ELECTRON TUBE RESEARCH, DEVELOPMENT AND PRODUCTION

Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 r;..1 CLASSIFICATION SECRET GLNIKAL INTELLIGENCE AGENCY INFORMATION REPORT THIS IS UNEVALUATED INFORMATION TABLE OF CONTENTS Electron Tube Research, Development and Production A. Vacuum Tubes (Background) 1. Foreign Influences 2. Vacuum Tubp Activities in the USSR (General) 4. Insti utea6 H(yazinor(Moscow) 5. Political Ideology and Tube Research B. Vacuum Tube Techniques, Production and Materials 1. General Assessment 2. Production 3. Materials and Techniques 4 Research C. General Tubes 1. Class Bulb 2. Metal-ceramic D. Special Tubes 1. Cathode Ray 2. Modulator T-R Subminiature 5. Image Converters CLASSIFICATION SECRET 50X1-HUM i Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 COUNTRY USSR PLACE ACQUIRED Electron Tube Research, Development and Production 50X1-HUM DATE DISTR. S APR 54 NO. OF PAGES 17 11 . 1.. .. ItR 11 H1 . ~ T ?. .[Y11f ? 1 1 Y I.  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 SECRET -2- E. Magnetrons 1. Basic Data 2. Magnetron #10 (German RM 4032) 3. Magnetron #8 (Early warning?) 4. 'Rising Sun' 5. Magnetrons in 40-150 MC Region 6. Techniques Tables I and II (Magnetrons) F. Klystrons 1. General Description of Klystrons Table III (Klvstronel 0. Transistors and Crystal Detectors 1. Transistors 2. Crystal Detectors Appendix A. Vacuum Tubes* (Background) 1. Foreign Influences on Vacuum Tube Technology. a. "in the immediate post-World War II period Soviet activities in vacuum tube technology were influenced very strongly by the German developments, methods, techniques and personnel. the original Soviet idea might have been to pattern their vacuum tube build-up in accord with the,Qen guided in its plans and programs much more strongly by the USA developments than by the German re commendal; ions. They continued to exploit fully the German technolcigical know-how, their shop and production techniques and their testing and production tools. They had the German ispecialists in the USSR survey and analyze their war-time and pest-war research and development, and were willing to adopt those that fitted their plans and requirements. They used Germans to design and build new devices, testing tools and equipment and to establish several well-organized modern vacuum tube institutes and plants. It was, however, the American methodology that the Soviets were impressed by, and tried to master. One of the important continuing fobs that the German specialists were expected to perform for the So%riets was to elucidate the USA vacuum tube technology and its developments. It got to the point that the best way foi' a German to convince the Soviets of the merits of his proposal was to claim that it was based upon an American development. * ote: The term 'vacuum tubes' is commonly d to include a wide variety of electronic devices, as well as transistors which'replace vacuum tuber. 'Electron tubes,' a generic term used in the' title of -this report'," is eosj into more widespread use to cover this wide range of airoudV components] SECRET 50X1-HUM 50X1-HUM Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 -3 believe that American methods as a whole are betteresuited8 to ,their purposes than the German, and that the American products lend themselves to much easier production processes in the USSR than the German. The second reason is that the American high-frequency technique is greatly superior to the German. Thirdly, American electronics progress in World War Ii was exceedi,,iriv we,, Communications Equipment a. "All vacuum tube institutes of MCEI (the Ministry of Industry) are directed by the Second Main-Administration Group (for vacuum tubes), the Chief E ineer of which is /f'nu7 Sorokin Each of these institutes eaded by a oa roe Of W1, are very administra 'a high quality technical men. Each institute has also a political commissar, who, however, do not interfere in technical matters. b. "In addition to MCEI vacuum tube institutes there are some vacuum tube capabilities i n other institutes of MCEI (ie, Radar Institute in Moscow and_i the institutes of other ministries. Of these of the Soviet m&vv_ et- s..