JPRS ID: 9895 WORLDWIDE REPORT TELECOMMUNICATIONS POLICY, RESEARCH AND DEVELOPMENT

APPR~VED F~R RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 FOR OFFICIAL USE ONLY JPRS L/9895 5 August 1981 w Woridwide Re ort p TELECOMMUNICATIONS POLICY, RESEARCH AND DEVELOPMENT CFOUO 10/81) FB~$ FOREIGN BROADCAST INFORMATION SERVICE FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 NOTE . , JPRS publications contain information primarily from foreign newspapers, periodicals and books, but also from news a;,:~:ncy transmissions and broadcasts. Materials from foreign-language sources are translated; those from English-language sources are transcribed or reprinted, with the original phrasing and other characteristics retained. Headlines, editorial reports, and material. enclosed in brackets are supplied by JPRS. Processing indicators such as [Text] or [Excerpt] in the first line of each item, or following the last line of a brief, indicate how the original information was processed. Where no processing indicator is given, the infor- mation was summarized or extracted. Unfamiliar na~nes rendered phonetically or transliterated are enclosed in parentheses. Words or names preceded by a ques- tion mark and enclosed in parentheses were not clear in the original but have been supplied as appropriate in context.� Other unattributed parenthetical notes within the body of an item originate with the source. Times within items are as given by source. ~The contents of this publication in no way represent the poli- cies, views or at.titudes of the U.S. Government. COPYRIGHT LAWS AND REGULATIONS GOVERNING OWNERSHIP OF MATERIALS REPRODUCED HEREIN REQUIRE THAT DISSEMINATION OF THIS PUBLICATION BE RESTRICTED FOR OFFICIAL USE Oi~1LY. APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 FOR OFF[CIAL USE ONLY JPRS L/9895 5 August 1981 WORLDWIDE REPORT TELECOMMUNICATIONS POLICY, RESEARCH AIVD DE`v'ELOPMENT (FOUO 10/81) CONTENTS ASIA JAPAN 'CAPTAIN' Computer Access System Test Results Published ~ASAHI EVENING NEWS, 21 Apr 81) 1 VIETNAM 'VNA' Reports on Printing of 'NHAN DAN' by Facsimile ~VNA, 14 Jul 81) 2 EAST EUROPE CZECHOSLOVAKIA CSSR's Magion Satellite Systems Outlined (SLABOr^ROUDY OBZOR, Apr 81) 4 Mag~on Satellite Design Concept, by Miroslav Studnicka . Transmitting Equipment Described, by Jozef Plzak Reception of Signals From Magion, by Vaclav Grim Prognoz 8 Soft X-Ray Radiation Analyzer Described (Bohuslav Komarek; SLABOPROUDY OBZOR, Apr 81) 27 WEST EUROPE UNITED KINGDOM ~ New Communications Satellite Being Built (Henry Stankope; THE TIMES, 22 Jul 81) 37 - a - [III - WW - 140 FoUO] F(1R (1FFT/`T A T i fCF IINT V APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 FOR OFFICIAL USE ONLY JAPAN ' Cc~P7'AIN' COMPU'I'ER ACCESS SYSTEM TEST RESULTS PUBLISHED Tokyo ASAHI EVENING NEWS in English 21 Apr 81 p 3 [ Text ] 't'he first-stage test ~ of the ~e TV receiving set, ~ monitors and screens to Z,000 "CAPTAIN .iystem," a new During the first-stage test and 200,000 respectively, or informadon medium which serHice period, the system was double those used in the first- subscribers may use tu request used an average of 0.72 time stage tesc. - information from a computer per telephone per day, or twice If the results of the second- over the telephone and re- in three days. The avcrage stage test ara satisfactory, full- ~eive the answer on their tele- time used per phone call was dress service will begin in fu- vision screen, ended in March, ~ 3 minutes and 41 seconds. cal 1983. - and the Posts and Telecom- The average number of fram- To the question "Will you munications Ministry and ot6- es used per call was 38. subscribe to the system if futl- er auihorities ihat conducted As to w6ich categories oE fledged service begins?" asked the test recently released a re- information were used the during the first-stage lest pe-~ port on the system. most, information on events, riod, more than half of the . . . CAPTAIN sxands for Char- including movies, hobbiea, 'respondeats replied in the af- acter and Pattern Telephone, quizzes and games were ovcr-� firmative. It is particuluriy Access Information Network whe}mingiy popular with 46: � noteworthy that 7S percent of Linking 