sign transformer, 4 to 5 kilovolts at under 10 mills current rating Two 1/2-megohm resistors (may be as high as 5 meg.) Power Supply, Portable: Three flashlight cells Model airplane ignition coil Small buzzer .005 mfd. condenser, 6,000 volts .1 mfd. condenser, 600 volts (if not built into vibrator coil) Two 1/2-megohm resistors lx2A or IB3GT/8016 tube Socket for above tube Wooden baseboard D.P.S.T. switch Grid cap Two fahnestock clips Note: These parts may be obtained from the P. ecise Measurements Co., 942 Kings Highway, Brooklyn 23, N. Y. A Beautiful AEROLUX CHEER. LITES Flowers and Emblems inside of bulbs glow in natural colors. Solid brass Maple Leaf lamp holder and bulb? mos Flowers or Merry Xmas bulbs (A & 13)? 1.75 Crucifix bulb? 1.00 FLUORESCENT PIGMENTS Brightest glowing. concentrated phosphors, available in many colors. Red, White, Blue, Green, Yellow and Orange. Mix with clear lacquer for painting. SAMPLE SIZE (specify color) 35c each COMPLETE SAMPLE KIT (6 colors). 81.75 ea. One Ounce Bottles (apecify color) 50c each Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 11111 HILLL 14 1. 111-1- .11111 11 1 Ell. ._11 L I a Ll [liii ill, Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 PRECISE MEASUREMENTS COMPANY - SNOOPERSCOPE SUPPLIES ?We have a limited quantity of the following supplies for the construction of snooperscope out- fits. All material is in new condition and carries our 11 warranty to be free of defects in material or work- manship. SNOOPERSCOPE TUBE SEE IN THE DARK SUPPLY LIMITED? These are government released British snooperscope tubes which employ the spe- cial simplified design, makin? construction of experimental models possible with simple hand tools. Highly sen- sitive, they provide a bright clear image of invisible infra red rays, Also useful as infra red (invisible) photocells. With complete hookup instructions. Special Price $14.95. ENGRAVERS GLASS?Has a ground lens for clear sharp images. Focal length three inches. Perfect as either a front or rear view lens. Plastic housing prevents elec- tric shock. Price 1.25 SNOOPERSCOPE BOOK Shows in detail Army and Navy snooperscopes, sniperscopes and infra red telescopes. One of the few books of its kind. Circuit hookups for practical instruments are given. Special Price $1.50. NEAR INFRA RED FILTER?An efficient filter that fits directly on the front of the image converter tube. High quality glass type with metal mounting clasp. Clasp also serves as the graphite contactor (?lead). Your Price LW IGNITION COIL?This miniature high volt. age coil provides high output for snooper- scope operation. Has built in condenser for extra power. Special $2.25 PLASTIC FILTERS Infra red plastic filers are also available at 15? each for small test square and 750 each for 6 x 6 inch squares. Permits passage of heat rays but appears black to visible light. Buy several at this price while the supply lasts. FILTERS?Infra red filter glass. Manufac- tured by a famous glass house to exacting specifications. Transmitts over 80% of the infra red rays but appears as a total black for visible light. 3 x 3 inch square Price $2.55 6 x 6 inch square Price $4.00 PA" Round $3.75 942 Kings Highway, Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I Li1 _ Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ADDITIONAL INFRA RED SNOOPERSCOPE SUPPLIES The following additional supplies were made available due to many requests for materials with which to construct experimental infra red instruments and snooperscopes. Sales of any item is limited to stock now on hand. New materials arriving dolly. POWER SUPPLY KIT?Provides the proper voltages for image converter tubes. Operates off three ordinary flashlight cells. Completely portable. Every part including case, rectifier tube and batteries is supplied. Your price $14.93 LENSES?These lenses are of top quality materials and intended for use where the best possible results are required. We make these lenses available only to our customers which have purchased our snooperscope tubes and send us there written assurance that they have been success- ful with the circuits and the simple lenses and now feel prepared to construct the finer models. SNOOPERSCOPE LENS ? Original Navy Snooperscope lens. Schmidt optical system type Government cost $134.00. Very fast speed F 1.0 Our Price $12.50 Mounted Optical Lens. High quality lens of fast speed. Excellent for image tubes. Priced at a fraction of their original cost. Price $8.50 HOW TO ORDER IMPORTANT NOTICE Sales are subject to the following conditions; all prices in this catalogup is subject to change without notice. Most material is shipped postpaid unless otherwise noted. Test instruments are not postpaid and postage fees should be included with your order. We will insure all material unless instructed other- wise. In the event of damage in transit, write us immediately giving details o f the damage and insurance numbers on package. If for any reason you wish to return material write us first giving all detai's and we will send you ship ping instructions. POSITIVELY NO MATERIAL ACCEPTED FOR RETURN UNTIL WE HAVE BEEN NOTIFIED AND YOU HAVE OUR SHIPPING INSTRUCTIONS. Merchandise made to customers own specifications cannot be returned. Foreign orders should add 10% to cover costs of additional packing, postage and con sular expenses. No C.O.D. orders accepted unless accompanied by a deposit 0 25%, balance wil be shipped C.O.D. This catalogue covers only a few of the items that we carry. We carry hundreds of items not listed on these pages write us on your requirements. Prompt efficient service is rendered on all orders regard'ess of size. Our lab oratory is engaged in the construction of scientific instruments of every de- scription. We are always very happy to send our free quotations on equipm On? built to order. PRECISE MEASUREMENTS COMPANY 942 Kings Highway, Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I. It I 1?lil I I I 1 I I 11 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 GE OZONE. LAMP ent1,11,114.5, 7;1 BLACKLIGHT LAMP Special Argon filled bulb pro- vides a good source of violet and ultraviolet light for blackout experiments and fluorescent materials. Very convenient as It screws into any standard lamp socket. Clearance Price 45e 10 for $4.00 Generates short ultraviolet radiation (1849A & 2537A) which produces ozone by converting the oxygen of the air (02) into ozone (CP). Useful for fluores- cent & phosphorescent ma- terials. Uses only '4 watts of power. Lamp supplied with socket and instructions. Your Price $1.95 FLUORESCENT PIGMENTS Brightest glowing, concentrated phosphors, available in many colors. Red, White, Blue, Green, Yellow and Orange. Mix with clear lacquer for painting. SAMPLE SIZE (specify color) 35e each COMPLETE SAMPLE KIT (6 colors) $1.75 ea. One Ounce Bottles (specify color) 50c each AMAZING BLACK LIGHTS Powerful 250 watt Ultra Violet Bulb is very convenient to use as it screws into any standard lamp socket. Provides black light which causes many things to glow. Excellent for experimenting with fluorescent and phosphorescent pigments. Lamp is designed for intermittent duty only. Price $1.95 PHOSPHORESCENT PIGMENTS. Expose these pigments to sunlight or ultra violet light or ordinary light bulbs. Pigments wil then remain glowing for sometime afterward in total darkness. Comes in powder form mix with clear lacquer for painting. Available in three colors: yellow-orange, green and blue. t One ounce bottle 60? 1/2 pound bottle $2.75 SAMPLE KIT. Consists of one of each of the above cooks (three bottles). Price 98 cents. SPECIAL PHOSPHORS ULTRA VIOLET Energize this phosphor with short wave ultra violet light (approx. 2500 A) and it will convert it to the near ultra violet of approx. 4000 A. This phosphor when used with many types of black lights will increase the ultra violet out- put considerably. Use as a coating on the out- side of photocells to change their response. Sample 50( 1 oz. Bottle $1 $12.50 lb. SHORT WAVE Responds to wavelength of 2500 A or shorter. Will detect alpha particles, electron beams, etc. Lights up a bright green. Sample 50? $12.50 lb. 1 oz. Bottle $1 TWO COLOR The beautiful colors that these concentrated phosphors will glow depend upon the wave- length. Different types of blacklights will make it change color. Red and green or yellow and green are available. Sample 500 $12.50 lb. 1 oz. Bottle $1 INFRA RED EMITTING This unusual material has the property of emit- ting far red and infra red radiation when ex- cited with ultra violet light. Useful as infra red light sources, experimental fluorescent lights, etc. Price $4 oz. INFRA RED RESPONSIVE A specially prepared material with rare earth activators. Charge with ultra violet light or alpha particles, phosphor then stores this en- ergy and releases it in the form of light when infra red radiation is present. Also useful as temperature indicators. Price $4 oz. ULTRA VIOLET FILTERS Glass type. Filters out most of the visible light while allowing free passage of ultra violet. Very handy for experimenting with fluorescent phosphors. s 3 x 3 inch square Price $2.55 6 x 6 inch square Price $4.00 PRECISE MEASUREMENTS COMPANY 942 Kings Highway, Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 _I .. it I _ Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 TRIPOD MAGNIFIER ULTRA VIOLET GENERATOR Lenses are ground for better clearity. Has high magnification power and is adjustable by means of a screw thread. Very popular item with ex- perimenters, colleges and research labs. Your Price $1.75 MICRO CIRCLE CUTTER FOR METAL ? WOOD ? PLASTICS ? Micrometer type size control ? Extra heavy duty beam ? Special beam locking mechanism At all Dealers Model Type Size Price 1 Round shank 4 inch $5.00 1 Square shank 4 inch 5.00 5 Round shank 6 inch 7.50 PRECISE COMPANY, 942 Kings Highway BROOKLYN 23, NEW YORK VAN DE GRAAF MACHINE Produces voltages between 10 KV and 100 KV. Well designed for long life and efficient opera- tion. Under favorable weather conditions sparks up to three inches can be obtained. Many in- teresting high voltage experiments can be per- formed with this miniature generator. Price $15.00 12537 Angstrom units 1 Consists of a miniature mercury vapor lamp in beautiful plastic housing. Lamp constructed of special glasses for the efficient production of ultra violet radiation. Built in ballasts for long life and good operation. Wavelength changer filter instantly changes the output wavelengths Your Price $9.95 WAVELENGTH CHANGER FILTERS available in blue, green, yellow, orange and red. Price $1 each INFRA RED WAVELENGTH CHANGER FILTERS Converts your ultra violet generator to an infra red generator. Price $1.50 each NIGHT VISION GOGGLES.?These gogglee were used by the Army for nighttime vision purposes. All are new and in indivi- dual cloth case. Price $1.00 esch INFRARED FILM. A fortunate purchase of infrared film allows us to offer this material at an almost unbelievable low price. Film is surplus aerial, cameral stock which is outdated. We have tested this film and find that good results can still be obtained. Speed rating is 50 with red filter. Comes in vacuum sealed can in rolls 51/2 inches wide by 26 feet long. Your Price $1.25 CESIUM VAPOR LAMPS These lamps produce nearly a pure output of infra red light of 8521 and 8943 Angstrom units. They are the most efficient source of infra red at these wavelengths and are about 700% more efficient than the Tung- stem filament lamp. These lamps may be modulated up to 10,000 cycles with voice or code. Only a very limited quantity of these lamps are available as they were used in Navy projects. Lamps are rated at 90 Watts at 5.5 amperes. Pries $30.00 sash. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I ,.LIt_11 Hit! I I 111.1 ? 11111 11,? 1 1111. LL I1_L111 L I LIJ .1,141 L LLI J 1 II 1 11.11. bait Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 No. 2425 READING DIFFRACTION SPECTROSCOPE. This spectroscope is suitable for medical research, analytical work and general purposes in physical laboratories. The dispersion is 34? and the slit is provided with an adjustment for varying the width. A graduated drum by which the spectrum can be moved, across the field, used in conjunction with an indicator enables readings to be taken. This drum is divided intolOOdivisions, which are arbitrary, but which can be calibrated if desired by the user. An adjustment is fitted for accurately focussing the spectrum. A table stand to carry the spectroscope can be supplied. Provision is afforded for the attachment of a test tube holder and also a cylindrical lens attachment. This latter is a very useful accessory, especially when working with a small or weak source of light, as it -concentrates an image of the light source on the slit. No. 2425. Reading spectroscope, in case ? $69.50 Nos. 2458 and 2459 PRISM SPECTROSCOPES. For certain purposes the prismatic type of spectrosco' pe is advantageous, as it passes very much more light than the diffraction type. The dispersion, however, is less, and as explained in the opening description (page 1), gives a smaller relative dispersion at the red end of the spectrum compared with that at the blue end. This model employs a train of five prisms giving a dispersion of 100. An adjustment is provided to the slit for varying the width ; there is also an adjustment for accurately focussing the spectrum. The instrument can he attached to a table stand, and provision is made for the attachment of a test tube holder, etc. No. 2459 has the addition of a comparison prism. This enables the spectra from two sources to be examined simultaneously. No. 2458. Prism spectroscope, in case 49.50 No. 2459. Prism spectroscope, in case 52.95 PRECISE MEASUREMENTS COMPANY Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 il I III I' 1 I 11111:1 11.11M ihiiIIIIIHIHJLLI Jill L, I I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Nos. 2522 and 2523 WAVELENGTH PRISM SPECTROSCOPES. For taking direct readings in wavelengths, where extreme accuracy is not required, this instrument will be found extremely satisfactory. The dispersion given is 10'. The scale giving readings in wavelengths is viewed in the same field as the spectrum, each division of the scale 'representing 100 A. The slit is adjustable and the necessary focussing adjustments are provided. There is also an adjustment to the scale so that it can be set accurately in relation to the spectrum. Provision for attaching to a table stand is provided and such accessories as test tube holder and cylindrical lens attachment can be employed. No. 2523 has the addition of a comparison prism. This enables the spectrum being examined to be compared with a standard ? or other source. No. 2522. Prism spectroscope, in case $$9849..5500 No. 2523. Prism spectroscope, in case ACCESSORIES TABLE STAND. This stand is strongly made, the spread of the feet is arranged to ensure that the stand is rigid. The fitting carrying the spectroscope has adjustments for. raising and lowering, also for tilting, both adjustments being provided with clamps. It is suitable for spectroscopes Nos. 2447, 2449, 2425, 2426, 3500, 2458, 2459, 2522, 2523. 2435 and 2438. No. 2437. Table stand . . ? . ? ? ? ? $995 CYLINDRICAL LENS ATTACHMENT. When small or weak sources of light are being examined, this attachment is found extremely II useful, as it produces an extended image of the light source on the slit. It can be used in con- junction with Nos. 2447, 2449, 2425, 2426, 3500, 2458, 2459, 2522 and 2523. No. 2496. Cylindrical lens attachment .. CYLINDRICAL LENS ATTACHMENT. This attachment is on the same principle as No. 2496, but is made in quartz so that it can be used in conjunction with spectroscopes Nos. 2435 and 2438. No. 2436. Cylindrical lens attachment ? ? ? ? ? ? $1 095 TEST TUBE HOLDER. This holder is a secure method of supporting a fest tube and enables a number_ of tubes to be easily and quickly changed. It is attached to the spectroscope 4-4;4ii 4 LI1 by two clamping screws and can be used on models Nos. 2447, 2449, 2425, 2426, 2458, 2459, 2522 and 2523. No. 2697. Test tube holder .. ? . $2.95 $950 PRECISE MEASUREMENTS COMPANY Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ? .1 1, it. I 111... 1..1,1 I I.. 1 I ? All Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Nos. 2435 and 2438 ULTRA VIOLET SPECTROSCOPES. Declassified This is a compact spectroscope for the examination of the ultra violet spectrum Its general design can be seen by the illustration. It has an accurately made slit, fixed or adjustable, through which the light passes on to a quartz prism, forming a spectrum upon a. fluorescent screen. The spectrum thus formed is examined by an eyepiece, giving a magnified image. The eyepiece is provided with a focussing motion and an eye cup to exclude extraneous light. Beside the spectrum in the field of view is an illuminated scale, divided in Angstrom units, so that the wavelength of any portion of the spectrum under observation can be deter- mined. The scale appears with illuminated lines and figures upon a black background, the illumination being obtained through a window in the instrument by means of the visible light in the light source under examination, so that no add- itional source of light for illuminating the scale is necessary. The spectrum included in the field of view is from 2,000 A. to 4,500 A., which includes a small portion of the visible light. The instrument can be conveniently used in the hand, table stand can be supplied if i equired This spectroscope has been designed with a view to giving a particularly brilliant spectrum, thus rendering it easily used in daylight and with the same ease as a spectroscope for visual light. It is, therefore, specially useful for rapid determinations in electromedical and similar establishments and for industrial workshop use, when a more complicated apparatus is inconvenient to use. When a small source of light is being examined, the brilliancy of the spectrum can be increased by using a cylindrical lens attachment (page 12), thus making it unnecessary to hold the spectroscope close to the source of light. No. 2435. ultra violet spectroscope, in case .. 109.50 No, 2438. ultra violet spectroscope with adjustable slit; in case . . 114.50 PRECISE MEASUREMENTS COMPANY Brooklyn 23, New York in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 20 25 30 35 46 45 Spark spectrum of zinc and cadmium as seen in eyepiece of spectroscope. _ _ I _ JLL. 11 I _ Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 What's Ahead? by LLOYD E. VARDEN With the coming of high-speed pan films, and later, color materials for home processing, photographers were compelled to struggle through most of their darkroom chores in absolute darkness. The once useful dark-green safelight provided enough light?after the eye became adapted?to give one confidence in carrying out the most intricate of darkroom manipulations with slower or less color sensitive ma- terials. Today, though, when a high- speed pan or color film jams, for ex- ample, while loading it into a develop- ing reel, about all that can be done is to start from scratch and hope for the best. To turn on a safelight is inviting disaster. Seeing in the dark During the war, reports leaked out that soldiers had been given devices enabling accurate rifle fire in complete darkness. The secrecy was not entire- ly warranted, because as early as 1934 disclosures had been made in the sci- entific literature on converting invisi- ble infrared radiation to visible light. The now well-known snooper scope and sniperscope employed this princi- ple. An infrared searchlight, which the enemy could not see, "illuminated" the field of observation. The scope con- tained a lens system that projected an infrared image of the scene onto the photo-cathode of an electrostatic im- age tube. Electrons emitted from the infrared sensitive surface were then focused by the tube onto a small fluorescent screen, producing a visible image that was observed through a magnifying eyepiece. The principle in- volved is made clearer in Figure 1. It is obvious that an instrument of such novelty should find peace-time applications. Immediately after the war, for example, Pavelle Color Inc. purchased a surplus military infrared Fig. 1. above: Invisible radiation is projected by infrared searchlight (1) onto scene (2). reflected to lens (3) and onto infrared sensitive photo-cathode (4). Electron beam is focused electrostatically by image tube (5) which gets its power from (6). Fluorescent screen (7) shows image, seen through viewing lens (8) by human eye (9). telescope in the hope that it could be adapted for "seeing" in the pitch black darkness of color processing dark- rooms. The instrument was relatively small, and was easily refocused for close-up viewing. It operated from an ordinary 115 volt electric line, and pro- vided an amazingly brilliant image when the area under observation was illuminated by a 150 watt tungsten fila- ment lamp, housed to emit radiation only through a Wratten No. 87 infra- red filter. Sufficiently fine detail could be observed to carry out nearly any darkroom operation. (Written instruc- tions on a sheet of paper could be read with ease.) It appeared as though the difficulties that arise from working in complete darkness would soon be a thing of the past. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 II III 1 I 1 111_1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28 : CIA-RDP78-03300A001600020097-5 Fig. 2, below: Infrared source (1) projects beam through infrared filter (2) onto sheet of film to be observed (3). Rays are reflected through infrared filter (4). lens (5). and onto phosphor-coated surface of rotating cylinder (6) which has previously been exposed to rays from ultra-violet source (7) in reflector (8). Image thus be- comes visible to human eye (9). This is principle of Tuttle's device. Fundamental problems involved The application of the infrared image tube for general photographic purposes is restricted by at least two fundamental problems. First, many photographic emulsions, after expos- ure in the camera, exhibit an image reversal when exposed to infrared radiation. This is known as the Her- schel effect. The first of these problems could no doubt be overcome by limiting the viewing times in the darkroom to a minimum, or by reducing in other ways the amount of infrared radiation reaching the film. A different approach Another approach to seeing in the dark was recently described by C. M. Tuttle of the Eastman Kodak Co. in U. S. Patent 2,521,953. Tuttle makes use of an infrared source and phos- phorescent substances, but the visible image is formed in a manner different from the image tube. He takes advan- tage of the fact that infrared radiation can be employed to stimulate the fluorescence of a previously excited phosphor, i.e., one that has been ex- posed to ultraviolet radiation, for ex- ample, so that the brightness of the fluorescence increases with the amount of infrared the phosphor receives. Or, by proper choice of the phosphor, the infrared can be used to quench, or "put out" the fluorescence previously pro- duced by an ultraviolet source. Now, by means of a rotating phosphor- coated surface enclosed in a box with an ultraviolet source, and with a lens on one side and a viewing hole on the opposite side, it is possible to illumi- nate a light sensitive material with in- frared and view its visible fluorescent image. One such device described by Tuttle for inspecting film during manufacture is shown in Figure 2. The rotating phosphor-coated surface passes the ultraviolet source where it is excited. It then passes the infrared image formed by the lens where, de- pending upon the phosphor used, the fluorescence of the rotating surface is stimulated or quenched according to the amount of infrared radiation strik- ing any particular point. The image produced remains on the surface long enough to be viewed through the peep- hole before reaching the ultraviolet source again. With one type of phos- phor a negative image is produced, and with the other, a positive image. A de- vice based on this principle could be made fairly compact and at much less cost than one incorporating an elec- tronic image tube. Whichever ap- proach is taken, there is no reason why photographers cannot expect to "see in the dark" in the darkroom of the future.?THE END. Reprinted from MODERN PHOTOGRAPHY Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I1 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 F" ARMY PLANS TO BUY 6,918 `SNIPERSCOPES' WASHINGTON, ?The night eyes" of the rifleman, the electronic "sniperscope" that is ?credited with causing 30 per cent , of all enemy casualties in the Oki- nawa campaign, is being made a f standard item of Army equipment. t. Army sources disclosed today I that'the field forces were so im- rresded with the efficacy of the auxiliary weapon that enables the infantryman to "see" the enemy / through darkness that units in all the .krmy's ten divisions would be equipped with the device. 1 Included in the Army's budget requests now before Congress is an $8,654,418 item for the purchase of 6,918 "sniperscopes" at a cost of $1,251 each. How many of the de- vices are already in use is con- sidered secret information. The "sniperscope" consists of an electronic telescope that is mount- ed on the standard Army .30-cali- bre carbine. Wiring runs from a portable power pack carried in a Iharnessed knapsack on the soldier's back. Operating under cover of dark- ness, the rifleman points the "sniperscope" and his gun sights toward. a spot whence a sound has come. By switching on an infra- red spotlight, he makes rays scan the territory. These are reflected from the target, picked up by the i telescope and transformed into an image across the sights of the rifle- La.4 mn. -111111110 Uranium Test Kit designed to fit in your pocket, will make a positive identification in five minutes. Chemical bead is formed on wire, fused with crushed ore, then examined for lemon.- yellow fluorescence under ultra-violet light. $4.95 VIBRATOR IGNITION COIL?This miniature high volt- age coil provides high output for snooper- scope operation. No. 2444 POCKET DIFFRACTION SPECTROSCOPE. This is a very convenient pocket spectroscope for general purposes and students, use, having a dispersion of 20?. The slit is of a fixed width, protected by a glass cover to prevent dust from entering. An adjustment for accurately focussing the spectrum is provided. No. 2444. Pocket spectroscope, in case Our Price $12.50 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I.. II J 1,11.1 !ILJ ?ih 1-1 Ili Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Rush Order Blank Name Date Street Address or Rural Route Box No Town Zone State QUANTITY DESCRIPTION PRICE PER AMOUNT MINIMUM ORDER 50 CENTS. MATERIAL IS SHIPPED POSTPAID TO ANY POINT IN U. S. A. UNLESS MARKED OTHERWISE. CANADIAN AND FOREIGN ORDERS ADD 10% TO COVER COST OF ADDITIONAL PACKING. REMIT BY MONEY ORDER OR POSTAL NOTES. PRECISE MEASUREMENTS COMPANY 942 Kings Highway, Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 p (0 (Z 61:11.../LAdt?-?A:A. the Book of Snooperseopes Ingenious infra-red viewing device lets you see in the dark PRECISE MEASUREMENTS CO. 942 KINGS HIGHWAY BROOKLYN 237 N. Y. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5STAT Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 An Infrared Imacc Tubc and its Military Applications by G. A. MORTON AND I. E. Ftovy Reprinted from RCA REVIEW September 1946, Vol. VII, No.3 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 -- Ii I J." 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 AN INFRARED IMAGE TUBE AND ITS MILITARY APPLICATIONS*t# BY G. A. MORTON AND L. E. FLORY Research Department, RCA Laboratories Division. Princeton, N. .1. Summary?The military value of the security obtained by the use of infrared for nocturnal vision was recognized even before the entry of the United States into World War II. A program for the development of in- frared viewing devices employing electron image tubes was consequently set up by the National Defense Research Committee. Before the close of the war a number of types of infrared telescopes had be.en manufactured in quantity and had seen service in fairly large numbers. The 1P25 image tube is the essential element in the infrared electron telescope, and serves to convert the invisible infrared image into a visible image. The tube contains a semi-transparent photocathode which is proc- essed to be sensitive to infrared radiation, and an electron lens for imaging the electrons from the photocathode onto a fluorescent screen which becomes luminous upon bombardment by electrons. When an infrared image is focused on the photocathode, a visible reproduction of this image is formed on the fluorescent screen. Basically, the infrared telescope consists of the image tube, an objective for forming the infrared image on the photocathode and an ocular for view- ing the reproduced image. Associated with the telescope is a battery oper- ated vibrator power supply which furnishes the 4000 to 5000 volts and the several intermediate voltages required by the image tube. A variety of types of telescopes was developed and produced for a number of different applications. These included a signalling telescope employing a large aperture reflective optical system as objective, the Sniperscope which is a carbine-mounted telescope and infrared source per- mitting aiming and shooting in complete darkness and the Snooperscope composed of the same infrared units mounted on a handle for short range reconnaissance work. Binocular telescopes, helmet-mounted driving and flying instruments, long-range reconnaissance units and other special night- seeing devices were also developed in the course of this project. F.4VEN before the entry of the United States into World War II, it was recognized that many military operations would require the secrecy afforded by complete visual darkness. Therefore, the National Defense Research Committee, under Army and Navy directives, undertook the development of infrared viewing devices em- ploying electron image tubes and an investigation of the applications *.Decimal Classification: R138.31 x R800 (621.375). 1. This paper is based in whole or in part on work done for the National Defense Research Committee under Contracts OEMsr-169 and OEMsr-440 with Radio Corporation of America. # Reprinted from RCA Review, September, 1946. 308 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 1 H Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 309 of such devices. This work was carried out by these laboratories. A variety of infrared telescopes was developed suitable for different tasks and a number of types saw considerable service during the war. Among the most widely used were the Navy infrared signalling equip- ment and the Sniperscope and Snooperscope procured by the Army. Figure 1 illustrates an infrared telescope, while Figure 2 shows the laboratory prototype of the Sniperscope. Basically, all of these telescopes consist of an objective for forming an infrared image of the scene being viewed upon the photosensitive cathode of the image tube, the image tube itself, and an ocular for viewing the reproduced image. The general form of the electron tele. Fig. 1?Infrared telescope. scopes using refractive and reflective optics is shown schematically in Figure 3. The fundamental component of these infrared telescopes is the electron image tube. This tube consists of a semi-transparent photo- cathode processed so that it has high sensitivity in the infrared por- tions of the spectrum, a fluorescent screen and an electron optical arrangement for focusing the electrons onto the screen. In undertaking the design of these instruments and tubes, the re- quirements of mass production as well as those relating to the particu- lar application, were taken into consideration. As a result, the U. S. Declassified in Part- Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 .L . 11 1 1 II 1. [III 1 1111 fl 11 III?11111 II , I HI Id .. 1,11111 I I:11 1.1 ..1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 '410 ? ELECTRON TUBES, Volume II Fig. 2?Laboratory prototype sniperscope. Armed Forces were able ,to obtain these instruments in far larger quantities than could either the Germans or the Japanese whose in- struments were not suitable for quantity production*. INFRARED TELESCOPES OBJECTIVE LENS IMAGE TUBE SCHMIDT OBJECTIVE CORRECTOR PLATE OCULAR TO POWER SUPPLY SPHERICAL MIRROR PLANE MIRROR IMAGE TUBE. Fig. :3?Schematic diagram of two types of infrared telescopes. OCULAR TO POWER SUPPLY Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I J., Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 311 TILE IMAGE TUBE An investigation of electron imaging dating back to the early 1930's had resulted in successful image tubes.' ' However, the requirements placed on an image tube for military applications were so very different from any heretofore encountered that it was necessary to re-examine the entire subject again. The most important considerations were, of course, sensitivity of the tube and perfection of the image. These are properties of the activation, phosphor efficiency and electron optics, and will be discussed in greater detail. A second very important consideration was that the tube be?of such a form that it could be produced quickly in fairly large numbers. Finally, it should be so designed that a single type of tube could be used for all of the various applications envisaged. Tube dimensions selected as being the best compromise between the very small size which would be desirable for portable instruments, and the larger tube suitable for fixed units, were 41/2 inches length and 17/8 inches maximum diameter. This size was found convenient from the production standpoint, and useful in a wide variety of instruments. Consideration of power supply design, cable insulation and tube sta- bility dictated an overall voltage range of 4000 to 6000 volts. The first decision which had to be made concerned the most practi- cal way of imaging the electrons from the cathode onto the fluorescent screen. There are essentially three systems which may be used, namely: (1) uniform field between cathode and screen; (2) magnetic lens; and electrostatic lens. The first was rejected because of the close spacing betweer oathode and screen and high field strength necessary in the vibinity of the cathode. This makes the activation difficult and the tube prone to cold discharge. Also, the image produced in this way is erect where prefer- ably it should be inverted. Magnetic focusing was also rejected from the standpoint of weight and complexity, and because of the difficulty of obtaining an inverted image. An electrostatic lens system is capable of a sharp, clear image over a wide range of magnifications. The image is inverted making it un- necessary to use an inverting ocular for viewing the reproduced image. It is necessary to curve the photo cathode in order to produce an un- distorted image over a large angular field. Where a reflective optical system is used as objective, the curvature of the cathode can be made V. K. Zworykin and G. A. Morton, "Applied Electron Optics", Jour. Opt. Soc. Amer., Vol. 26, No. 4, pp. 181-189, April, 1936. 2 G. A. Morton and ENG. Ramberg, "Electron Optics of an Image Tube" Physics, Vol. 7, No. 12, pp, 451-459, Dec., 1936. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 II II HA I I Il I I. I I 111 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 312 ELECTRON TUBES, Volume II to match that inherently present in the image surface of these optics. It is, however, sometimes necessary to use an optical field corrector lens when an ordinary refractive objective is employed, if the field of view is to be flat. However, since the electrostatic lens is also free from the objections mentioned in connection with the magnetic and uniform field systems, it was selected as the most satisfactory for the purpose. The magnification of the image tube has an important bearing on its performance. This is because the brightness of the reproduced image varies inversely with the square of the magnification. Thus, if a telescope with a given overall.magniflcation employing an image tube IMAGE TUBE (IP25) ELECTRON LENS FLUORESCENT SCREEN 600 V. CATHODE 4000V. SIMPLE OPTICAL ANALOGUE Fig. 4?Schematic diagram of 1P25 Image Tube. with unity magnification and an X5 ocular is compared with one using an image tube with magnification and an X10 ocular, the image in the latter will be four times brighter. However, for a given size of image tube and angular field of view, the magnification cannot be de- creased indefinitely because ,as the power of the ocular increases the size of the exit pupil decreases until a poin t is reached where the pupil of the dark adapted eye is not filled. Beyond this point, the brightness of the retinal image does not increase with decreasing magnification of the image tube. For many applications, it is also essential that the exit pupil be much larger than the pupil of the eye, so that the ob- server's eye ,does not have to be located too exactly with respect to the Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ' INFRARED IMAGE TUBE 313 instrument. Experiment showed that for a tube the size of the image tube under discussion, the magnification should not be less than one- half. Figure 4 illustrates schematically the construction and action of the image tube adopted. ELECTRON OPTICAL CONSIDERATIONS The electron optical system of the image tube consists essentially of a strong main lens as the principal imaging means and a series of relatively weaker correcting lenses between the cathode and main lens. The potential distribution along the axis of the tube is shown in the upper portion of Figure 5. Two electron paths, one of an electron CORRECTING LENSES MA IN LEN'S G, G. G. Fig. 5?Potential distribution and electron paths in the Image Tube. originating from the cathode on the axis of symmetry with radial initial velocity, the other originating off the axis with no initial velocity, are illustrated in the lower part of the figure. These two paths are sufficient to determine the first order imaging properties of the system. A detailed theoretical study of this type of system le4e5 to the following conclusions: (1) Curvature oi the image field and pincushion distortion can only be eliminated by the use of a curved cathode (or a radial potential gradient on the cathode). Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I_ I 11 I . LU 1..td 1 1 1 I In I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 314 ELECTRON TUBES, Volume II (2) Curvature of the image surface and astigmatism limit the off-axis definition. (3) Chromatic aberration due to the spread of initial velocities of the photoelectrons establishes the limit of resolution at the center of the image. (4) Spherical aberration and coma play a negligible role in limit- ing the definition. The radius of curvature of 2.38 inches selected for the cathode was a compromise between that required for a flat electron. image surface and optical considerations of the objective. With this Ciirvature very little pincushion distortion remained, and a definition of 350 lines (television nomenclature) or better could be obtained near the margins of the picture. At the center, the diameter (C) of the circle of cohfusion due to chromatic aberration is given approximately by: 2 m V/E (1) where E is the gradient near the cathode and V the' initial electron energies in electron volts. Evaluating this from the gradient known to exist in the tube and from the initil velocities expected near the infrared threshold, the limiting definition at the center, is 2000 or more lines. Definitions of 1000 lines were realized in laboritory tubes, and of 450 lines or better in production tubes. In general, the difference in definition between the theoretical estimated definition and that achieved in practical tubes is due to misalignment of the electrodes, inhomogeni- . ties in the photo-cathode and granOlarity of the fluoiencent screen. PHOTO-ELECTRIC CATHODE The photo-sensitization of the cathode is one of the critical steps in the preparation of the image tube. Research to date has lead to the cohclusion that a complex surface involving caesium, oxygen and silver yields the highest infrared response of any of the surfaces yet studied. This surface is formed by evaporating a thin layer of silver on the cathode disk, oxidizing it completely, then adding alternately silver, caesium and silver while subjecting it to an appropriate thermal treat- ment. The completed surface is semi-transparent so that, when illumi- nated from the outside, electrons are emitted from the inner surface. The photoemission from a well activated surface of this type will be 30 to 50 microamperes per lumen for whole light (iiisible + infrared) from a. tungsten source at a color temperature of 2870 degrees Kelvin. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001'600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE Figure 6 illustraths the spectral response of this type of emitter. 315 FLUORESCENT SCREEN The requirements of the fluorescent screen are the following: (1) It must have a high efficiency of conversion of electron energy into visible-light of a color suitable for scotopic vision. (2) It should have a fine grain structure capable of giving high definition. (3) Its time 'constant must be short so that moving images do not blur. (4) It should be inert to the chemical action of caesium. Synthetic willemite was found to satisfy these requirements fairly well, although its' phosphorescent decay time is somewhat longer than 60 50 O 40 a. UI 1/1 CC 30 6.1 ? 20 -1 UI CC JO ? .2 Lo LI 12 1.3 14 WAVELENGTH (MICRONS) Fig. 6?Spectral response of 1P25 Image Tube. might be desired-,.. In spite of its shortcoming as far as persistence is concerned, it was selected as the phosphor most suitable for the 1P25 because of its availability and ease of handling together with its chemical stability., The efficiency' of this phosphor in the vicinity of 5000 volts is be- tween 1 and 3 candles per watt. Its color is green or yellow-green which is quite satisfactory from the standpoint of scotopic vision. With a little care, the grain 'and aggregate size can be made small enough so that the screen does not limit the definition of the image. The decay charac- teristic of the material cannot be expressed by a single time constant. However, for the brightness involved in such applicatiohs of the tube Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I I I I l_ Ii II I I I IIIt ? Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 316 ELECTRON TUBES, Volume II as night driving, reconnaissance, and sniperscopes, the relation: g=go,-60t (2) where t is the time in seconds after excitation ceases and Bo is the brightness at t o is entirely adequate. The expression for phos- phorescent decay indicates that the image brightness falls to 10 per cent of its initial value in 0.04 secs. While rapid enough for most purposes, it causes some loss in definition for, rapidly moving objects. At very low brightness levels, the decay becomes less rapid than ? is indicated by this expression. This long low-level afterglow is of con- sequence in the detection of an infrared marker and signal light near the visual threshold. Fig. 7-1P25 Image Tube. IMAGE TUBE PERFORMANCE The performance of the 1P25 image tube may be summarized as follows: The light output per lumen of Tight incident on the photo- cathode, or conversion, is in the neighborhood of 0.5 to 1 lumen. In conjunction with an infrared filter, the conversion is reduced by the corresponding filter factor. It has been customary to express this filter factor in terms of the ratio of the image-tube response for whole light from a given incandescent source at color temperature 2870 de- grees Kelvin to the response from the same source when filtered. The central definition of the image is 450 lines or more and the Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 1 1, 11 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28 : CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 317 peripheral definition 300 lines. This definition is such that for most brightness levels encountered in practice, the eye rather than the instrument is the limiting element. A photograph of the finished tube is shown in Figure 7. During the later stages of the research program, a number of new types of tubes were developed to meet special problems. One of these was a single-voltage tube, contained in an envelope identical to that of the 1P25, but requiring no intermediate or focusing voltages. This tube is interesting in that it employed an electron optical system with an unconventional departure from circular symmetry. A second tube operated at an overall-voltage of 16 kilovolts employing a multiple lens anode. INSTRUMENTS EMPLOYING THE 1P25 During the course of the investigation, many different types of infrared instruments were developed employing the image tube. The number is so large that only a small fraction of them can be described in this paper. Therefore, a few representative instruments have been selected which will be described ahd their performance indicated. Signalling Telescopes One of the widest and at the same time most exacting use of the electron telescope is for the observing of infrared signal and marker lights. Here, since the object observed is an unresolved luminous point, the consideration,s involved in determining the sensitivity of the instrument are quite different from the case of an extended image. The two primary optical factors are the area of the objective and the magnification, while for the image tube the conversion and background only are involved. It will be noticed that the f-number of the objective and magnification of the image tube do not affect the sensitivity. How- ever, if a lens with a large f-number or an image tube with high magnification is used, the angular field of view will be small which is undesirable for a marine signalling or search instruments. For these reasons the signalling telescope was designed with an objective having a short focal length and.large aperture. The only practical way of achieving such a system is by the use of reflective optics, as illustrated in the lower part of Figure 3. The corrector plate and spherical mirror were of transp. arent plastic, assembled as a unit in a plastic barrel. The system was arranged so that the image was folded back by means of a plane mirror onto the cathode of the image tube. The focal length of this objective was 2.4 inches and its effective f-number was about 0.9. The image on the fluorescent screen was viewed through an XII npriacsified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I 11 1 lu I .111 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 318 ELECTRON TUBES, Volume 11 ocular. A hemisphere, which was an integral part of the image tube bulb, was a component of the ocular system. The telescope and power supply were assembled in a light, weatherproof and hermetically sealed magnesium casting. A discussion of power supplies for this type of instrument will be postponed until a later section. A much larger reflection-type telescope was also developed having a 7-inch focal length and approximately the same effective numerical aperture. This instrument was very much more sensitive as a signal- ling telescope but had a much smaller angle of view. Because this instrument was also designed for reconnaissance, its optical focus was made variable through an adjustment which moved the plane mirror in and out. Reconnaissance Telescope With the exception of the large reflective-type telescope mentioned in the preceding paragraph, the reconnaissance instruments were in general of the small portable variety. In order to give them greater depth of focus than could be obtained with a reflective optical system, these telescopes employed refractive optics with f-numbers down to about 2.0. With an f/2.0 lens and an image tube having a conversion of 1.0 the ratio of brightness of the image of an object illuminated with whole light as seen through the telescope to brightness as seen directly is about 0.10. This ratio is reduced by the appropriate filter factor when a filtered source is employed. In their simplest form, these instruments consist of a barrel (usu- ally of mu-metal or other high permeability alloy for a shield) contain- ing the image tube, to which are affixed the objective and ocular, both in focusing mounts. Tests indicated that objective focal lengths in the range 21/2 to 31/2 inches and ocular magnification of X8 to X12 were most satisfactory. For example, when used as the basis of a driving telescope, as will be discussed below, an instrument with a 21/2-inch objective and an X8 ocular giving an overall magnification of unity and a 24-degree field of view gave best results, while for devices such as the Sniperscope and Snooperscope a 31/2-inch focal length objective and a X8 or X12 ocular were to be preferred. Power for the image tube was supplied through a three wire, in- sulated cable providing ground, the overall voltage and the variable focusing voltage. A resistance voltage divider at the image tube socket provided the other voltage steps for the 1P25. Other instruments were designed with the power supply an integral part of the telescope. One unit employs a 21/2" focal length f/2.0 plastic Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ? I Ji Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 319 objective and an X12 ocular. A model is illustrated in Figure 8. Its size and weight is only about one third that of the telescope shown in Figure 1. For general purpose observation, these simple in-line monocular telescopes served as very useful tools. For example, this type of in- strument was frequently carried by an observer during night driving. Also, it was used to supplement the large reflective-type telescopes as general orientation instruments, and for many other supporting opera- tions. Under these circumstances, the illuminator providing the in- frared radiation was a separate unit over which the user of the tele- score had little or no direct control. Fig. 8?Experimental telescope. Frequently it is advantageous to have a portable light source to use in conjunction with the telescope. Therefore, a study was made of instruments involving source-telescope combinations. In particular, two instruments of this class were developed, namely, a monocular telescope and a light source mounted on a handle for relatively short range reconnaissance (see Figure 9) and a similar telescope and source mounted on a carbine in such a way that the telescope could be used for aiming in complete visual darkness. These instruments were christened Snooperscope and Sniperscope respectively and were later Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I I I III I. LI I I .1 I I!Hi.? Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 320 ELECTRON TUBES, Volume II named Molly and Milly by Members of the Armed Forces. The telescopes used in the laboratory prototypes of these units were essentially the same as the monocular telescope described in earlier paragraphs. The objectives were 31/2-inch focal length f/2.0 lenses while an X8 ocular was used for viewing the screen. A chevron was placed on the surface of the field-corrector lens to serve as the aiming index for the Sniperscope. This chevron was accurately aligned with the direction of fire of the piece. By placing the aiming index at the objective, distortion or deflection of the electron image had no effect on the accuracy of aiming. Tests were made to determine whether the telescope, including the image tube, was sufficiently rugged to withstand the rough usage in- volved in this application. No particular difficulties were encountered Fig. 9?Laboratory prototype Snooperscope. in the case of the Snooperscope. In the Sniperscope, a certain percent- age of tubes were found to fail as a result of the shock of firing, due to minute particles of the phosphor becoming dislodged from the fluor- escent screen and settling On the lens electrodes and causing flashing in the tube because of cold discharge. This made it necessary to shock- test production tubes before employing them for this purpose. The selection of the size and form of light source was a result of compromises in a number of directions. These included angular field, range, operating life for the allowable battery weight, and considera- tions of security. The source chosen for the laboratory models was a special General Electric sealed beam lamp with a 12 to 15 degree spread and a maximum beam candle power of 80,000. Various infrared filters Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5  I fl Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 321 were used including Corning 2540 heat transmitting glass and the Polaroid XRX series. The high voltage power supply and storage batteries were carried in a knapsack with a cable from it to the instrument carrying both the image tube voltages and the current for the infrared source. The de- sign of the power supply is discussed in a later section. The weight of the telescope and source was about 5 pounds while the power supply and batteries weighed approximately 13 pounds. The unit was capable of 3 to 4 hours continuous operation before it was necessary to recharge the batteries. The Snooperscope and Sniperscope were manufactured on a fairly large scale, the production design being carried out by the Engineer Board of the Army for the Corps of Engineers. Driving Instruments In some applications, particularly vehicle driving, it is advantageous to have binocular vision. It is interesting to note that while the observer feels a very definite need of being able to use both eyes it makes very little difference whether or not he has stereovision. The first experimental driving instruments were in the form of a single large barrel carrying the objective and eyepiece, and enclosing an image tube which was much larger than the 1P25. The eyepiece was so arranged that the virtual image of the fluorescent screen was at infinity and the observer saw this image with both eyes. This type of driving telescope was found to be generally quite satis- factory, but suffered from two serious drawbacks. It was quite large and occupied considerable space in the vehicle and it was difficult to use on short turns. To overcome these difficulties, a small binocular instrument was developed using two 1P25's. This instrument, illustrated in Figure 10 gave the observer true stereovision. The binocular consisted of a pair of in-line telescopes mounted parallel to one another by means of hinges so that the interpupillary distance could be adjusted to fit the user. In order to obtain satisfactory register of the images seen by the two eyes, it. was necessary to provide means for moving the two images relative to one another. This was accomplished by mounting the ocular lenses in such a way that their axes were slightly displaced with respect to the axes about which the ocular fittings could be rotated. When the eyepiece fittings were turned the two virtual images seen by the observer moved in circles about two different centers. The points of intersection of these circles are the points of register of the images. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I I Iliii III ,_ 11 111, 111 1 LIU 1 11,1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 322 ELECTRON TUBES, Volume II Separate focus of the two objectives and two oculars was provided. The power supply was designed so that the electrical focus of the two image tubes was also independent. These binoculars, with a suitable head rest, served as excellent driving telescopes, when supported on a pivoted arm in front of the driver. As designed the instrument not only gave the operator use of both eyes but also permitted true stereovision. Some experiments were undertaken in helmet mounting the in-line binoculars. However, even when counterbalanced to neutralize the forward torque of the instrument, the moment of inertia was rather high which made it awkward to handle. To overcome this, an investigation was made on a series of helmet- Fig. 10?Infrared In-line Binocular. mounted instruments. Figure 11 illustrates an early right-angle peri- scopic unit. The results of these tests were so encouraging that the -development of a light-weight, Z-shaped binocular suitable for night flying and driving, was undertaken in collaboration with the Johnson Foundation of the University of Pennsylvania. The completed instrument is illustrate in Figure 12. The unit was made of aluminum, and plastic optics were used throughout (except for the ocular lenses) to reduce the weight to a minimum. The folding was accomplished by means of plastic prisms. Again, independent optical and electrical focusing adjustments were provided for the two sides, the electrical focus being controlled by means of potentiometers mounted at. the bases of the telescope barrels. Register of the image was effected by Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 323 means of a pair of rotatable ring magnets mounted on each barrel just below an inner mu-metal shield which surrounded the image tube from cathode to main lens. The resultant field of these ring magnets, which could be varied in intensity and direction by rotating the rings, made it possible to deflect the electron images into exact alignment. These helmet telescopes appeared to be a very adequate solution to the problem of infrared night driving, and were on the verge of going into production when the war ended. Fig. 11?Periscopic Helmet Monocular. HIGH VOLTAGE POWER SUPPLIES The 1P25 image tube requires a rather high voltage for its opera- tion. Since portability was one of the aims of the development, it was essential that the power supplies be small and operate from a small primary battery source. At the same time, the battery life had to be above a certain minimuT if the instrument was to be practical. The design of a power supply meeting these requirements is pos- sible only because of the fact that while la 4000 to 6000-volt output is Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I 11 I LILI I II ( I 11111 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 324 ELECTRON TUBES, Volume II required, the actual power needed is very small. The tube itself re- quires only a fraction of a microampere of current even under bright light conditions. The total power output required to supply the tube and the voltage divider necessary for the various focusing electrode voltages of the 1P25 is on the order of a tenth of a watt. The only practical available means of converting the low voltage Fig. 12?Type Z Helmet Binocular. from the batteries to the high potential necessary to actuate the image tube is a vibrator-transformer-rectifier combination. A typical vibra- tor power supply is shown in Figure 13. It differs from the conven- tional vibrator power units used in battery operated radios, in that, due to the low power requirement, use can be made of the relatively high voltage peaks appearing across the primary of the transformer when the magnetic field collapses as the primary circuit is broken by Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 325 the vibrator. In addition the primary is tuned to resonate with the natural period of the secondary to obtain maximum transfer of energy. By this method an effective primary voltage of ten to twenty times the battery voltage is realized. This makes possible a great reduction in the size of the transformer required. A standard automobile type vibrator was used because of ease of procurement. The frequency was of the order of one hundred inter- ruptions per second and the power consumed was about 0.2 watt. A conventional rectifier circuit and capacity filter was used employing the special rectifier described later. The design of the transformer was necessarily a compromise be- tween light weight and efficiency. A light-weight transformer with VIBRATOR R?il*NO K- 901414 Fig. 13?Basic circuit of vibrator power supply. somewhat lower efficiency means a larger battery or shorter battery life, while a heavier transformer will give a higher efficiency due to lower core losses. As a result, the optimum transformer is usually a design unique to the particular application. For an overall efficiency of 10 per cent, including vibrator power and rectifier filament, at an output of 4000 volts, the weight of the transformer is on the order of 20 ounces per watt of output. This means that in order to supply one- tenth watt at 4000 volts a two-ounce transformer would be required at an input of one watt. At somewhat higher power ouputs the efficiency may run as high as 20 per cent, since the power taken by the vibrator and rectifier will be constant. A typical transformer design may be approximated by making the following assumptions: Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I 11 I III 1.1,1 I I I 1.. 