-__ __ _--_ the best are those "A.'ll Soviet institutes are organized to be fully self- isufficient, and in theory at least capable of all 'activities required to support their operations. All main vacuum tube institutes have their independent research and development faciliti es, they design and produce their own testing equipment, they have their own workshops, they produce do their own raw material and also their own metallurgical and chemical work as required. Three reasons for this Soviet procedure which is quite foreign to the normal German procedure are: (1) reliance upon a host of suppliers located frequently at great distances from the vacuum tube plants in laboratories, the tremendous distances in the USSR coupled with poor transportation makr,the flow .of :peterial slow and hazardous; (2) the specialized needs of th..vacuum tube institutes for relatively small quantities or high. quality material not generally produced elsewhere, and (3) the desire of the Soviets to have as many operating units as possible in any eventuality similar to the invasion of the USSR by the Germans in World War II. Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 e these ?meetln s communal very effective. At B problems are discussed and' recommendations are made for assignment of problems to one or mcrequalified organizations. When the project is assigned of to o one institute, a special p committee is selected from members other institutes to pass on the given progress and htandeth'e At best s so solution is to several institutes solution is accepted for all., t is method works very satisfactorily in the USSR, a p zed problems in their field. good deal of thought and preparatory work is required for such meetings and that they are consider d p g,ess and problems of all others biannual meetings areheldof representatives of all institutes on s eci li orderto pateunnecessary duplication keep on the ro informed of effort and to 3. Svetlana GE?oup (Leningrad) of MIT in the field of ,radar, or the~Bell Teleph ~honu"" Labo `'te ies in the field of telecommunications. Poratories 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM b. "The Svetlana inatitute 'grew out of the old Marconi plant in Svetlana whi h ommun ist Party ideology, are quite independent and yet are left unmolested because of their technical su a- it e? Svetlana engineers are not influenced by the 50X1-HUM c manufactured transmitter tubes. It is one of the oldest and best electronics groups in the USSR; it is here that -Qv uovieteieccronica specialists at present were trained. (Zuzmanovaki is one of them.)Svetlana men are not only id goo engineers, they are regarded as an outstand- ing lotof people and are welcomed in any other plant, or institute. All new vacuum tube institutes in the USSR have several Svetlana men assigned to them to serve as a core in technical administration and activities. There were four or five Svetlana men in Fryazino, and the same number in Novosibirsk and Tashkent where some Svetlana people were stationed even during the war. example, there was the instance of the former leader of Svetlana being imprisoned for political unreliability in 1947 without any detrimental effect upon Svetlana personnel. d. "There is also another facet of the special position of the Svetlana groups it is a.closed fraternity and its influence can be just as strong in support of progress as against it. An interesting case to support this opinion occurred in 1939/40. A Soviet article was published on magnetrons* in which the author, N F Ale v, appears to have made the basic discovery of the use off' resonant cavities in connection with magnetrons. It is known that this article had some influence on German magnetron developments during 1941/42 this 50X1-HUM Influence was not greater because the Germans at that time were primarily interested in tunable magnetrons and missed fully the potentialities of the fixed magnetron technique so well recognized by the British). In the U33R Alekseyev's work was wholly disregarded by the Svetlana people, responsible for this field of activity, because Alekseyev was not one of the Svetlana group and worked with =,apitza in another institute. Notes This sight refer to an artie]a annaar.- 50X1-HUM pp 1297-13 , ysv lairovv which was translated and published in !larch 1944 issue of IRE Proceedings) dotes The fact that the Soviets ignored this development is one of the most ?3pificant factors in the :history of Soviet micro- wave tube development. The Soviets missed a major discovery' and exploited only one part of magnetron technique--- continuous wave gansrationj Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 SECRET -5- Institute 160-.Fryazino (Moscow) ma...~ presence there of the, largest group of?German specialists. 50X1-HUM Two-thirds of the well-trained in radar and high-he German specialists r ^"w " frequency work and electronics and in the specialized field of vacuum tubes by the Soviet Communist ideology or the demands for Party line purity. There are many Party members among Soviet vacuum tube specialists. There are 50X1-HUM Soviets techniques apparently recognized th=-eir -r potnt al in inetesting eiassignedoRh most is field, of the noto Genlyntmspecialists the to this meet the needs ofthe t: j ruts but for' ,,.