976 telephqnes in To- 83 percent, followed by news those who made active use of kyo, the first-stage test was and weather forecasts with , the tesi service answered in conducted from Dec. 25, 10.55 percent, education with ibe affirmative.. � 1979, to Mazch 15 this year. 10.36 porcent and sports wiih To the query What is aa Information contained in the 9.83 perceat. Fields that were adequate fee for the service?" computer includes about 100,- used the least were healtb, many replied "About ~f3,000 a 000 "frames," including those . beauty culture, childbirth and month." Twenty percent of the for news, weather forecasts, child rearing with Q.68 per- respondents said they were quizzes and travel informa- ceni, followed by economic willing to pay more than ~'3,- tion. and legal questions with 0.60 ~ a moath. Those making use of the perceat. The new iaformation medi- system, or monitors, are lim- Household heads used the ~ obviously is enjoying high ited ta those living in areas system the most at 45 per- P�p~~y' ~ uader the jurisdiction of a cent, followed by children, 30 telephone exchange equipped perceat and housewives, 18 _ with electronic t e 1 e p h o n e ~~eM. � switchboacds and w6ose phone Users apparently made use is of the pushphone type. of the system with clear-cut The telephone line and ihe ' objectives. Most household TV receiving set at home are b~ads said. that they used ttire linked by means of an adapter. system "to' obtain knowledge;" To use the system, one calls ihe houso~vives said they used che CAPTAIN Ce~ter with ihe it "to obRain information nec- pus6p6one. After setting his essary for our adivities" and T'V set for recepdon on an the children answered "for open channel, ~e designates ~udy aad amusemenL" what he wants to~ know by ~ pushing designated numbers on Tbe second-stage test sec- the keypad. Then, characters ~ice is scheduled to get under or patteros are sent via the tele- way in August this year, with phone line and screened on ~~e.nuanber Qf COPYRIGHT: Asahi Evening News 1981 CSO: 4120/240 1 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-04850R000400040007-6 FOR OFFICiAL USE ONLY VIETNAM 'VNA' REPORTS ON PRINTING OF 'NHAN DAN' BY FACSIMILE OW210323 Hanoi VNA in Vietnamese to VNA Ho Chi Minh City 1350 GMT 14 Jul 81 [TextJ [no dateline received] After the complete liberation of South Vietnam, an urgent task arising was tha t NHAN DAN, organ of the party, had to be widely and rapidly published throughout the country to disseminate the party line and policy among the people of the newly liberated areas. At that time 1~IiAN DAN was being printed in Hanoi and then transported by plane or other means to Ho Chi Minh City and the southern provinces. The transportation often met w~th difficulties from weather conditions and in means of transportation. Due to this, we could not assure the up-to-date character of the paper every day. In face of this, based on results obtained in the transmission of radiophotos during the war and particularly dur3ng the "Ho Chi Minh Campaign," and relying on existing equipment, VNA put forward a number of inethods for transmitting the di.m~y of NHAN DAN from Aanoi to Ho Chi Minh City to be published locally for southern provinces on the same day. The transmissioi: of the paper was based on the existing network of radio transmission and reception and Soviet facsimile reproducing equipment, according to th e narrow-band shortwave trans- mission method. In the conditions where our country did not yet have a wide-band newspaper transmission facility, this method was the most appropriate one. VNA's technical section experimented transmission of newspapers by this method from July to September 1975 and achieved relatively good xesults, confirming that it was practical enough ~:o be applied on a regular basis. Lturing the experimental process, engineers and technical cadres concerned made use of facsimile and Voice of Vietna~n Radio's transmitting equipment and assured the quality of reception of the transmitted newspaper within our technical capa- bilities and under our country's weather conditions. . Early in 1976, after perfecting this method, VNA joined N~EiAN DAN and the Posts a.nd