1 LII 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 326 ELECTRON TUBES, Volume II Vibrator frequency-100 per second Time of contact?.005 second Battery voltage-3 volts Maximum battery current (peak)-3 amperes Peak output voltage-4000 volts. Under the type of operation required, the secondary current is small and most of the power dissipated in losses. Therefore, as a first approximation the effect of the secondary circuit on the primary may be neglected except as it affects the resonant frequency. If the time constant of the primary is made equal to the contact time, then ?= .005 Since the maximum current is to be 3 amperes and the voltage is 3 volts, the primary resistance is 1 ohm. Consequently, L = .005 Henries. If the decay time of the primary current is now assumed to be one-tenth of the contact time as determined by the resonant frequency of the secondary to which frequency the primary is tuned, then A e = L ? t = .005 = 30 volts. .0005 (3) Since the peak output is to be 4000 volts, the turns ratio of the trans- former becomes 4000 = 133 30 To obtain the necessary primary inductance requires about 100 turns. Thus 13,300 turns will be required for the secondary. The direct current from the 3-volt battery under these conditions is about 0.5 amperes with the secondary delivering about 50 micro- amperes. A core cross section of 0.25 square inch ordinary silicon steel with a 0.010 air gap was found sufficient. Since no rectifier of small size and low filament power consumption was available, a special tube was developed. This tube, shown in Figure Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 .1 _1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 327 14, is now in production as the 1654 and in the special circuit shown will deliver 100 microamperes at 5000 volts. ? A typical example of this form of power supply is shown in Figure 15. This supply delivers 0.15 watts at 4000 volts with an input of one watt. The total weight including the battery, which will operate the instrument for 21/2 hours, is 21/2 pounds. A high degree of stability of the overall voltage is not essential but the ratio of voltages on the various electrodes must be maintained to Fig. 14-1654 Rectifier Tube. keep the image in good focus. The regulation of the power supply is not important since the load is essentially constant. As a matter of interest the equivalent resistance of the power supply shown in Figure 15 is approximately 40 megohms. Since the overall voltage varies considerably as the batteries dis- charge and since the instruments may be subjected to wide ranges of temperature, behavior of the components of the voltage divider as Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 II 1 1. _11 1 111 LIE I I . I I ill Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 328 ELECTRON TUBES, Volume II regards temperature and voltage was a matter of considerable con- cern. It would be highly desirable to be able to maintain the proper voltage ratios over the range of temperatures and voltage encountered in the field. However, this is not always possible and occasional re- focusing may be necessary although the variations can be greatly reduced by proper choice of components in order to balance their characteristics. All of the available high value resistors (50 megohms or more) show considerable change of resistance with voltage. The voltage character- istics of a few of the best-known resistors are shown in Figure 16. Using dry cells as a source of power, a 2 to 1 change in overall voltage may be encountered from start to end point. Under these conditions, it is impossible to maintain focus without adjustment since a 50 per cent change in voltage represents a change of about 5 per cent in Fig. 15-5-kilovolt vibrator power supply. resistance of the best resistor. Therefore, unless compensation can be provided, it is necessary to refocus as the batteries deteriorate. In the case of storage batteries, about 10 per cent change in voltage may be expected over the operating life. This produces a negligible change in resistance of the No. 5 resistor and no refocusing is necessary. Most resistors have a high temperature coefficient and in order to design a voltage divider which will maintain the tube focus independ- ently of temperature, it is necessary to select components which either have the same coefficient, so that the ratio remains the same over the temperature range, or which have coefficients which tend to compensate Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 L J1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 329 for each other. Variation of resistance with temperature for a variety of resistors is shown in Figure 17. In making up a divider, many combinations of resistors tending to compensate are possible. From the curves in Figure 17, two combina- tions were selected and the characteristics of the dividers plotted in Figure 18. In both cases, the G3 voltage remained essentially constant over the entire temperature range, the small variations being in such a direction as to compensate for the variation in G2. With divider No. 1 adjusted for focus at 20 degrees Centigrade, the voltage on G2 remains in the region of good focus over the range from ?10 degrees Centigrade to + 60 degrees Centigrade. Divider No. 2 remains in focus 3; 0 0 co) cc 0 2 0 CC 0 ?20 5 Ui 0 ?30 V CC 0. 1000 2000 3000 4000 5000 - APPLIED VOLTAGE Fig. 16?Voltage characteristics of resistors. from ?40 degrees Centigrade to +75 degrees Centigrade. Therefore, using storage battery supply and selected components for the voltage divider, it is possible to build an instrument which will not require electrical focusing in the field under the range of conditions usually encountered. The Type S., supply shown in Figure 19 is an interesting modifica- tion of the vibrator power supply. This arrangement is similar to the conventional voltage doubler circuit except that the two halves of the doubler are brought out separately. In this way, it is possible to place a voltage divider across one side without disturbing the other. In these vibrator supplies, the alternating-current wave is non-syrtunetri- neclassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I. 11 I. Id 1-1,I I I I Idu I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 330 ELECTRON TUBES, Volume II -40 -30 -20 -10 0 410 420 .30 440 DEGREES CENTIGRADE ?50 +60 +70 Fig. 17?Temperature characteristics of high-valued resistors. +80 cal, being in the nature of a damped oscillation, so that in the circuit shown, the voltage across the high voltage section, which is determined by the first loop of the wave, is about 4000 volts while the voltage in the opposite section, determined by the second or negative loop, is about 1000 volts. Therefore, by putting the voltage divider across +6 +4 42 04 _[ R, 200 MEGS --E3(G,) R, 20 MEGS R, 10 MEGS RA 1 MEG G. 11t I MEG ? DIVIDER 41 R 6 FIG.I7 ? =? "9 DIVIDER R, -6 FIG.I7 R2 = R, = '4 174, P. STD I MEG - DIVIDER ?I -2 -4 -6 -6 -101- E.z -40 -3'0 -20 -10 0 ?10 420 +30 +40 450 460 410 Fig. 18?Temperature characteristics of composite voltage divider. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I .11 , Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 jaL/3 4760 T? INFRARED IMAGE TUBE 331 K. 901576 . ( ET -4236) 614 YE L. Of ORR R- 6193 BLUE 30u) 1.0039 .0039 RED 4C, ? BLUE R.G.193 Fig. 19?Voltage doubler power supply (Type S-2). 4,1MEG. ME4 only the low voltage section, the desired low voltages may be obtained without loading down the high voltage section. Another very interest- ing feature of this circuit is the fact that by introducing resistance in the tuned primary circuit, the damping of the circuit is increased which tends to decrease the second or negative loops and thus the low voltage without appreciably affecting the high voltage. This action is shown in the curves on Figure 20. This affords a means of varying the POINT OF FOCUS OVERALL VOL TAGE 100 RE EiS TANCE O14M5 200 300 400 Fig. 20?Voltage control of type S-2 Power Supply. 500 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I I II I 111. 1,dd .. I I l Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 332 ELECTRON TUBES, Volume II focusing voltage by an element in the primary circuit which is a great advantage from the standpoint of electrical design. Another power supply of interest was developed for use with the single voltage tube. With this tube the only load on the power supply is the actual photocurrent and leakage. By careful design, the entire load resistance can be made as high as 1010 ohms. Using a relatively large capacity in the output, the time constant of the circuit can be made to equal several seconds so that a quite infrequent charging of the circuit is required. For this purpose, an Interrupter was designed consisting of an electrically-driven balance wheel having a period of Fig. 21?Electrical components of pulsed power supply. about 1/4 second. The design was such that the transformer primary is open most of the time and is closed for a short time, to allow the current to build up, and immediately opened. In this way the drain on the battery is extremely small, the supply operating for as long as 50 hours on a single size D flashlight cell. A photograph of the interrupter, the 1-ounce transformer designed for the purpose and the special rectifier described below are shown in Figure 21. Since the primary power required by this supply is so small, the power taken by the usual rectifier filament becomes very large in com- parison. Consequently, a new type "filamentless" rectifier was developed, known experimentally as the KR-31. This rectifier depends for its action upon a gas discharge in Helium, Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I E 1 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 333 Neon, or other inert gas at about 0.5 millimeters pressure. The cathode is an aluminum cup, mounted so that its closed side faces the anode. The anode is a nickel rod or tube, over which is fitted a woven fibre- glass sleeve. The entire anode is covered with the fibreglass; the sleeve fits down over the glass seal at one end and is closed by fusing the glass at the free end. The peak inverse voltage of the KR31 is 6000 volts and the for- ward breakdown voltage is 300-600 volts. The peak current may be several milliamperes but the allowable average current is low. In the applications for which the tube was designed the average current is under 10 microamperes. An average current of 50 inicroamperes may not be exceeded except for very short periods due to sputtering and clean-up of the gas. This tube has not been put into production and is not available commercially. The power pack for the Snooperscope and Sniperscope involved some special considerations. A 6-volt, 25-ampere-hour storage battery was used to operate the infrared source so the power required to oper- ate the high-voltage power supply was a negligible drain on the battery. It was necessary to silence the vibrator to a surprisingly high degree since the most obvious uses of the instruments were under conditions of extreme quiet and where the utmost in secrecy was essential. The usual rubber-mounted automobile radio-type mounting is effective for damping out the high frequencies, but the fundamental vibrator fre- quency (100 cycles) is not sufficiently suppressed. One method used in experimental models was to suspend the mounted vibrator by two flat spiral springs of at least one turn, coiled around the vibrator can, the inner ends being fastened to the vibrator can and the outer ends to the power supply chassis, or box. By proper choice of spring thick- ness, a period of only a few cycles per second can be obtained with sufficient stiffness to support the vibrator adequately. By this means it was possible to silence the vibrator so that the user himself could not detect the vibration. Another method used, with some increase in bulk, was the addition of one or more stages of sponge-rubber cushioning around the usual vibrator can. The type MA4, high-voltage image tube raised some special prob- lems in power supply design. The overall voltage required is on the order of 15 to 20 kilovolts and in addition, a number of intermediate voltages are required. These intermediate voltages, particularly those over 4000 volts are difficult to obtain efficiently by conventional means because of the relatively large power which would be wasted in a voltage divider of sufficiently low resistance to be stable. Also, it is Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I. IL I LII Lid I I I. I i.. 1 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 334 ELECTRON TUBES, Volume 11 possible to obtain higher voltages from the previously described power supplies only by increasing the flux in the transformer. This in turn can be accomplished only by increasing the primary power, necessi- tating larger transformer and batteries. Lastly, if a conventional power supply is used, a rectifier tube capable of withstanding 20 to 30 kilovolts inverse voltage would be necessary. This type of rectifier is not available in small size and low filament power. Consequently, a cascade type (voltage-adding) power supply was designed which over- came most of the objections and automatically provided the necessary four steps of high voltage without a voltage divider. A schematic diagram of the S-5 power supply making use of this circuit is shown in Figure 22. As can be seen, this supply is made up of four rectifiers which are essentially in parallel for alternating cur- AMPA44101- PI.04 TO BATTERY VIBRATOR. K..84749 24. .45 TR An5FOR wIER. 401574 ? OOLA F .002 .004 A F F "44-Twrff-'4 G7.0 .004 AF I .004 ? 004 F TO SoCWIT Fig. 22?Circuit of voltage quadrupler power supply (Type S-5). rent. The direct-current voltages developed across the rectifiers, how- ever, are added by means of the resistors which connect the anode of one rectifier to the plate of the next and thus place ail the rectifiers in series for direct current. These resistors offer much higher impedance to the alternating current than do the capacitors so they do not affect the parallel alternating-current connection. Any number of stages may be cascaded in this manner,, provided, of course, that the transformer will deliver the proper voltage to all the rectifiers in parallel. Four stages were chosen in this case because four steps of voltage are neces- sary for operation of the MA4 tube. The lower voltages required for the tube are obtained in the usual way by a voltage divider across the first section of the power supply. A thermionic rectifier (1654) is used in this stage in order to supply the divider current but the following stages make use of KR31 gas rectifiers, thus eliminating the need for Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5  iiH H Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 INFRARED IMAGE TUBE 335 filament supply circuits, with a high degree of voltage insulation. The current drain at the high voltages is very low so that the voltages shown are obtained with a total battery current of only 0.4 ampere at 2 volts. A photograph of the power supply is shown in Figure 23. The chief problems in connection with this supply are leakage and corona. These must both be kept to a minimum since the internal re- sistance of the puwer supply is quite high (approximately 109 ohms at the 16-kilovolt tap). Leakage can be minimized by use of high-quality insulation and protection from humidity. Hermetical sealing, or other provisions for drying, are essential with this type of voltage supply. Fig. 23-16-kilovolt voltage quadrupler power supply. Corona can be prevented by eliminating all sharp edges at the high voltage connections or by coating with a closely-adhering insulating material such as wax. CONCLUSION The above discussion stresses only the military application of in- frared imaging equipment. There are, however, a number of peacetime uses for these instruments. Among these applications are their possible value in police work, their use in the field of medicine, the viewing of the usual types of photographic film during processing and production and for the inspection and control of a number of other industrial and scientific processes where visible light is undesirable. In closing, the authors wish to express their appreciation to Dr. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I 11 I III Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 336 ELECTRON TUBES, Volume II V. K. Zworykin, Director of Electronic Research, for his advice and encouragement during the course of this development and also their recognition of the contribution made by Dr. J. E. Ruedy, G. L. Krieger and Dr. P. Rudnick to this project. Credit should go to Dr. L. B. Headrick, Miss H. C. Moodey and Dr. R. B. Janes of the Lancaster plant for work on the production design of the image tube. As an interesting example of the effectiveness of the infrared devices described in this paper, two illustrations of a war street scene at night are included below. The upper picture shows the scene as viewed by the unaided eye. The lower picture shows, in the circle, the details of the scene when viewed by the infrared devices. The Manager, RCA REVIEW Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Home= Built Snooperseope Ingenious infra-red viewing device lets you see in the dark DURING wartime, man's inability to see in the dark can often mean the difference between life and death. This is particularly true of scouts, patrols, night drivers, and flyers. Since visible light makes an excellent target for the enemy, mili- tary 'forces began experimenting with infra-red rays as aids to nocturnal vision when visible light is not per- mitted for reasons of security. Many types of infra-red telescopes were de- veloped as the direct result of this need for invisible illumination. The sniperscope (an infra-red light source and telescope mounted on a car- bine to permit the soldier to locate and shoot the enemy while both are in total darkness) and the snooperscope (an infra-red light source and telescope used for short-range observations) are perhaps the most well known of these developments. Other infra-red instru- ments include helmet-mounted driving and'flying binoculars, and blackout sig- naling devices. The infra-red telescope is designed around an infra-red image converter tube which transforms invisible infra- red rays to visible light. Several types , of image converters were developed. The American forces used equipment built around the RCA 1P25 infra-red image tube. This tube has a cathode which emits electrons in proportion to the amount of infra-red light falling on it. Additional electrodes within the tube focus the electrons on a fluores- cent screen. Thus the image falling on the cathode is focused on the screen without scanning devices. This tube, described in detail in the September, 1946, issue of RCA Review, requires By HAROLD PALLATZ voltages of 15, 100, 600, and 4,000 for proper operation. The British developed a simplified infra-red image converter tube requir- ing a single source of 4,000 to 6,000 volts for its operation. This tube, type CRI 143 or CV 147, is currently avail- able on the surplus market and is used in this experimental snooperscope. The parts for this snooperscope?a CRI 143 or CV 147 infra-red image converter tube, a 4,000-volt, low-cur- rent power supply, two infra-red fil- ters, and a light source?are easy to obtain. The power supply For indoor operation, a 4,000- to 6,000-volt neon-sign transformer oper- ates the tube satisfactorily. Rectifica- tion is not necessary unless the objects under observation are in motion. (Ap- plication of the image tube as a strobo- scope is the subject of a patent appli- cation made by the author.) A portable 4,000-volt power supply designed for use with this snooperscope is shown in the photograph and in Fig. 1. This efficient supply needs to be turned on only momentarily to charge the 0.1-?f, 6,000-volt capacitor. The snooperscope works for several minutes on the charge, and thus it can be op- erated for long periods without notice- able battery drain. The high voltage is supplied by a model-airplane ignition transformer with a vibrator to interrupt the pri- mary current. The vibrator, not :visible in the photograph, wits removed from a small buzzer and mounted just above the core at one end of the transformer. A small buzzer can be inserted in series Reprinted from Radio Electronics Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified I I. J1 I .I iii. in Part - Sanitized Copy Approved for Release former if desired. The rectifier tube is a 1B3-GT/8016. When the power supply is turned on, the current drain drops the voltage of each cell to approximately 1 volt; therefore the 1B3 was connected in series with a 1-ohm resistor across two cells. (A 3Q5, with its plate and screen grid tied together and control grid floating, might do the job just as well and would use less filament current. See the battery-operated, high-voltage supply described in the article "Build This Geiger Counter," in the Septem- ber issue of Radio-Electronics.?Ed- itor) 1133-GT/8016 DPST SW 2 7 L7pc_.1 .25/600 ?1E? FROM OLD BUZZER, 4K \/' 0+ 7.7 1.5V HI IC NSIO I. 3 No D BATTS LEAD MODEL PLANE ON COIL Fig. I?Miniature high-voltage power supply. The power supply was constructed in a plastic ice-box dish and fitted with insulated binding posts. Avoid contact with the output of this power supply or a rather uncomfortable shock may result. The capacitor remains charged for some time after the supply is turned off, so be careful. (It might be wise to shunt the output terminals with two or three 47,000-ohm resistors in series when the supply is not being used.? Editor) Assembling the snooperscope The snooperscope is constructed as shown in Fig. 2. The image converter is mounted in a plastic drinking cup 3% inches high and 2% inches in diameter. The optical system depends on the requirements for the snooper- scope. We used a double-lens, fixed- focus jeweler's loupe (engraver's glass). It has a focal length of approx- imately 3 inches and objects a foot away from the observer's position are focused sharply. After selecting the optical system, mount it in a hole cut into the bottom of the cup. A jeweler's saw or coping I saw is ideal for cutting the hole. A few drops of household cement will hold the loupe in place. Paint the in- side of the CUD with a jet black paint 2011/12/28: CIA-RDP78-03300A001600020097-5 phone black. This will prevent stray reflections. Place an infra-red filter between the tube and lens to reduce the effects of stray illumination on the tube. No light should be allowed to enter the unit ex- cept through the lens. The light source must of course be filtered if it is to be invisible. Near infra-red filters will cut out most of the visible light. Far infra- red filters, while of somewhat lower efficiency, will cancel out visible light completely. They must be used with comparatively powerful light source. Infra-red filters can be purchased from a number of scientific and pho- tographic supply houses. Experimental infra-red filters can be made by sand- wiching several layers of red and blue cellophane between two sheets of clear plastic. The image-converter tube is inserted with the metal end toward the mouth of the cup. The thin flexible lead con- nects to the positive side of the power supply. The other end of the tube has a ring of graphite around the outside. This is the cathode terminal. This makes contact with the B-minus lead through a strip of spring brass or a thin coil spring formed to fit snugly around the cathode terminal. A piece of rubber tubing holds the tube in place. It is protected by a window cut from clear plastic and held in place with three brass clips as shown in the photograph. The handle is a plastic bicycle han- dlebar grip cemented over a hole drilled in the side of the drinking cup for the high-voltage leads. The light source The required intensity of the light source is determined by the distance from the target to the lens. Heat lamps, flashlights, and ordinary bulbs will work well for most indoor applications. Our model is equipped with automobile parking light housings on both sides. These supply a limited amount of illu- mination. The intensity of the parking lights is insufficient for many applica- tions and a heat lamp is used. Outdoor applications involving greater distances require a bulb with a sharply focused reflector. The sniperscope used a 30- watt, 6-volt bulb operated on a small rechargeable storage battery. Good sub- stitutes are auto headlamps, the sealed- beam type being preferable for this purpose. The heat lamps mentioned are of course those sold for infra-red treatment. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 .1. 1.1 .1 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 WINDOW GRAPHITE CATHODE TERMINAL PLASTIC CUP ENGRAVER'S GLASS PLEXIGLAS EYE 4 MAGNIFYING LENS (OPTIONAL) PLATE TERMINAL INFRA-RED CONVERTER TUBE INFRA-RED FILTER HANDLE TO POWER SUPPLY 3.5-60 Fig. 2?The construction of the snooperscope. Snooperscope experiments A number of interesting and enter- taining stunts can be devised around the snooperscope's ability to look through any opaque material which passes infra-red rays. Crime-detection laboratories use parallel equipment for reading through certain types of ma- terial. Since the infra-red reflection of pigments in paints and inks is different for white light, it is possible to detect forged paintings and checks by the way the colors appear. Demonstrate this by writing a message with India ink and then painting it over with a coat of or- dinary fountain-pen ink. The eye will only see the blackened spot but the snooperscope will peer through the top layer of ink and reveal the writing just as clearly as if there were no top coating. This type of inspection can be made photographically if infra-red film is used in a camera. The electronic method permits instantaneous exami- nation, which is often a great con- venience as well as an interesting ex- periment. Driving in fog has always been a great hazard. An infra-red beam will display the road with 30% more clarity. This increase may be the difference be- tween a safe situation and a very dan- gerous one. Snooperscopes for this pur- pose require very good lenses and pow- erful headlights. It would probably be difficult for an experimenter to con- struct one and dangerous to use it. The image-converter tube can be used as an infra-red phototube. Reduce the voltage to 250 or 300, and insert a 470,000-ohm to 1-megohm resistor in the B-plus lead. Connect a two-tube amplifier and relay across this resistor. The relay operates when infra-red rays strike the converter tube, changing the voltage across the resistors. A modified snooperscope has been used in bioloeical laboratories to study the behavior of rats and other small nocturnal animals in total darkness. The converter tube has been used with a microscope to study bacteriological and botanical specimens under infra-red rays. They have also been used in measuring temperatures of materials below visible red heat. For additional reading on this sub- ject, see: Forsythe, William E., Fluorescent and Other Gaseous Discharge Lamps. Pratt, T. H., Journal of Scientific Instruments, Vol. 24, No. 12, December, 1947. Monahan, A. C., Science News Let- ter, Vol. 50, page 26-28, July 13, 1946. Pratt, T. H., Electronic Engineering (London), Vol. 20, No. 247, page 278, September, 1948; and Vol. 20, No. 248, page 314, October, 1948. SNOOPERSCOPE TUBE Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I 1 II I III Ill I I I 1111 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 The Infra-Red Image Converter Tube Based on a Lecture delivered before the Electronics Group of The Institute of Physics Pr HE principle of the infra-red image converter tube is not new but it has only been with the development of equipment for Service applications that any parti- cular interest has been shown in such devices. In principle the image converter is a system for rendering visible radiation of wave- lengths lying outside the range of spectral sensitivity of the human eye. Several tubes have been described in the scientific journals, and the wartime work has consisted of the development of operationally serviceable equipment based on the principles given in the published accounts. In particular, equip- ment has been produced for Service use that transforms an image in the near infra-red spectral region into an image visible to the eye. It is, perhaps, appropriate first to make a brief reference to this near infra-red region of the electro- magnetic spectrum which lies between about 8,000 and 13,000 Angstroms (0.8 and 1.3 microns). The lower wavelength represents the approximate long wave limit of the response of the eye,' while the upper figure is the long-wave limit of sensi- tivity of most of the photodetectors available for use in this region. Transmission of near infra-red radiation through the atmosphere is virtually the same as that of visible light. In particular it should be noted that at wavelengths so slightly removed from the visible, no useful advantage is obtained in conditions of mist or fog. The tungsten filament lamp running at normal colour temperatures (say 2,800? K.) is, of course, an extremely efficient source of radiation in the region of one micron, and was used in all Service applications. By T. H. PRATT* The main phenomena used for detection in the region are photo- graphy, photoconductivity, phos- phorescence and photoemission. In the case of the first of these, the sensitivity of the photographic plate can be extended to about 1.3 microns by the use of a suitable dyestuff such as pentacarbocyanine to absorb radiation and transfer the energy to the main silver bromide lattice. Results obtained in long range aerial photography using infra-red plates have led to the widespread impression that near infra-red radiation will penetrate mist, but it must be stressed that the increased atmospheric penetra- tion is only obtained through the small particle haze that is present even under conditions of the best visibility. Photoconductivity and phosphorescence rely, as does the photographic plate, on an internal photoelectric effect. In the former, absorption of radiation raises elec- trons to the conduction level from impurity centres in a semi-conduc- tor lattice, with a corresponding variation in resistance, while in the case of phosphorescence, electrons that have been raised into trapping centres by some activation process, are removed from these centres by the infra-red radiation and return to the ground level with the emis- sion of visible radiation. The best known photo-conductor in this region is thallium sulphide,' while typical of an infra-red sensitive phosphor is strontium sulphide sensitised with samarium and euro- pium.' In the case of photo- emission, we have the external photo-effect, the absorption of radia- tion completely removing electrons from a layer. The main infra-red sensitive layer consists of a silver Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I L 1 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 rI00 3 cc oci 0 80 m 40 5 INFRA-RED FILTER Fig. I. The near infra-red region of the spectrum Cs.- 0-Ag. PHOTO-SURFACE I- R WAVELENGTH caesium oxide compound surface.' It is, of course, this latter effect that is used in the infra-red image converter tube. Image converter tubes relying on an internal photo- electric effect and an electron mirror system' will not be considered here, nor will devices such as the image orthicon in which the visible image is not formed in the tube itself. Principle of the Image Converter Tube In the infra-red image converter tube, an image formed with radia- tion of about 1 micron wavelength is transformed in to a visible image. .The infra-red image is focused on to a Ag-O-Cs photo-cathode and the electrons emitted caused to impinge on an anode in the form of a fluorescent screen. The converter may thus be divided into three main components, the photo- emissive surface, the electron optical system, and -the screen, with each of which it is intended to deal briefly here. The photo-emissive effect in an Ag-O-Cs layer results from the removal of electrons from the outer- most orbits of the caesium atoms by absorption of infra-red radia- tion. The energy transferred to an electron by a photon is sufficient not only to enable it to leave the field of influence of the parent atom but also, under favourable condi- tions, to overcome the forces of sur- face attraction and so leave the layer and pass into the evacuated space outside. The magnitude of the effect is dependent upon the wavelength of the incident radia- tion, and in the case of the corn- MICRONS posite caesium surface, peak response occurs at about 8,000 Angstroms with a long wave cut-off at 13,000 Angstroms. The number of photo-electrons is proportional to the intensity of radiation, although at room temperature there is always a number of electrons leaving the surface as a result of thermal agitation. There is some spread in velocity among the photo- electrons corresponding to the different wavelengths (energy) of the exciting radiation and to the varying depths in the layer at which the electrons are released. < The high accelerating voltages employed render this spread of velo- city unimportant. Since the number of electrons leaving a point of the photo-sensitive surface will be pro- portional to the intensity of radia- tion at that point (ignoring the background of thermal electrons), it can be seen that the electron density immediately outside the surface will vary from point to point according to the correspond- ing variation in the intensity of the infra-red image focused onto the surface. The infra-red. image has thus been replaced by an electron image. The electrons forming this image are accelerated towards the fluores- cent screen anode by an applied field of several thousand volts, and, except in the simplest forms of image converter, pass through some form of electron optical system in the process. The high voltage both limits the electron spread during the passage from cathode to anode and also gives a fluorescent Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 L I 1 1 I , . 111 I?II I 1 1 I 1 .111 I 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Fig. 3. Types of infra-red image converter Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 J iiI Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Fig.2. Prin- ciple of the image con- vertertube INFRA -RED RADIATION FROM OBJECT SEMI-TRANSPARENT ELECTRON FLUORESCENT PHOTO CA ODE PATHS SCREEN ANODE OBJECTIVE LENS INFRA-RED IMAGE image of high brightness. The ten- dency of electrons to follow helical paths about magnetic lines of force may be utilised to bring all the electrons leaving a point of the cathode to a. point focus on the screen irrespective of the original angle of emission of the electrons. Alternatively an electrostatic focus- ing system may be employed when the inverted infra-red image formed by a normal glass lens on the photo- cathode may be reproduced as an erect . image on the screen, and further the size of the latter image may to some extent be varied. It is an advantage to reduce the size - of the fluorescent image and so, by increasing the electron concentra- tion, obtain a brighter image on the screen. An electron optical reduc- tion to about one-half is the optimum. The principles of elec- tron optics and the analogy to normal . optics are well known, applications being widespread in both the field of electronics and, for example, electron microscopy. Use is made of the fact that electrons are deflected by an electrostatic field, tending to follow a path at right angles to the equipotential lines. Thus the electron lens formed by the field between two adjacent co-axial cylinders of different poten- tial has a similar focusing effect on a parallel bead of electrons as does a convex glass lens on a parallel beam of light. In the image con- verter tubes use is made, for the most part, of either cylindrical or aperture electrostatic lenses. Little use has been made of electro- magnetic lenses owing to the greater weight of such systems. After passing through the elec- tron optical system the electrons impinge on the fluorescent screen. Declassified in Part - Sanitized Copy Approved for Release ELECTRON OPTICAL SYSTEM VISIBLE IMAGE Various compounds are available for use as screen material, for example, zinc sulphide and wille- mite (zinc orthosilicate). The com- parative inertness of the latter to caesium contamination makes it particularly suitable, as does the colour (green) which corresponds roughly to the maximum sensitivity of the eye. Bombardment by high velocity electrons will, of course, cause the Screen to glow. The intensity of the light emitted by the fluores5ent material is proportional to the number of electrons striking it, and thus the variations in bright- ness from point to point of the fluorescent image will correspond to the variations in electron density in the electron image which, in turn, is directly related to the variations in intensity of the original infra-red-image. The latter has thus been transformed into an image visible to the eye. Historical Development The development of the image converter tube may be traced back to. the modification of the electron microscope employed, for example, by BriicheT in an investigation of metallic surfaces. The state of a surface is, to some extent, reflected in the electron emission under ultra-violet . irradiation. Briiche formed an image of a zinc surface in an plectron microscope using the electrons emitted by the zinc when illuminated with a mercury arc. Other workers used similar systems and it was a logical development to arrive at a device in which the elec- trons imaged on the fluorescent screen originated from an infra-red image focussed on a caesium photo- surface. In 1934 the first descrip- tion was published of a normal 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part L t I hi1..1.1 I I... - Sanitized Copy Approved for Release of which had earlier been advanced in the form of a patent (B.P. 326200) by Hoist, and his co-workers' of Messrs. Philips of Eindhoven. Their arrangement is of particular interest since it was chosen by the Admiralty in 1940 as the basis of the British Service image converter tube. The cylindrical glass envelope of the tube is fitted with two plane parallel windows, on one of which is deposited the photo-cathode, on the other the fluorescent screen. An accelerating potential of a few thousand volts is applied between anode and cathode which are separated by a distance of 2 cm. The photo-electrons emitted are accelerated along a straight path by the homogeneous electrostatic field and impinge on the fluorescent screen giving rise to a visible image bearing a one-to-one correspondence to the original infra-red image falling on the cathode. The defini- tion attainable with such a simple device is limited by the varying angles of emission of -the photo- electrons and by the spread due to mutual repulsion during passage to the screen. Coeterier and Teves later introduced improvements to the simple system, and experi- mented with alternative focusing devices. Also in 1934, Farnsworth pub- lished in America details of a so- called image dissector tube for television purposes.' In his tube a plane cathode was used with a uniform electrostatic field, together with a uniform magnetic field pro- duced by a solenoid wound around the outside of the tube. Since electrons travel in helical paths about the magnetic lines of force, all electrons leaving a point of the cathode, whether in a normal direc- tion or not, can be brought to a point focus in the final image plane by means of the magnetic field. It can be shown that the position of this focus is independent of the transverse velocity of the electrons on emission. In the image dis- sector tube, the whole electron image was deflected by means of additional magnetic coils, so that it fell point by point on the collecting anode after passing through an 0.015 in. aperture. This aperture 2011/12/28: CIA-RDP78-03300A001600020097-5 using a 4 in. cathode Farnsworth achieved a 210 line picture. Although developed as the basis of a television camera, in which appli- cation an electron multiplier was added to the anode, in order to examine the quality of the electron image the collecting anode may lw replaced by a fluorescent screen, when the system corresponds to that of Hoist with the addition of a long magnetic lens. The focusing effect of the long magnetic lens and the consequent improvement of definition led Coeterier and Teves to modify the Philips tube to include a uniform magnetic field." They also con- structed tubes in which use as made of a converging field that permitted an electron optical reduc- tion in image size. The in,preve- ment in definition resulting from the employment of focusing s.