=G gsrcral 'ueneiit of all vacuum tube institutes. The Institute ractically all its built measuring devices and these were better than 50X1-HUM those produced in Germany. b. "Once the Soviets recognized the importance of laboratory equipment, the German engineers received considerable assis- position tance in to their obtain work theon such necessaaaiPm'nt. They were in a ryeven those other- w to inltiatep~through ise not obtainable because of scarcity and were encouraged foreign-made equip enth ofrspecialized design or~performance characteriatlcb, Other Germans and myself inFryazino asked on many? occasions for the purchase abroad of American-made laboratory equipment advertised in USA technical periodicals and dot them. Political Ideologa and Tube Research. a. "No hindering effects were evidenced in the whole field of only are not members of the Party, but are quite outspoken in their non-Party views without any apparent penalties. b. "Although there are such cases as a past scientific leader of Svetlana who was imprisoned for his political views and 7n 7 Katzmann who, as a Jew, was not considered reliable and remove rom Moscow to Novosibir however. t re are other cases such as that of Mai Chee-lastni who 50X1-HUM was caught in an attempt to desert t e es an who was not punished (in the USSR the penalty for his act is death) but, in addition, was placed in charge of sub- miniature tube development and production in Kalinin and was permitted to-travel frequently to Leningrad which is in the zone of severe security restrictions, and of L`nug Zuzmanovskiy who was quite candid in his views of the highest Soviet officials without any detrimental effect upon his professional position. c. "In institute 160, as in all others, there was a political commissar. He was totally ianoant in technical matters and had nothing to-do with scientife tctlvities 50X1-HUM of personnel of the Institute, but handled such matters as procurement of materiel. Thl a indicative of 50X1-HUM the general situation in the In regard to the vacuum tube and electronics fields. The Soviets are too anxious to use all their capabilities in. building up their potential to permit their political views' to interfere with this goal, at least at present. Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 SECRET 6- B. Vacuum Tube Techniques, Production and Materials 1. General Assessment. a. -- i-cuugnlzea oy the Soviet leaders towards the end- -o-of--, World War II in that they ,were pinpointed and analyzed during the immediate -- 11 war period and most of these weaknesses were allevated 50X1-HUM by 1951/52. By that time the Soviets had built a number of well-operated and effective institutes for the development and production of all modern vacuum rubes. --, -01-vu he war- time and post-war progress of German and American technology; recognized the importance of effective laboratory and production measuring and testing techniques and set up special facilities for developing and producing testing equipment. They fostered a new generation of vacuum tube apecialists,theoretically well-trained in Soviet educational institutions and providedplentiful facilities for their practical on-the-job training in electronics and vacuum tube i the nstitutes. Therefore, although the Soviets are still behind USA lttshed field of in the USSR for 'future growtha anhind expansion, besioand the growin? Soviet vacuw. +++ti pOteuti 1 should be watched closely. "Soviet vacuum tube specialists have been guided to a large ex hodology, technology and progress 50X1-HUM C. "Although originally the Soviets concentrated on outright copying of American methods and end-products, the period of imitation by the Soviets of American tube technology has passed,, and original native developments by the Soviets or basic native redevlopments of foreign ideas should be on the increase. Specific examples of post-war original Soviet efforts are the multi-cavity high-output, high- efficiency magnetron in the 40-150 cm region, the 'Samovar' klystron and the high-quality theoretical work of Zeitlin on space charge in the reflex klystron. 2. Tube Production. b. "At Fryazino one department was established in 1948 to design tube machinery and develop methods and means for tube production. (There were 200 to 300 enaineerm in this department.) At ts operation of this department the performance and output of-this department was poor due to severe lack of sproialists,? inadaqutte cols, wager experience in this field eiad Door coordination with other in wit . 