Telegraphs General Department in organizing the regular transmission of NHAN DAN from Hanoi to Ho Chi Minh City. By this method, the first issue of NEIAN DAN was off icially printed in Ho Chi Minh City on 20 April 1976 and issued on the same day in the southern provinces, thus supporting in good time the election to the unified national assembly of the whole country on 26 April 1976. _ 2 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400044447-6 FOR OFFICIAL USE ONLY In 1978, VNA again joined NHAN DAN and the Posts and Telegraphs General Department in successf ully transmitting the newspaper from Hanoi to Danang by this method. - In addition to NHAN DAN, VNA has alsa helped QUAN DOI NHAN DAN in technical and equipment aspects to apply the transmission of QUAN DOI NHAN DAN to Ho Chi t4inh City for printing there. CSO: 5500/2272 3 ~ FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00854R004400040007-6 FOR O~FFICIAL USE ONLY CZECHOSLOVAKIA CSSR'S MAGION SATELLITE SYStEMS OUTLINED Magion Satellite Design Concept Prague SLABOPROJllY OBZOR in Czech No 4, Apr 81 pp 159-161 [Article by Eng Miroslav Studnicka, TELSA-WST: "The Magion Exp~riment"] [Tex~] Not long after Czechoslovakia entered the Inter- kosmos organization, TELSA-WST [A. S. Popov Research Institute of Communications Engineering] began cooperation with the CSAV [Czechoslovak Academy of Sciences] in the development of instrumentation and equipment for the astro- nomical and geophysical study of space by means of satel- lites. Over the course of 15 years, they have successfully developed more than 200 types of instrtmments. The high point of our participation in the Interkosmos program has been the development and launching oi the first Czechoslo-- vak MAGION satellite. This article describes the purpose of the experiment and the design concept of the satellite _ and evaluates the findings that have been obtained. Introduction On 14 November 1978, the MAGION satellite (international designation 1978-99C) separated.from the Interkosmos 18 spacecrafi (1978-99A); this satellite was intended to study the temporal and spatial structure of low-frequency electro- magnetic fields in the earth's ionosphere and magnetosphere. The scientific aim of the experiment and the method of carrying it out were d~veloped by the Institute of Geophysics, C$AV, in cooperation with the Institute of Geophysics, CSAV, in cooperation with the Institute of Geomagnetism, the Ionosphere and Radio Wave Propagation, USSR Academy of Sciences. The Magion satellite was developPd and manufactured by TESLA-WST and the laboratories of the Institute of Geophysics, CSAV, in Prague. To carry out the experiment with the Magion satel.lite it was necessary to provide transmitting and receiving equipment for ' the ground control stations, including the antennas, as well as monitoring in- - str~Fntation. Some 17 instruments were produced, most of them in several models. Thus it is clear that the project was rather exteasive and required considerable effort. Accordingly, the placement in orbit of the Czechoslovak sateilite, and its prolonged activity, may be considered a considerable success. 4 FOR OFFIC[AL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-04850R000400040007-6 FOR OFFICIAL USE ONLY Aims of the Experiment The scientific aim of the experiment is to study the temporal and spatial struc- ture of low-frequency electromagnetic fields around the earth. The investigatidn is carried out through simultaneous measurement of selected parameters on two spacecraft whose relative position is changing. One of the craf t is the Inter- kosmos 18 satellite and the other the Magion satellite. These satellites move in a nearly polar, slightly elliptical orbit whose plane is inclined at an angle of 82.96� to the equator. The a.pogee of the orbit is 772 km and the peri- gee 404 km; the orbital time is 96.36 minutes. The Magion satellite separated f rom the Interkosmos 18 in the area of radio visibility from the Panslaa Ves sta- tion in Ceska Lipa, from which the experiment is controlled. The Magion satel- lite makes 15 orbits a day. It is given co~ands during each pass: on the average 6 to 10, but sometimes as many as 20. The number