% stems was calculated by Henneherg nul Recknagel of A.E.G." Three systems were considered,. the uniform electrostatic field, the electrostatic field with uniform magnetic field added, and a short lens. Calculated circles of confusion in the three cases were: 2IE 2L V 41,s1 ? ? --- ? L ? L' (2V + 1) ' where 1 is the anode-cathode spacing, E, the velocity of emission of the photo-electrons, and U, the final velocity of the electrons. In the third formula V is the magni- fication, and L the cathode-lens centre spacing. With a factor E I' of the order of 10-4 a resolution .of 250 lines per in. (black plus white) might be expected from the simple electrostatic arrangement with a gain of about 100 times with the magnetic field. In practice E.M.I., Ltd., achieved a better figure and Coeterier and Teves with the long magnetic lens reported a resolving power many times better than with the simple system. In general, the theoretical gains with lens systems have not been obtained. Tubes employing more complex electron optical arrangements were soon investigated. Pohl" first described the use of a short lens between cathode and anode. Heimann" of the German Post Office Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28 : CIA-RDP78-03300A001600020097-5 Fig. 4. Early R.C.A. tube with electostatic fo- cusing. Laboratory developed a tube employing both magnetic and elec- trostatic focusing, the latter being carried out by two metal cylinders at different potentials. The electro- static lens inverted and reversed the fluorescent image relative to the infra-red image on the photo- cathode so that the orientation of the final image correspon& to that of the object. Schaffernicht" also produced a tube with combined electrostatic and magnetic lenses resulting in an electron optical reduction in image size, whereas Heimann's tube gave a magnified fluorescent image. The opaque cathode was deposited on a con- cave surface and the shape on the anode cylinder was such that a suit- able focusing effect was produced with a single applied voltage. Move- ment of the magnetic lens enabled the magnification to be varied. Cathode-anode spacing was 40 cm. and accelerating potentials up to 20,000 volts were applied. The original tube was not, in fact, an infra-red image converter, but employed an ultra-violet sensitive potassiu,m photo - surface. Von Ardenne" describes a similar arrangement in which the cylindrical electrostatic lens incorporated a resistance element in the form of a fine nickel spiral. It was claimed that the system resulted in reduced field emission owing to the lower potential gradient in the vicinity of the cathode. Early RCA Tubes ' In America, Zworykin and Morton," of R.C.A., reported on optical systems for image converter tubes using only electrostatic focus- ing. A curved cathode was used in conjunction with a series of focusing rings giving a compromise between the resistance lens and the single element (Fig. 4). Introduction of an aperture between lens system and anode enabled the magnification to be varied-. Morton and Ramberg" extended the investigations of this type of system using moveable anode and cathode. The R.C.A. team also described a tube employ- ing a uniform electrostatic field and a long magnetic lens." Continuing their work on image converters, Coeterier and Teves" developed a tube that could be used conveniently with an opaque photo- cathode and fluorescent screen. Use was made of a magnetic field to deflect the electrons through a right-angle. The radiation passed through the wall of a spherical glass bulb before falling on the cathode on the back wall of the bulb. The anode was mounted in the neck of the bulb at right angles to the cathode, both anode and cathode having a cylindrical magnet behind then'. An accelerating potential up to 10,000 volts was applied. An alternative arrangement was also used in which the positions of anode and cathode were reversed and a third electrode ?added in the form of a ring spaced a short distance from the cathode. The accelerat- ing voltage was applied between ring and cathode so that the deflect- ing and focusing action took place in a region free from any disturb- ing electrostatic field. A further development consisted of a double system in which the first anode con- sisted Of a caesium treated plate, the secondary electrons from which were in turn focused mi a fluorescent screen. In 1938, E.11LI., Ltd., produced a system employing a plane parallel cathode and anode with a long mag- netic lens, either in the form of a solenoid or a permanent magnet. npHaccified in Part - Sanitized Copy Approved for Release 2011/12/28 : CIA-RDP78-03300A001600020097-5 I I I 11111 1111 II LLIJL-111.1-1-1 1111,,...ILLL J11111-1.. L-11, 1, ILLll Ail Declassified in Part -Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 oasea on me original noist aesign. When the complexity of the Super- Emitron television camera is com- pared with the simplicity of the image converter, it is perhaps not surprising that within a month or two Dr. J. D. McGee, of E.M.I., was able to demonstrate a success- ful tube of the simple type. gl Mb were III LW- duced between cathode and anode. This resulted in a substantial improvement in sensitivity at the expense of resolution. It thus came about that, at the outbreak of war, some ,form of image converter tube was available in this country, in -America, in Holland, and in Germany. Fig. S. Comparison of definition of War-Time Development Consideration of the military applications of infra-red image con- verter tubes was commenced by the Admiralty in 1938. It soon became apparent that the devices already available were too cumbersome for many of the possible Service uses, although technically the perfor- mance was promising. In addition, production techniques were diffi- cult. After comparative tests of the available British, American and Dutch gear in 1940, it was decided that if useful quantities of equip- ment were to be available for Service use in an acceptable time, the l original system of Hoist offered the best possibilities. The -Philips team had given a number of reasons why the simple arrangement was undesirable?for example, the ,diffi- culty of working at high voltages with a small cathode-anode spacing, - optical retroaction between fluores- cent anode and the cathode, and the relatively low sensitivity of semi- transparent photo-surfaces, but it was considered that simplicity justi- fied a fuller investigation. Accord- ingly E.M.I. were asked to under- (left) and (right) A.E.G. tubes E.M.I. Tube The final arrangement of the tube is shown- in the photograph of?Fig. 3. The cylindrical Pyrex envelope, 5 cm. in diameter and 4 cm. in length, is fitted with plane end windows 2 mm. in thickness. On the inside surface of one of these is deposited the semi - transparent Ag-O-Cs layer, while the screen is mounted at a distance of 5 mm. from the photo-surface. The wile- mite is .deposited on a thin glass disk on which a platinum graticule has been sputtered to reduce screen resistance. The screen mounting is carried on tungsten wire supports sealed into the second window through which the fluorescent image is viewed. Cathode contact is made by a platinum paste seal at the edge of the window. To prevent caesium contamination of the willemite and to facilitate the deposition of -a uniform photo-surface, during the activation processes the screen lies with willemite surface downwards on the back window of the tube. Evaporation of both silver and caesium is carried out by electrical Declassified in Part - Sanitized Copy Approved for Release 2011/12/28 : CIA7RDP78-03300A001600020097-5 Declassified in Part Iii_11 _ - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 the tube itself. Otherwise the pro- cesses employed are similar to those normally used in the preparation of this type of layer. Care in design and manufacture resulted in a high level of insulation being maintained and potentials of between 3,000 and 7,000 volts can be applied to the tube without failure. The deposi- tion of the cathode on a plane glass surface without any associated metal parts helps in this respect by reducing cold emission. The final sensitivity of the semi-transparent photo-cathodes was comparable with the values normally obtained for opaque surfaces of the same material. Declassified in Part - RCA Tube Both the American and German tubes developed for military appli- cations employed electrostatic focusing. The R.C.A. tube has been described by Morton and Flory. Use is made of a four- component cylindrical lens in con- junction with a curved cathode, the actual curvature of the latter be;ng a compromise between light end electron optical considerations. The introduction of low potential com- ponents between cathode and main lens enables a sufficiently flat image plane to be obtained. The electron optical magnification is 4, which represents the best compromise between the brightness of the fluorescent image and the power and exit pupil of the viewing. lens required. Accelerating potential is 4,000-3,000 volts. The overall dimen- sion i of the tube are 11 cm. length and 4 cm. diameter. AEG Tube The production version of the A.E:G. tube manufactured for the German forces Used an aperture lens requiring a single intermediate potential. Again image distortion was reduced by using a curved cathode and electron optical magni- fication was about 4. A high.volt- age was applied to the tube (up to 17,000 volts) and the image bright- ness was further enhanced by the application of an aluminium layer to the back of the screen. Overall dimensions were 8 cm. by 16 cm., although a smaller version was com- mencing production at the end of the war; The photographs of Fig. 3 show the development of the various tubes . !vents and the relative sizes can be , judged from the scales. The simplicity of the British tube resulted in it being the first to become available in production quantities, whereas in the case of the A.E.G. tube, in spite of very much greater development effort, Service equipment had only reached the training stage in? the German army at the end of the war. Although the E.M.I. tube repre- sents the best compromise between .performance and complexity in the applications for which it was originally intended, namely the detection of sources such as infra- red homing beacons, the more com- plex focusing systems are an advan- tage where extended images are involved. Some gain in resolving i power s possible, using a lens system, but operationally the more important advantage, is the higher brightness level of the fluorescent image. The electron optical reduc- tion combined with a high power viewing lens is partly responsible for this gain. In addition, thy larger cathode-anode separation en- ables higher accelerating voltages to be used as in the case of the A.E.G. tithe. Comparative resolving powers of the British and German tubes are shown in Fig. 3. The uniform resolution over the whole screen of the former is apparent as is the high resolution at the centre of the screen in the case of the latter. Exposure time in photo- graphing the screen of the British ,tube was several times that p.111161.4 for the A.E.G. tube. References e. F., Prw.B.8., 155A. 664. 1936. Brooker. L. 0. S.. and Keyes, G. H.. ./. Frank. mat.. 219. 255, 1935. Case, T. W., Phr. Pee., 111, 269. 1920. 1-rhaeh, F.. Pearlman. D.. Hemmenglinger. H., ./.0.S.A.. 36. 372. 1946. ' Campbell. N. K.. Phil. Mew.. 6. 633. 192A. ? Hottenroth. G.. Ann. d. Phy,,.. 3o, 669. 1937. Bruehe. E.. Z. f. Phys.. $6. 446. 1933.? ? Hoist, 0., de Boer. J. H.. Teves, M.C.. and Veenemans. C. F.. PhyAfra. 1.297. 1934. ? Farnsworth. P. Fronk. mat.. 21,4. 411. 1934. Coeterier. F.. and Teves. M. I.. Phy.iro. 3, 964, 1936. " Fienneberg, IV.. and Reeknagel. A.. Z. f. tech. Phe., 16. 230. 1935. 12 Brodie. S.Kerzcr, Spring.-r. 'krill), 1934. " Heimann.' W., EST. 12. 494. 1936. 14 Schallernicht, W.. Z. f. Phgx.. 93, 762. 1935. " on Ardenne. M.. EST. 13. 230. 1936. " Zworykin. V. K.. and Morton, G. A.. ./.0.s.?4., 26. 161, 1936. - 1' Morton, G. A., and Ramberg, E.41.. Phfpgies, 745, 1936. " lams., H? Morton. 0. A., and Zworykin. V. K.. Priv. I.B.E., 27. 541, 1939. Coeterier. F., and TeVe4..M. 4.. PhyAirn. 4, 33.1.07 '? Morton. 0. A.. and Flory, L. E.. Elertroni,.. 19 Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I II 11 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ilL 11E11- I 1 I II I The Infra-Red Image Converter Tube By T. H. PRATT Infra-Red driving equipment mounted on a jeep Service Equipment ATYPICAL complete Naval re- ceiver of the type used for beacon detection is shown in the diagram. of Fig. 6. ,An aspheric plastic objective lens, used in conjunction with a plastic field, flattening component focuses infra-red radiation from a distant beacon on to the photo- cathode. An infra-red filter is included in the optical system. to reduce the effect of .stray illumina- tion such as moonlight. The field of view is 25?. The screen is viewed through a simple piano-convex eye lens set at a fixed focus of 1 dioptre. Presentation is, of course, inverted and reversed. In all applications it is necessary to have a source of infra-red radia- tion, and in this respect the high i efficiency n the one micron region of the tungsten filament lamp run- ning at normal colour temperature is convenient. The lamp must be screened with some material that absorbs visible light while transmit- ting infra-red radiation. Several filters were developed by the Admiralty and produced by firms such as Erinoids and B.I.P. Most filters consisted of a plastic base in which was incorporated a dyestuff with the required transmission characteristics. Polyvinyl alcohol, melamine, viscose and cellulose acetate are typical bases, while a polyazo direct dye such as naptha- lene leather carbon is a suitable dye. Typical transmission charac- teristics given in terms of Kodak , Wratten 87 are: Infra-red Transmission Visual (to a Ag-O-Cs Transmission ! photosurface) 25%0 75% 2% I 50% ? 20% Reprinted from Electronic Engineering Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 In most apPlications the trans- mission of some visible red light through the filter was permissible particularly in view Of the low sensi- tivity of the retina (except for the fovea) to red light. Data has been published on similar infra-red filters developed in America.'" Where high power transmitters were con- cerned and plastic-based filters un- suitable, use was made of a Chance- Pilkington pigmented glass. In applications involving the view- ing of any extended scene an erect presentation is obtained by the introduction of an erecting viewing system as shown in Fig. 7. This instrument, which is .a binocular, employs as objective a 11 in. focal length 1/1.9 projection lens, a cemented doublet erector and a 1 in. Ramsden eyepiece. A resolving power of 350 lines per in. on the cathode is obtained at one foot- candle level of target illumination, at whieli level the visual acuity of the eye is the limitation. In the case of these picture-forming appli- cations where the best resolution and brightest image are required, a voltage of about 6,500 volts is applied to the tube from a vibrator power unit. The weight of the receiver is about 7 lb. and the dimensions 16 in. by 6-1 in. by 5 in., the power unit with cold cathode rectifier weighing about 5 lb. and being S in. by 51 in. by 3 in. in size. It is interesting to compare the weights of the various British receivers with the equivalent Ger- man instrument, which weighed 27 lb. and was 21 in. long and 6 in. diameter, with a power unit of weight, 20 lb. and size 11 in. by 84 in. by 7 in. The relative sizes of the tubes themselves are shown in Fig. 8. Service Applications Service applications of image con- verter tubes fall into two distinct categories. The first is concerned with the detection of distant sources of infra-red radiation such as hom- ing beacons, the second with the observation of a scene illuminated TUBE ELECTRONS PLASTIC LENSES SIMPLE EYE LENS ZAMBONI PILES (1600 VOLTS EACH) 0 - 2 - GLASS PLATE INVISIBLE INFRA?RED RAYS DYED PERSPEX I.R. FILTER RASS END CAPS SPRPNG PAPER ELEMENTS EXONITE TUBE TIGHT PERSPEX CASE BALL BEARING GRAVITY SWITCH 3 ? INCHES 'AN ? ?,???,??,?????? Fig. 6 Infra?red receiver with enclosed Zamboni pile power unit for beacon detection with infra-red radiation. The earliest operational uses were of equipment of the first type in con- nection with special Naval opera- tions in the Mediterranean in 1041. The Naval applications were almost all concerned with homing aids. Thus, in all the X-craft operations, commencing with the attack on the Tirpitz in Alte Fjord and continu- ing with the operations in the Far East, the craft returned to parent vessels using an infra-red telescope to home on an infra-red beacon. Again, the small combined opera- tions pre-invasion reconnaissance parties that worked along the coast of France and North Africa and later in Malaya, used similar equip- ment to enable canoe parties to return to parent craft. Infra-red beacons or corner cube reflec- Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I LI 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I I ? 