61AVMU "anumery? 50X1-HUM n e t t in Wit; equal y and uantity/of Soviet sp ici alists an d 50X1-HUM with the determination of the Soviets to improve their vacuum tube production, the work of this department must Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 0. "Phosphors were initially imported from Germany, one of the ~Iw -w...._- i-_.-- -- --? ' - - c. "Althofi was primarily w ~rittoy with a large preproduction tube production plant. there were some ?n automatic units organized on the American production line basis, each unit handling ona step-by-step basi's all the required operations. Only, general type tubes were produced there at the rate of .a tubeeach five to eight seconds. Thus some 10,000 tubes an hour could be produced there, amounting to an,effective output of, some 5,000 good tubes per hour based upon a 50% , rejection tubes irate which was computed on the basis of ratio, to the total number of tubes produced. Note: Some caution should be exercised in e use of German reports on Soviet vacuum tube production and rejection rate of vacuum tubes. Since most Germans were not permitted tovisit:the Soviet production plants they might be familiar with the quality and quantity of vacuum tubes produced in preproduction runs on the experimental,basis.'" It is, therefore, possible that their figures might not apply to the true large-scale production runs in the Soviet production plants) have improved. J although the Germans in center for and ign and production totof tube n production equip or des p q A- peerhyhapore effective, Soviet institutes must be doii,g the same work as the tube production activities in the USSR 'cou no have been supported by theend-products of the Fryazino department for d ai% and production of vacuum tube equipment. no mac nes er ma e, the same type whicheareof the by American tube concerns, purchased there were some German automatic machines a(Funkenwautomaten)? There were two of these in Novosibirsk. Some 16 such automats were in Berlin at the end of the w removed by the Soviets 3ealex machinea so ava able at Fryazino, 3. Vacuum Tube.Materials and Techniques a. "Special work on tube cathode production and materials was done at the Moscow cathode plant. The equipment in this plant was German which was removed by the Soviets from the Telefunke #2 plant in East Berlin. This Moscow plant0 was planned to be large enough to supply the. whole needs in cathodes. b. "Until about 1950 the Soviets were forced to use standard nickel, which was not good quality for cathode processes. The difficulties in obtaining pure cathode nickel were largely administrative. The Ministry of Metallurgy was not interested in adjusting its production processes to provide a small quantity of high quality nickel and ultimately the Ministry of n laboratory was .stab by the Soviets for production of phosphor. the quality of this phosphor is fu13 aslsble with fhft of GezwAn phosphor. Also an LWO Later a a eola1 ohenist in Poasa,o with good resulti1RQ11 by a Gersan 1C11Ly Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 SECRET -8- j r.F was removed by the Soviets from the Heyden Plant in Dresden.When this supply was exhausted-work was initiated at Fryazino on developing substitute materials 'and onthe production. of thorium oxide. Seri lties were' encountered, which difficulties are generally well known and ara available in Frazino -11, thorium oxide material was h are some deposits of mica in Northern Sib fluctuates widely -25%to+15%. Mica"was carefully handled by the Soviets and?was'graded into three classes: (a) for hilh-.orgnera tpupose technique; for The use only ,gowenP'tu and (c forfreeneral ur of f m mica in e ac that it does not last, particularly under con- ditions~of over andyunder heating. Operating conditions in the USSR are?ver hard on tubes as line voltage the only ?oo arum oxide in the USSR istha sup iplsup ed b the Heydpn Plant; others were not good enough, the robl unsolved in the USSR. the quality of um oxide is a matter of luck and the success of Heyden is due to such luck and the characteristics of the raw material used. "The Soviet mica was of poor quality. This is based upon +. t, f t I consi era le. work as done b the armans on s thetic mica In the summerof an important request came from MCEI to a German specialist to study the replacement of mica by ceramic Note: Analysis o ov a gen , - - t u b e s by T C indicates that the quality of mica used in these tubes is very good and in fact somewhat superior in quality to ours. It is therefore possible that source was not familiar with the mica situation in the USSR or that mica supplied to the development institutes in the USSR was of poorer quality than that available to the production plants] the use by the Soviets of oxygen- _re_opper, a asic Soviet requirements for copper for tubes (including magnetrons) were (a) suitable electrical characteristics (b) easy machining. The Soviets have had no trouble with copper and they have had enough experience with copper in other industrial uses so that normal quality copper was considered by the Soviets to be good enough for Note There have been other indications that Soviets have been keenly aware of characteristics and importance of oxygen-free copper and concerned with the availability of such copper for this use) "In general, the Soviets are quite familiar with all modern problems and progress in vacuum tube techniques and methods and have proven capable of adapting the foreign develop- ments and ideas to their purposes. The Soviets are presently doing very capable research in the vacuum tube field. They are capable of originality although not adverse to borrowing ideas from abroad. Older specialists such as Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 e ng neers, for example, Zuzmanovskiy andAlekseyev's work on magnetrons, Zeitlin's work on klystronsVogelsohn's work on gas tube technique. The Soviets are very imaginative and stubborn people and permit experimental work, at times very costly, on prob- lems which would not be tol r tedin Germany or, the USA; ie, 'Samovar' which would have been abandoned elsewhere, intense wor on-10 megawatt and higher magnetrons. h. "The following sketch 7Fig 17 is of the kreuzaonde device Svetlana engineersare being augmented in this regard by very capable young engineers fully comparable if not better than young German i a to each evice consists ets of electrodes at right angles th. These of se were used in the electrolytic trough toobtain two r fight-angle components of th e magnetic field. The device was of considerable laboratory use at Fryazino. Research. KREUZSONAE (FIG 1) 0-1 1 a. "All research in the USSR, including the work on vacuum tubes was centered in and coordinated by the Academy of Sciences in Moscow and by biannual meetings of the research leaders of the important tube institutes jee par 2d abov). Some of the tube research was centered in an inat Kharkov, presumably for the Ukraine that the good work done there was felt in a institutes. b. "Special problems relating to cathode Droblems wer ,centered in Kievl excellent work was supposed to be done there. C. General Tubes. 50X1-HUM 50X1-HUM 50X1-HUM 50X1-HUM 2. Metal-Ceramic a. "The metal-ceramic tubes made at OSW were of the World War II ? . .- __ _ _ type and coast ... coon; ~ 04- Go the German grid due o w er variations in grid-to-cathode spacing. c. "In the summer of 1946 the German group at 06W experimented with a new form of grid to reduce the grid-to-cathode spacing and improve high-frequency cut-off characteristics. b. "Metal-ceramic tubes were produced at Novosibirsk. The LD-12 grid was in the form of a woven mash iee Appendix Fig 2a and 2 b7. this grid is i i 9SCP..T Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 D. Special Tubes 1. Cathgde Ray Tubes SECRET -10- A glass form was stamped in the form of a cathode and.a grid mesh was machine-engraved on it. The grooves of the mesh were filled with carbonand a copper grid was produced by electrolysis. The work was stop ed when the cone usion ~~ the u e m g ave een used n a special computer then under development, most probably for a ballistic computer, is based on the type of special accuracy requirements supplied to the Cathode'Ray Department at Fryazino and on special work on testing devices which the Germans werA aat~o,a r,. At Fryazino a special oscilloscope was built to study the build-up time of magnetrons. -km woo uoeu for ooservl the cathode ra trace. 50X1-HUM "Dr Roethe worked on dark trace tubes at OSW. Development work on these tubes was continued in the USSR. In 1950 the work was considered so secret that the Germans were not ermitt work on it. FnVI_ui inn Note: In line with repeated statements that the normal Soviet Procedure was to 50X1-HUM eliminate Germans from the classified projects whenever their development was completed or proceeded to the point that it could be completed b the Soviets,. it is possible that elimination of the 50X1-HUM German specialists rom further work on dark trace tubes might have meant that the Soviets considered the project sufficiently advanced for production or pre-production engineering) "There was a