1 Ill I MULCT ILLLINONATID Or INTRA-RCP LIGHT OGJECTISIC LEN IRONY 515005 fLOONESCOO or TUNE %RUN INSTRON And. LING ?000 cam= CONTACT RING ELI STREAM MOM CONTACT RING h.. LI o Fig. 7. Infra?red receiver for viewing tors served to mark beach ren- dezvous for the collection of person- nel operating inside enemy territory. R.A.F. applications were con- cerned with recognition systems. In 1942, when German intruder air- craft were mixing with our return- ing night bombers, night fighters were equipped with an infra-red receiver and a coded infra-red beacon was attached to the tails of our bombers. Before carrying cut an attack, the fighter pilot glanced in his telescope and if the plane ahead was British the appropriate signal would be seen. Later in 1944, a similar device was fitted to rear turrets of night bombers to enable rear gunners to dift,m-entiate between members of the bomber stream and German night fighters, the former being fitted -witn suit- able beacons shining forward. The main Army application was a night vehicle driving aid, using normal headlamps covered with infra-red filters in conjunction with the binocular receiver for viewing the terrain ahead. This arrange- ment enabled convoys of armoured or supply vehicles to move at night over roads or open country at speeds about equal to normal daytime convoy speeds without danger from air observation. The eqi,ipment was fitted as a navigational aid on amphibious vehicles used in ferry- ing 'troops across the Rhine dui ing the main crossing. The Army also possessed quantities of simple KT. GLAND TING LENS CE LOTS NEATEN SINGING illuminated with infra-red radiation receivers for use as countermeasures in the event of enemy use of infra- red. Research and Commercial Applications The first image converter tubes were not, of course, developed with a view to military applications. As has already been stated, Brche was concerned with the examination of the surface of a metal plate using the electrons emitted under ultra- violet illumination to form a fluores- cent image of the surface. Similarly Kluge used the form ef tube developed by Heimann for an investigation of semi-transparent photo - surfaces. The application to spectroscopy" is immediately apparent since the tube can Ise used for the direct observation of emis- sion or absorption phenomena out to 1.3 microns. During the ?A ar an image converter tube attachment was made for the N.P.L. spectro- meter to facilitate the direct measurement at one TA icron of the refractive indices of various Inaterials used in the optical com- ponents of infra-red receivers. The R.C.A. workers described the use of their tube in conjunction with a microscope for the observation of biological and botanical specimens in the infra-red.' Useful information can be obtained on animal behaviour in the dark using infra-red viewing equip- ment. During the war this was applied in connection with an investigation on the sensitisation of the retina to infra-red radiation. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I II._ .1 I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28 : CIA-RDP78-03300A001600020097-5 R.C.A. 0 I ? 11111[111 INCHES More recently Colonial Office field team's have used instruments for obseiving rats in the dark in the course of an investigation of the spreading of scrub typhus in the Far East, and for observing the behaviour of malaria-carrying mos- quitoes in the dark over water. Although the wavelengths to which the image converter tubes are sensi- tive are too short to be preferen- tially .transmitted through natural scattering media such as fog, where ? scattering particles are sufficiently . small, some advantage can be gainef by using an infra-red receiver. Thus descriptions have been given'" of the applieation of the converter tubes to ophthalmic problems connected with certain types of corneal opacity. Infra-red aids have immediate application to the production of photographic materials. Simple manipulative work, time studies and inspection are all made in- estimably easier using the simplest devices. The use of optical pyro- metric methods at temperatures below visible red heat is made possible by the use of the image converter tube. Many of these applications are only now being investigated fully, but there is no doubt that the. return from the war- time effort will be considerable in the fields of research and industry. References E.g. Elementary Lessons in Electricity and Magnetism, Silvanus Thompson. p. 180. " Mout. E. R., Amon. W. F. Shepherd, R. (1., Thomas, A., West, ('. 1).. and Land, E. H., ./.0.S.A., 36, 460, 1946. " Shenk. J. R.. Hodge. E. S.. Morris. R. J.. Pickett, E. E., and Brode, W. R.. J.O.S.A., 36,569,1946. " Eluge. W., Z.! Phys., 93, 789, 1935. Schaffernicht, W.. Z. f. tech. Phys., 17, 596, 1936. Vasko. and Peleska, Ophth. July 1947. 2' Kelly, T. S-B, B. J. Ophlh., July 1948. ? A.E.G. Fig. 8 Relative sizes of British,American and German tubes. T4 '..*...-'..."'.'....r' "''.......01."...... 0,0???...... ARMY PLANS TO BUY 6,918 `SNIPERSCOPES' WASHINGTON, ?The "night eyes" of the rifleman, the .1' electronic "sniperscope" that is credited with causing 30 per cent , of all enemy casualties in the Oki- nawa campaign, is being made a / standard item of Army equipment. t Army sources disclosed today ! that !the field forces were so im- pressed with the efficacy of the auxiliary weapon that enables the r infantryman to "see" the enemy jthrough darkness that units in all the krmy's ten divisions would be equipped with the device. Included in the Army's budget requests now before Congress is an 1 $8,654,418 item for the purchase of 4 6,918 "sniperscopes" at a cost of $1,251 each. How many of the / de- Vir..e7- are already in use is con- siuered secret information. The "sniperscope" consists of an electronic telescope that is mount- ed on the standard Army .30-cali- bre carbine. Wiring runs from a portable power pack carried in a t harnessed knapsack on the soldier's back. Operating under cover of dark- ness, the rifleman points the "sniperscope" and his gun sights toward. a spot whence a sound has come. By switching on an infra- red spotlight, he makes rays scan the territory. These are reflected from the target, picked up by the telescope and transformed into an ? image across the sights of the rifle- man. .141"..4?41100.6 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I. IL I I I . 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I IhoWIVIUNAIN I SNOOPERSCOPE SUPPLIES We have a limited quantity of the following supplies for the construction of snooperscope out- fits. All material is in new condition and carries our - warranty to be free of defects in material or work- manship. SNOOPERSCOPE TUBE SUPPLY LIMITED? These are government released British snooperseope tubes which employ the spe- cial simplified design, making construction of experimental models possible with simple hand tools. Highly sen- sitive, they provide a SEE IN THE DARK bright clear image of invisible infra red rays. Also useful as infraared (invisible) photocells. With complete hookup instructions. Special Price $14.95. SNOOPER5COPE BOOK Shows in detail Army and Navy snooperscopes, sniperscopes and infra red telescopes. One of the few books of its kind. Circuit hookups for practical instruments are given. Special Price $1.50. NEAR INFRA RED FILTER?An efficient filter that fits directly on the front of the image converter tube. High quality glass type with metal mounting clasp. Clasp also serves as the graphite contactor (?lead). Your Price 1.50 ENGRAVERS GLASS?Has a ground lens for clear sharp images. Focal length three inches. Perfect as either a front or rear view lens. Plastic housing prevents elec- tric shock. Price 1.25 IGNITION COIL?This miniature high volt. age coil provides high output for snooper- scope operation. Has built in condenser for extra power. Special $2.2f FILTERS?Infra red filter glass. Manufac- tured by a famous glass house to exacting specifications. Transmitts over 80% of the infra red rays but appears as a total black for visible light. 3 x 3 inch square Price $2.53 6 x 6 inch square Prise $4.00 PLASTIC FILTERS Infra red plastic filters are also available at ISO each for small test square and 75? each for 6 x 6 inch squares. Permits passage of heat rays but appears black to visible light. Buy several at this price while the supply lasts. 942 Kings Highway, Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 r-- _1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 /MAJ. I IVPIAL INFRA RED SNOOPERSCOPE SUPPLIES The following -additional supplies were made available due to many requests for materials with which to construct experimental infra red instruments and snooperscopes. Sales of any item Is limited to stock now On hand. New materials arriving daily. POWER SUPPLY KIT?Provides the proper voltages for image converter tubes. Operates off three ordinary flashlight cells. Completely portable Every part including case, rectifier tube and batteries is supplied. Your price $14.93 LENSES?These lenses are of top quality materials and intended for use where the best possible results are required. We make these lenses available only to our customers which have purchased our snooperscope tubes and send us there written assurance that they have been success- ful with the circuits and the simple lenses and now feel prepared to construct the finer models. SNOOPERSCOPE LENS ? Original Navy Snooperscope lens. Schmidt optical system type Government cost $134.00. Very fast speed F 1.0 Our Price $12.50 Mounted Optical Lens. High quality lens of fast speed. Excellent for image tubes. Priced at a fraction of their original cost. Price $8.50 HOW TO ORDER IMPORTANT NOTICE Sales are subject to the following conditions; all prices in this catalogue is subject to change without notice. Most material is shipped postpaid unless otherwise noted. Test instruments are not postpaid and postage fees should be included with your order. We will insure all material unless instructed other wise. In the event of damage in transit, write us immediately giving details o f the damage and insurance numbers on package. If for any reason you wish to return material write us first cjivina all detai's and we will send you ship ping instructions. POSITIVELY NO MATERIAL ACCEPTED FOR RETURN UNTIL WE HAVE BEEN NOTIFIED AND YOU HAVE OUR SHIPPING INSTRUCTIONS. Merchandise made to customers own specifications cannot be returned. Foreign orders should add 10% to cover costs of additional packing, postage and con sular expenses. No C.O.D. orders accepted unless accompanied by a deposit of 25%, balance wil be shipped C.O.D. This catalogue covers only a few of the items that we carry. We carry hundreds of items not listed on these pages write us on your requirements. Prompt efficient service is rendered on all orders regard'ess of size. Our lab ? oratory is engaged in the construction of scientific instruments of every de- scription. We are always very happy to send our free quotations on equIpm ent built to order. PRECISE MEASUREMENTS COMPANY 942 Kings Highway, Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I I 1 I .iIU 1..1.1 I I I I II is 1 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 \otaall.1.1,111,/ Generates short ultraviolet 0111//////' radiation (1849A Se 2537A) which produces ozone by converting !"..?.. the oxygen of the air (02) into ozone (03). Useful for fluores- cent 8,7, phosphorescent ma- terials. Uses only 4 watts of power. Lamp supplied with 111 TV socket and instructions. Your Price $1.95 *freiyaranTrivr BLACKLIGHT LAMP Special Argon filled bulb pro- vides a good source of violet and ultraviolet light for blackout experiments and fluorescent materials. Very convenient as it screws into any standard lamp socket. Clearance Price 45c 10 for $4.00 FLUORESCENT PIGMENTS Brightest glowing, concentrated phosphors, available in many colors. Red, White, Blue, Green, Yellow and Orange. Mix with clear lacquer for painting. SAMPLE SIZE (specify color) 35c each COMPLETE SAMPLE KIT (6 colors) $1.75 ea. One Ounce Bottles (specify color) 50c each AMAZING BLACK LIGHTS Powerful 250 watt Ultra Violet Bulb is very convenient to use as it screws into any standard lamp socket. Provides black light which causes many things to glow. Excellent for experimenting with fluorescent and phosphorescent pigments. Lamp is designed for intermittent duty only. Price $1,95 PHOSPHORESCENT PIGMENTS. Expose these pigments to sunlight or ultra violet light or ordinary light bulbs. Pigments wil then remain glowing for sometime afterward in total darkness. Comes in powder form mix with clear lacquer for painting. Available in three colors: yellow-orange, green and blue. One ounce bottle 600 1/2 pound bottle $2.75 SAMPLE KIT. Consists of one of each of the above coolrs (three bottles). Price 98 cents. SPECIAL PHOSPHORS ULTRA VIOLET Energize this phosphor with short wave ultra violet light (approx. 2500 A) and it will convert it to the near ultra violet of approx. 4000 A. This phosphor when used with many types of black lights will increase the ultra violet out- put considerably. Use as a coating on the out- side of photocells to change their response. Sample 500 1 or. Bottle $1 $12.50 lb. SHORT WAVE Responds to wavelength of 2500 A or shorter. Will detect alpha particles, electron beams, etc. Lights up a bright green. Sample 50? $12.50 lb. 1 oz. Bottle $1 TWO COLOR The beautiful colors that these concentrated phosphors will glow depend upon the wave- length. Different types of blacklights will make it change color. Red and green or yellow and green are available. Sample 500 $12.50 lb. 1 bz. Bottle $1 INFRA RED EMITTING This unusual material has the property of emit- ting far red and infra red radiation when ex- cited with ultra violet light. Useful as infra red light sources, experimental fluorescent lights, etc. Price $4 oz. INFRA RED RESPONSIVE A specially prepared material with rare earth activators. Charge with ultra violet light or alpha particles, phosphor then stores this en- ergy and releases it in the form of light when infra red radiation is present. Also useful as temperature indicators. Price $4 oz ULTRA VIOLET FILTERS Glass type. Filters out most of the visible light while allowing free passage of ultra violet. Very handy for experimenting with fluorescent phosphors. 3 x 3 inch square Price $2.55 6 x 6 inch square Prise $4.00 PRECISE MEASUREMENTS COMPANY 942 Kinds Hialiwoy. Brooklyn 23. New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I Ii .1 t I- - s Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ULTRA VIOLET GENERATOR TRIPOD MAGNIFIER Lenses are ground for better clearity. Has high magnification power and is adjustable by means of a screw thread. Very popular item with ex- perimenters, colleges and research labs. Your Price $1.75 MICRO CIRCLE CUTTER FOR METAL ? WOOD ? PLASTICS ? Micrometer type size control ? Extra heavy duty beam ? Special bea* locking mechanism Al all Dealers Model Type Size Pace 1 Round shank 4 inch $5.00 1 Square shank 4 inch 5.00 5 Round shank 6 inch 7.50 PRECISE COMPANY, 942 Kings Highway BROOKLYN 23, NEW YORK VAN DE GRAAF MACHINE Produces voltages between 10 KV and 100 KV. Well designed for long life and efficient opera- tion. Under favorable weather conditions sparks up to three. inches can be obtained. Many in- teresting high voltage experiments can be per- formed with this miniature generator. Price $15.00 12537 Angstrom units I Consists of a miniature mercury vapor lamp in beautiful plastic housing. Lamp constructed of special glasses for the efficient production of ultra violet radiation. Built in ballasts for long life and good operation. Wavelength changer filter instantly changes the output wavelengths to the 3500 A band thus enabling complete coverage of the most important bands. Your Price $9.95 ADDITIONAL WAVELENGTH CHANGER FILTERS available in blue, green, yellow, orange and red. Price $1 each INFRA RED WAVELENGTH CHANGER FILTERS Converts your ultra violet generator to an infra red generator. Price $1.50 each NIGHT VISION GOGGLES.?These goggles were used by the Army for nighttime vision purposes. All are new and in indivi. dual cloth case. Price $1.00 each INFRARED FILM. A fortunate purchase of infrared film allows us to offer this material at an almost unbelievable low price. Film is surplus aerial, cameral stock which is outdated. We have tested this film and find that good results can still be obtained. Speed rating is 50 with red filter. Comes in vacuum sealed can in rolls 51/2 inches wide by 26 feet long. Your Price $1.23 CESIUM VAPOR LAMPS These lamps produce nearly a pure output of infra red light of 8521 and 8943 Angstrom units. They are the most efficient source of infra red at these wavelengths and are about 700% more efficient than the Tung- stem filament lamp. These lamps may be modulated up to 10,000 cycles with voice or code. Only a very limited quantity of these lamps are available as they were used in Navy projects. Lamps. are rated at 90 Watts at 5.5 amperes. Pries $30.00 sash. Declassified in Pa - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 11 I hid I I II i.t Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 ---? AVAI This spectroscope is suitable for medical research, analytical work and general purposes in physical laboratories. The dispersion is 340 and the slit is provided with an adjustment for varying the width. A graduated drum by which the spectrum can be moved across the field, used in conjunction with an indicator enables readings to be taken. This drum is divided intolOOdivisions, which are arbitrary, but which can be calibrated if desired by the user. An adjustment is fitted for accurately focussing the spectrum. A table stand to carry the spectroscope can be supplied. Provision is afforded for the attachment of a test tube holder and also a cylindrical lens attachment. This latter is a very useful accessory, especially when working with a small or weak source of light, as it concentrates an image of the light source on the slit: No. 2425. Reading spectroscope, in case ? $69.50 Nos. 2458 and 2459 PRISM SPECTROSCOPES. For certain purposes the prismatic type of spectroscope is advantageous, as it passes very much more light than the diffraction type. The dispersion, however, is less, and as explained in the opening description (page 1), gives a smaller relative dispersion at the red end of the spectrum compared with that at the blue end. This model employs a train of five prisms giving a dispersion of 100. An adjustment is provided to the slit for varying the width ; there is also an adjustment for accurately focussing the spectrum. The instrunaent can be attached to a table stand, and provision is made for the attachment of a test tube holder, etc. No. 2459 has the addition of a comparison prism. This enables the spectra from two sources to be examined simultaneously. No. 2458. Prism spectroscope, in case ? ? 49.50 No. 2459. Prism spectroscope, in case ? ? 52.95 PRECISE MEASUREMENTS COMPANY Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 For taking direct readings in wavelengths where extreme accuracy is not required, this instrument will be found extremely satisfactory. The dispersion given is 10?. The scale giving readings in wavelengths ie viewed in the same field as the spectrum, each division of the scale representing 100 A. The slit is adjustable and the necessary focussing adjustments are provided. There is also an adjustment to the scale so that it can be set accurately in relation to the spectrum. Provision for attaching to a table stand is provided and such accessories as test tube holder and cylindrical lens attachment can be employed. No. 2523 has the addition of a comparison prism. This enables the spectrum being examined to be compared with a standard or other source. No. 2522. Prism spectroscope, in case .. ?$$9849?3500 No. 2523. Prism spectroscope, in case .. ACCESSORIES TABLE STAND. This stand is strongly made, the spread of the feet is arranged to ensure that the stand is rigid. The fitting carrying the spectroscope has adjustments for raising and lowering, also for tilting, both adjustments being provided with clamps. It is suitable for spectroscopes Nos. 2447, 2449, 2425, 2426, 3500, 2458, 2459, 2522, 2523. 