special development in 1946 at OSW on a high-speed writing cathode ray.tube. The principle used in 1--},a.. "-- ---- - ? - 2. Modulator Tubes. a. "AI first the Soviets tried spark gap modulators for high efficiency jobs but the methods, were given up when they later developed high efficiency hydrogen thyratrons and Of special interest was the Soviet use?of the tec niique- to maintain the hydrogen pressure at constant at Fryasino. This is a half-tee watt b p plate- anode voltage of 35000 volts. no trouble 50X1-HUM was experienced with this tube. was very good and the wa The no about 50?. The 5 AC 21 tube was an interesting one developed and roduoed was tiravQ in 1y;11/rjw Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 SECRET -15- Magnetron NO .1 Clta netrona were numbered for ease of discussion during expe a an y This ' pons lacin~development s innInatn10 the Man 50X1-HUM is in contrast to information obtained from other German cow. returnees who stated thxt-therewa salarge.production of this tube already in effect. Magnetron No 2 This, tube is in the planning stage only, and is designed. for 1 cm operation (30,000 Mc/S). The proposed construction would follow the wartime TelefunkenLMS-14 tube. Magnetron.No 3 This tube is acopy of US725 magnetron Which was designed for the H2X X-band blind bombing radar. This is called "Meddo" by both Germans and Soviets Magnetron Nn 4 is a This tube, type 7' is designed for It similar in design to the German LMS 3 . A copper tuning ring is mechanicallymoved towasd,and.' away from. the, cavities. Magnetron No 5 , The tube is a "Rising Sun," fixed tuna pulse type 1-band magnetron. Development is not yet complete ee Appendix, Fig 57. Magnetron No 6 This is a copy of a Canadian tube of the CV series, S-band. Magnetron No 7 This tube is.CN, mechanically tuned magnetron designed for Jamming. flee Appendix, Fig 6.7 An inductive ring is used for tuning in a manner similar to be No 4, and German type IM-32. Magnetron No 8 This tube is an 3-band, pulse-type, fixed-tuning, 2-megawatt peak power such as would be used for early warning. Its efficiency. is about 60 - 70%, and frequency stability 115,000. The internal structure,-coupling device and test equipment were designed by Soviet engineers. The teat equipment is reported to have filled a room of about 300 sq ft floor area. The tube development took three years, requiring seven or eight Soviet engineers. Magnetron NO 9 This tube was designed by the Soviets, without GerrAn assistance. It was rumored to have 10 Mf or larger power output by having the equivalent of a number of two cavity magnetrons in parallel. The tuning was accomplished by.wave guide techniques and had a range from 40 to 150 M. It is probably intended for early warning. MS .etran ro 10 This tube is a copy of the German RM 4032, called the "zero slot" to it ? 3ft e? ioe g a ram ?? t field. Two tubes are made--one of` a range from 0.8 to 3 dm, seOther from 3.0 an to 12 on. '1!e main use or this tube is experimental. Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Nomenclature ~a net z~oi h'z Magnetron Magnetron lagnetron Magnetron Magnetron Magnetron Magnetron Magnetron Magnetron No. 1 No 2 No 3 _12-4- - 1o 5.. ---- No 6 No 7 No 80* No 9 1o IOMW avelength, cm 0.5 1.0 3.2 ?3.0. 3,2 - a.5 9 - 10 9 - 10 10.0 - 410,0150 Two 1odele - ' 0.&.3 iaed or Tunable Fixed : -- unable Fixed Fixed Tunable Fiord Fixed- ? ltmab]e gda sEulse or CW CI CW es se Anode Voltage -- ------ - - - 000, A-Ij 2000-3000e Anode Current Duty c'cle 300-400 ma 21 s 1-1,000 or eater Supply - Thor ozdde Directly Da oxide -7 heater. boated beater thode- _ --- - -- - - - ----?__--- ------------ -------..---- ----- sten Out t Poser= pu _- 500-600 11 --- 80.100 Mi ? 01 2 Mtf Hid1. si! fw T' _ aillisatts Application _i Meddo - Radar Jamming - Radar Radar Jamming atlar,N ? laboe+a~aey Development Data Start Similar to Copy 1949 1947 Copy 1946 1946 Completion Now in Teleiunken Intermittent Not cai- 1948-49 1949 Special remarks experi- LMS-1l, In preprod. plete mental only in rtage - stage planniog sta" Production Data Bass Ro- In 1949 200 dnced in several 1948 -- --- P-W Elm ''Where Developed Moscow - ry 1087_ F asino Pr yasiao lrpadso a1sfs egsipwt Where Produced Saratcr ]duo In pro- O 401 900 ductia- u3 2 T * ompara a ev Dusan. ing the war by-the berme took one-. Inside of magnetron wets developed by Soviets coupling and external 'plumbing' by Germsirs. +-* Equals German RU-4032 Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 SECRET -17- 1, "Soviet kl stron work was influenced by both German and US desijzns /see Table TTT_nava 1 ; a. "Klystron #1 the tube isa copy of a General Electric .42 cmtube , scaled up. The Germans in Fryazino were asked to produce such a klystron for use in testing gear for'8 mm crystal detectors, but found it a hard job. In order to speed their work,' the Soviets supplied Fryazino with this klystron,and some, additional testing gear, which was produced elsewhere. b. "Klystron the Soviets #2 is a copy from a US prototype as copied by viets from a,1949 1950 IRE publication. The tuning"rangewas claimed to be 2.5 to,12 cm,"and the tuning was accomplished by mechanical control of the cavity Liee Appendix, Fig #9 . c. 'aKlystron #3 and #4 were copied from the US Western Electric 725 k1Ystron and German LD copy -20,which was a of the same prototype. Klystrop #3 was tuned around 3,2 cm and used for 'Meddo' radar; #4 was tunable from 28 - 29 cm and represents a variation of #4. "Klystron#5 is the' 'same was copied by the Germans during the war, Down as LD-25, or klystron 1 (Siemens-Halske), e. "Klystron #6 is a shortened version of #5. Both these tubes have a glass envelope and use an external tuning cavity. G. Transistors and Crystal Detectors. 1. "The USSR work on crystal detectors was based upon the German developments in 03W. In 1950 a plant was established in Prvaz1no to ,we w.+Pe ., ~..re silk det-_t-.__ -O v_.;rw` procedures. Attempts were made in Moscow to manufacture these detectors following the American procedure. Results were rumored not to be very good and best work was done with the German method. The second step was the intro- duction of germanium detectors. These were first made in Institute 28 in Moscow but with relatively little success and in 1950 Fryazino started to produce germanium detectors in small quantities on*,experimental basis. Some production was done at Fryazino, primarily for Institute 160's require- ments. The main work of production of crystal detectors must have been done elsewhere. 2. "It was only in 1952, that basic development and researen c was initiated by the Soviets on transistors. The background of knowledge was available to the Soviets in American publications. There was a book by William Shockley which became available in the USSR in January 1952. A special committee was established in MCEI, consisting of the best specialists in the Soviet Union, to work out the fundamentals of transistors. Everyone was very optimistic though[ t e opt s un. founded. SECRET Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 Nomenclature Klystron No 1 Klystron ]io 2 Klyatron L; 3 Elyatron No 4 YVetron No 5 E]ystron No 6 Ds Type go 725 1 10-1 1 1C-2 W a v e 08 2.5 - a 28-2 e 5! Ultaff* ,000 ~_. t ut Pow ..tt ` - - - Sam as d is pplicatioa Deae nz~iag Experimental N_`Ltab and a as t 10-1 but device Ga 7 P ' Development Data a Ma ro aadltled In Start 1949 1 year 1951 totypss Completion 1952 At 0SN (m-?.0 Variation ftediRl remarks Ccwv of US t: of 725 Production Data 36PAgag, etc e Developed oscovr TInet 1os?) Pryawino ~ fteum ere Produced Moscow Svetlaaa 9?et land is (presently prodoetion believed to be in pro- duction in S Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  50X1-HUM Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 on wor Table s,know itiona 91 t be,sc produc crysta speed klyst produ 2 is s fro: nge wa 3 accoi ?e, App, ~3 and T25 k1; ~d for )resen 5 Is the Gf )n 1 (: 'E6is ag1a on crJ .n OEW ,ttempt a fol] Lot to n metY maniun n Moac yazinc itiea yazinc in wo= done 1952, d rese The in An okley A ape the be undaas e, the not k ELEMENTS (I) CATHODE (2) GRID-OV- (3) GRID 2000 (4) Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 LD 12 GRID Pi .2a and 2b - Details of Metal-Grasic Dubs LD-12 BEAM FORMING  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 I METALLIC SHIELD 2 G D ~_ 3 GRID 2 4 ANODE' 5 CATHODE 6 ENVELOPE LATER MODEL OF ABOVE TUBE CATHODES IN-LINE AS IN SDZI Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 CATHODE HEATER ENVELOPE  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 Pala 3'' MAGNETRON NO. 7 STRAPS (3) -VANES '(2) CAAf$TY (I) (4) TUNING RING Pig. 6 - NWatrm No. 7 - Jamir Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 Page I& A-A' OPENING. FOR OUTPUT COUPLING 'TO THE WAVE GUIDE (I) (2) CAVITIES Fig. 7 - lwgatraa Is, e - Rftr. pN7 lhraiI! 50X1-HUM Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8  Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 DIAGRAM APPROX. 10" NO.9 (2) ARRANGEMENT OF CATHODES (I) No. 9 I TUNING SLUGS 2 OUTPUT COUPLING TO WAVE GUIDE 3 NIEPELLEN 4 ELECTNIOW GUN s1g.9- uy"m r.. 2-*amble Sanitized Copy Approved for Release 2011/08/10: CIA-RDP80-00809A000600050387-8 IN SEVERAL CAVITIES (2)