2435 and 2438. No. 2437. Table stand . . . . $995 CYLINDRICAL LENS ATTACHMENT. When small or weak sources of light are being examined, this attachment is found extremely useful, as it produces an extended image of the light source on the slit. It can be used in con- junction with Nos. 2447, 2449, 2425, 2426, 3500, 2458, 2459, 2522 and 2523. No. 2496. Cylindrical lens $950 attachment . . CYLINDRICAL LENS ATTACHMENT. This attachment is on the same principle as No. 2496, but is made in quartz so that it can be used in conjunction with spectroscopes Nos. 2435 and 2438. No. 2436. Cylindrical lens attachment ? . ? . ? ? $1 095 TEST TUBE HOLDER. This holder is a secure method of supporting a test tube and enables a number of tubes to be easily and quickly changed. It is attached to the spectroscope by two clamping screws and can be used on models Nos. 2447, 2449, 2425, 2426, 2458, 2459, 2522 and 2523. No. 2697. Test tube holder . .. $2.95 , PRECISE MEASUREMENTS COMPANY Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I pl Ilii LfLL L Declass fied in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 IlUb. GY.30 UI.. 1 MA 1 Declassified This is a compact spectroscope for the examination of the ultra violet spectrum Its general design can be seen by the illustration. It has an accurately made slit, fixed or adjustable, through which the light passes on to a quartz prism, 'forming a spectrum upon a fluorescent screen. The spectrum thus formed is examined by an eyepiece, giving a magnified image. The eyepiece is provided with a focussing motion and an. eye cup to exclude extraneous light. Beside the spectrum in the field of view is an illuminated scale, divided in Angstrom units, so that the wavelength of any portion of the spectrum under observation can be deter- mined. The scale appears With illuminated lines and figures upon a black background, the illumination being obtained through a window in the instrument by means of the visible light in the light source under examination, so that no add- itional source of light for illuminating the scale is necessary. The spectrum included in the field of view is from 2,000 A. to 4,500 A.,. which includes a small portion of the visible light. The instrument can be conveniently used in the hand, table stand can be supplied if required This spectroscope has been designed with a view to giving a particularly brilliant Spectrum, thus rendering it easily used in daylight and with the same ease as a spectroscope for visual light. It is, therefore, specially useful for rapid Spa, k spectrum of zinc determinations in electromedical and similar establishments and cadmium as seen in and for industrial workshop use, when a more complicated eyepiece of speciroscope. apparatus is inconvenient to use. When a small source of light is being examined, the brilliancy of the spectrum Can be increased by using a cylindrical lens attachment (page 12), thus making it unnecessary to hold the spectroscope close to the source of light. No. 2435. ultra violet spectroscope, in case .. . . 109.50 No, 2438. - ultra violet spectroscope with adjustable slit, in case .. 114.50 PRECISE MEASUREMENTS COMPANY Rrnnlelvn v?..L in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 1 I Declassified in Part - Sanitized Copy Approved for Release,2011/12/28 : CIA-RDP78-03300A001600020097-5 This is a very convenient pocket spectroscope for general purposes and students, use, having a dispersion of 200. The slit is of a fixed width, protected by a glass cover to prevent dust from entering. An adjustment for accurately focussing the spectrum is provided. No. 2444. Pocket spectroscope, in case the menlo 7eueveetem battery powered, in this pro? fessional instrument case with six different speci- men -holding end caps ; choice of long or short wave operation ? complete: $49.50. Fluoretor for II5-v 60-cycle power: $42.00. Inter- changeable lamp for 'alternate wavelength: $20.00. Our Price $12.50 "'hobbles The Fluoretor makes many hobbies more enjoyable. Mineral collectors use it in the discovery of fluorescent specimens in the field and to enhance displays of their collections. Philatelists :identify papers, cancella- tions, ink variations, stir- prints and Eorgeries. ' chemical testing Both quantitative and ? qualitative chemical checks are made in or out of the laboratory with light, convenient Fluoretor. Inval- uable in smaller labora- tories. Long or short wave, choice of battery or electric outlet power. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I I I I I IL I-I.1 II II I. I I 111 I u Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Rush Order Blank Name Date Street Address or Rural Route Box No Town Zone State QUANTITY DESCRIPTION PRICE PER AMOUNT MINIMUM ORDER 50 CENTS. MATERIAL IS SHIPPED POSTPAID TO ANY POINT IN U. S. A. UNLESS MARKED OTHERWISE. CANADIAN AND FOREIGN ORDERS ADD 10% TO COVER COST OF ADDITIONAL PACKING. REMIT BY MONEY ORDER OR POSTAL NOTES. PRECISE MEASUREMENTS COMPANY 942 Kings Highway, Brooklyn 23, New York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 I I I I-- Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Rush Order Blank Name Date Street Address or Rural Route Box No Town Zone State QUANTITY DESCRIPTION PRICE PER AMOUNT MINIMUM ORDER 50 CENTS. MATERIAL IS SHIPPED POSTPAID TO ANY POINT IN U. S. A. UNLESS MARKED OTHERWISE. CANADIAN AND FOREIGN ORDERS ADD 10% TO COVER COST OF ADDITIONAL PACKING. REMIT BY MONEY ORDER OR POSTAL NOTES. PRECISE MEASUREMENTS COMPANY 942 Kings Highway, Brooklyn 23, New. York Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 VIBRATOR ANSFORNR.ERS IGNITION COIL?This miniature high volt- age coil provides high output for snooper- scope operation. Has built in condenser for extra power. GE OZONE LAMP Generates short ultraviolet radiation (1849A & 2537A) which produces ozone by converting the oxygen of the air (02) into ozone (0l). Useful for fluores- cent & phosphorescent ma- terials. Uses only 4 watts of power. Lamp supplied with socket and instructions. Your Price $1.95 FLUORESCENT PIGMENTS Brightest glowing, concentrated phosphors, avail- able in many colors. Red, White, Blue, Green, Yel- low and Orange. Mix with clear lacquer for painting. SAMPLE SIZE (specify color) 15c each COMPLETE SAMPLE KIT (6 colors) $1.75 each Oar Ounce Bottles (opacity color) 511c each No. 2444 POCKET DIFFRACTION SPECTROSCOPE This is a very convenient pocket spectro- scope for general purposes and students' use, having. a dispersion of 20". The slit is of a fixed width, protected by a glass cover to prevent dust from entering. An adjustment tor accurately focussing the spectrum is pro- vided. Not a toy but a scientific instrument. Available for the first time in small size_ No. 2444. Pocket spectroscope, in leather case. Special 412.50 (while they last) "Little Wonder" RADIO RECEIVING SET Compact in size but big in results. The open type detector permits adjust- ments to be made to the finest degree. This set includes the Philmore Super- sensitive Crystal which assures quick results when "looking" for a station, because the entire surface of the crys- tal is sensitive. Cat. No. 7000 Price $1.75 Plus Federal Excise Tax HIGH VOLTAGE TRANSFORMER Pt-i. 115 v. 50-60 ey. ;lee. 4500V. 2MA o2: 2,5v 9 $795 Postpaid in U.S.A. "Supertone" RADIO RECEIVING SET A remarkable Radio Receiving Set built to give everlasting service.. This set will bring in broadcasting loud and clear without distortion or noises. The Supertone Crystal Set is equipped with a Rhilmore Supersensitive Crys- tal which will give excellent results over an indefinite period of time. Cat. No. 7001 Price $2.25 Plus Federal Excise Tax NIGHT VISION GOGGLES.?These goggles were used by the Army for nighttime vision purposes. All are new and in indivi- dual cloth case. Price $1.00 each AERIAL KIT A complete kit of parts for assembly of a profes- sional antenna. Attrac- tively packaged in a multi-colored display box. 1 coil 7-26-50 ft. stranded copper aerial wire. 1 coil 25 ft. rubber coy. ere. lead-in wire. 1 Ground Clamp. 1 Lead-in-strip. 2 Porcelain insulators, 2 Nail-it knobs. 1 Instruction sheet. Cat. No. 2103 Price $1.50 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 VIBRATOR ANSFORNR.ERS IGNITION COIL?This miniature high volt- age coil provides high output for snooper- scope operation. Has built in condenser for extra power. GE OZONE LAMP Generates short ultraviolet radiation (1849A & 2537A) which produces ozone by converting the oxygen of the air (02) into ozone (0l). Useful for fluores- cent & phosphorescent ma- terials. Uses only 4 watts of power. Lamp supplied with socket and instructions. Your Price $1.95 FLUORESCENT PIGMENTS Brightest glowing, concentrated phosphors, avail- able in many colors. Red, White, Blue, Green, Yel- low and Orange. Mix with clear lacquer for painting. SAMPLE SIZE (specify color) 15c each COMPLETE SAMPLE KIT (6 colors) $1.75 each Oar Ounce Bottles (opacity color) 511c each No. 2444 POCKET DIFFRACTION SPECTROSCOPE This is a very convenient pocket spectro- scope for general purposes and students' use, having. a dispersion of 20". The slit is of a fixed width, protected by a glass cover to prevent dust from entering. An adjustment tor accurately focussing the spectrum is pro- vided. Not a toy but a scientific instrument. Available for the first time in small size_ No. 2444. Pocket spectroscope, in leather case. Special 412.50 (while they last) "Little Wonder" RADIO RECEIVING SET Compact in size but big in results. The open type detector permits adjust- ments to be made to the finest degree. This set includes the Philmore Super- sensitive Crystal which assures quick results when "looking" for a station, because the entire surface of the crys- tal is sensitive. Cat. No. 7000 Price $1.75 Plus Federal Excise Tax HIGH VOLTAGE TRANSFORMER Pt-i. 115 v. 50-60 ey. ;lee. 4500V. 2MA o2: 2,5v 9 $795 Postpaid in U.S.A. "Supertone" RADIO RECEIVING SET A remarkable Radio Receiving Set built to give everlasting service.. This set will bring in broadcasting loud and clear without distortion or noises. The Supertone Crystal Set is equipped with a Rhilmore Supersensitive Crys- tal which will give excellent results over an indefinite period of time. Cat. No. 7001 Price $2.25 Plus Federal Excise Tax NIGHT VISION GOGGLES.?These goggles were used by the Army for nighttime vision purposes. All are new and in indivi- dual cloth case. Price $1.00 each AERIAL KIT A complete kit of parts for assembly of a profes- sional antenna. Attrac- tively packaged in a multi-colored display box. 1 coil 7-26-50 ft. stranded copper aerial wire. 1 coil 25 ft. rubber coy. ere. lead-in wire. 1 Ground Clamp. 1 Lead-in-strip. 2 Porcelain insulators, 2 Nail-it knobs. 1 Instruction sheet. Cat. No. 2103 Price $1.50 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Assembly of the tripod is strairhtforward. The longer set of le gs engage the set of holes farthest apart. to form a point at the lower end. The kegs should be unfolded BATTER/. CHARGER AND BATTERIES When a substantial portion of the ampere hour capacity of the batteries has been discharged, the batteries should be recharged. To doso remove the front cover and plug the line cord intba 115 AC line. ( A link is provided in case 041230 VAC is available) Turn the function switch to position "C" and depress the charge start switch button which is located near the modulation indicator light. The indicator light will be lit and will remain lit as long as the chnrger is in operation. It may be necessary to depress the start button for several seconds due to capacity in the relay circuit.of the charger. If the charFcr fails to remain in operation upon relaease of the start button after several attempts this indicates that the batteries are very close to a fully charged condition. The charger will cut off automatically when the battery potential has risen to a fully charged condition. It requires approximately 12 to 14 hours to charge a set of r hi ar ccmpLetely The equipment should be kept in an upright position while the charger is in pperation if this is possible. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 As a result of some field testing of the equipment by the manufacturer, the following procedures are recommended for establishing donta'ct between two units. Since the viewers are not as effective in daylight as they are in darkness, initial familiarization will probably best be done at night at moderate ranges( two or three miles) It is assumed that the watches of the operators have been synchronized and that some particular time has been designated for the establishment of contact. NIGHT OPERATION 1. Both units are assembled for operation, the legs are attached to the table and the unit is mounted in the yoke. 2. The scan mechanism is disabled by running through a complete scan ( three sweeps to the left alternated with three sweeps to the right) In this condition, the instrIonnt does not change its angle of elevation with further horizontal scanning. 3. The angle of elevation is then set approximately and the wing nuts at the side of the unit are tightened to the yoke. The azimuth setting is adjusted so that sweeping will cover the area in which the other unit is believed to be located. 4. The Function Switch is turned to "F". 5. The R-T Swittivis turned to R. 6. The viewer charging switch, located just to the right of the eyepiece is depressed, and held depressed until li hts in the vicinity form sharp green points on the viewer screen, or if there are no lights moon , or sometimes even stars wifl suffices Keep- the switch derressed for 5 to 10 seconds. 7, At the desir7nated time onerator A turns his R-T switch to T and slowly scans the area in 1.,q}nich operator B is supPosed to be located. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Operator A also watches through his viewer for the appearance of the light of operator B, and continues scanning until this light appears. 8. Operator B watches through his jewer for a flashing light. The duration of the flash will denend on the sneed of A's sweeping, and the brightness will depend on the accuracy of alignment as well as range. At the specified initial test range of 2 or 3 miles, the light will probably be brighter thn any other light visible. 9. When B sees what he thinks is the light of A, he turns his unit so that the light falls within the reticle of his viewer. (With some tubes, the background brightness is so low that the reticle will be seen only with difficulty. In this case the image is brour-ht to the center of the screen as judged by the onerator) The azimuth setting is then carefully adjusted for maximum loudness of the 1000 cycle note that will be heard with each flash. Because of the nature of the source (i.e. not steady) this adjustment will probably not be exact, but will probably be sufficiently close. 10. When the adjustment (9.) has been completed, B turns his R-T Switch to T. 11. When B comnletes step (10.) A will see the light of B in the viewer of the A unit. When this light anears, he turns his 7Z-T switch to R and adjusts his azimuth setting for maximum loudness of the 1000 cycle tone bein- transmitted bY B. Since the B transmitter is fixed, A can make this adjustment with considerable accuracy. He also will "touch up" the elevation adjustment, again for maximum loudness of B's signal. 12. When A has completed step (11.) he turns his R-T switch to T. He again watches his viewer for the apearance of B's 13. B, when he sees A's light according to (12.) turns his R-T switch Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 to R, and makes final touch-un adjustments to his dizimuth and elevation settings. This time B has a steady tone on which to align, and so can do this alignment with accuracy. 14. When B has completed his alignment, he turns his function switch to OP, and his R-T switch to T, and then starts communication. 15. When A sees B'S lamp in (14) he turas his R-T switch to R and his Function switch to OP. After the initial alignment has been completed, the viewers need not be used, however it has been found that if they are used, "Break-in" operation is possible. That is, when the person who is transmitting sees the lamp of the other in his viewer, he knous that he should go into the R condition. DAYTIME OPERATION The procedure for the first seven steps are as above, except that ?robabts, because of the high brightness of the landscape, AAwill not be able to see the light of operator B at any time. The siewerris still useful if the collimation of it wibh the unit is known since the unit can now be quite accurately aimed at any reference landmarks that may be known. 8. During the course of his scanning, operator A must interrupt the transmission to listen for B. It is suggested that after each minute or two of scanning with the R-T Switch in the T position, operator A should make a complete scan with the R-T switch in the R position. 9. Operator B leaves his R*T switch in the R position, and slowly, very much more slowly than A, scans the area in which A is believed to be located. If A completes a horizontal scan in three or four seconds or less, a scan by B should take not less than 30 seconds. Actually the B scan should consist of a series of finite steps, each about 1/3 or less of the diameter of the reticle. Obviously, if B knows the Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 location of A quite accurately, he will have a smaller range of scan to make. 9a. If B does not hear A's tone after two scans, he should change the elevation by approximately 1/3 the height of the reticle and repeat step 9 until the B unit is aimed for the best loudness of the A tone. 10. B locks his unit and turns his R-T Switch to T.X074), At the end of each minute for three minutes he listens, i.e. Turns the R-T switch to R and listens for a steady tone signal ( as compared to the pulses of the 1000 cycle tone heard during the A scan() 11. If A hears a tonefom B's transmitter on one of his "listening scans", A immediately aligns his instrument for loudest signal. This will involve both azimuth and elevation fine adliustment. When his unit is aligned, A turns his R-T Switch to T. Eat. vAthAO tLereAr A turns lANe su3rtcv% 4.0 it +or 10 -tC Secon45. 12. When B hears a steady fone from A, he makes fine adjustments on his azimuth and elevation settings for maximum loudness of signal. The signal will be turned off after some period of time which should not exceed 1 minute. When the signal frank ceases, B turns his R-T switch to T and his function switch to OF, and starts communication. 13. When A hears voice modulation from B during his listening period as mentioned in (it) he turns his function switch to OF, and continues communication. Since the viewers are not able to distinguish the transmitter from the background during daytime operation, Break-in operation is not possible, but each oneratchr must wait until the other has finished his transmission. Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 - - REPLACEMENT OF COVERS Care should be used Inane replacing the covers to prevent distortion of the draw pull catches. The catches should all be fully extended before any are latched in order to Prevent the catch from beinp wedged under- neath the gasket. The catches on opposite sides of the cover should be latched in pairs for best results. Make sure that the locating tabs on the center section do not extend into the gasket groove. The tabs should pass to the inside of the innermost flange. Screw the occular of the viewer inward before replacing the tripod platform. The microphone may be wedged into the compartment against the arms of the bellows mechanism to Prebent rattle. The covers are stamped with serial numbers and should be replaced only on the corresponding units. , I Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 L Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 /4 ? / .?1,416 -loco Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 L9ZI ON 01 X 01 339 Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5 OF' 11 PIP2fX - ME IMEM?MG MEM ME 1ME mmmommommmommommommmom mommommilmmomm ? milim m mmummommomm Eli mommmis mom um m TEMP% gimmpum ? mm mommommommom IIIIII ? ? mm mm EL ,araimm 'mom ?Em 1 Imill M1111 'III mom I mmommmEmmomm 1111m1 mil immlmmm m ? 911111111111111 mom m 116?MIIIIME111111110111111 ? m?111111111111111 MmEME EMEMEmmEMMEIBIEMEMEME NIP m M m M Migi 111% IIM ? 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" Word4 WZ010 ' MM 1 EMU MUM 111 MM ME 1 ? 1 ' h ?' + ? 1 ? MM =MEM= I ? M ' M ? MEM MR IMMMMMMM ME ME ?MMIMIMMOMMEMM MI ? ? E =MEM MOM IMMEMMEMMIMM MMMMMM MMOMIMMEMMIMMIMMIM MI ME ??MEM ? Declassified in Part - Sanitized Copy Approved for Release 2011/12/28: CIA-RDP78-03300A001600020097-5