of comm~nds depends on the length of time it is above the horizon. Some 64 quantities are measured; some of these are scientific informa*_ion, while the others are information on the conditions of the satellite. The lifetime of a few weeks that was initially assumed~for the satellzte has been exceeded by several times. T1~+is it has be- come possible to ob~ain much valuable data. Of interest, for example, is the information acquired on the aging of the satellite's surface as a result of a gradual rise in temperature, which can be generalized for zonsealed ob~ects. These and other findin~s can be called the technical objectives of the experi- ments; they will be used for subsequent projects. The Design Concept of the Magion Satellite Equipment for space research has certain specific characteristics. Some of these are similar to those of equipment for ground-based radio communications and aircraft onboard equipment, nar?ely small size and weight, minimum energy consumption, high mechanical and climatic durability, and, not least, high reliability. Among the specific characteristics of satellite equipment, we include the requirements for operation in a nonsealed environment and in a rarefied atmosphere that is close to a vacuum, and particularly such design requirements as location of the antennas and their release into working posi- tion and precise balancing. The totality of requirements exceed current prac- tice in other areas of electronics. Because satellites generally are destroyed in the earth's atmosphere, it is difficult to determine confidently the causes of failure. As a result, in developing space objects, considerable time must be spent in tests and measurements whose results will affect the concept and design of the equipment. This was the case for the Magion satellite. The satellite is a rectangular prism with sensors and antennas protruding from it (Fig. 1). When the satellite separated from the parent vehicle, the antennas were extended and brought into working position on a command from ~he earth. The Magion's antennas are linear, unipolar and dipolar types. They are installed at a certain inclination to the main axes of the satellite and are relatively small compared to the wavelengths on which they operate. The antennas for 137 and 149 MHz protrude from the bottom of the satellite and are inclined at 15� to the base plane. The antenna for the 400 MHz band is in the middle of the top of 5 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/42/09: CIA-RDP82-40854R040400040007-6 FOR OFFICIAL US~: ONLY . r . 4. ~~aG~~~~ Figure 1. The Magion Satellite . � Key: A - l. Ejection base 2. Magnetic loop 3. Permanent magnets Ig ~ 4. Solar batteries ~ A. Magnetic probe n~,_____ ~ B. Support with amplifier for probe i o: rt _ J yT L__ rf _~P ~ gi C. Receivers and decoders I I D, E. Parts of scientific section I 0,35 ~ i c- ~ ' F. Transmitters and temperature i I je ~ measurement circuits i ; ~ G. Constant-te~nperature chamber i ~ i ~ with oscillator L_____ H, J. Preamplifiers for scientific ~ sensors r------'" j K, L. Batteries ~ r"'-~"- "-'1-~' '"-""-'1 ~ M. Connector cables ~Z~`- i.-,~ ~ o ~ ~ 0, P. Balancing weights I ~ I I I ~ I ~ I I I H ? G J�-~- rqi ' ~ ~ ~ I ~ - ~ ~ ~ I i i ~ I (3L ~ ' I I � � L F ~ ~ t ~ t iti. I L-�-�-- - I � ~ y ~oo Fi ure 2. La out of the Satellite h-- - 6 FOR OFF[C[AL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/42/09: CIA-RDP82-40854R040400040007-6 FOR OFFICIAL USN: ONLY the satellite body at the feet of the support which holds the ferrite aiil-enna. It has a length of approximately 0.5a and is inclined at 45� to the satellite's vcis. The antennas' input impedances are adjusted to 50 ohms by means of a parallel reactive component attached at a convenient place on the power supply. Figure 2 shows the layout of the satellite. In designing the Magion it was necessary to allow for many requirements, a few of which are shown in Table l. Table l. Some Requirements for the Magion Satellite Dimensions 300 x 300 x 300 mm Weight 15 kg maximum Force of ejection of satellite from parent vehicle 7.845 N+ 10 percent Temperature range +10� to +30�C Highest permissible temperature of solar cells +130�C - tdidth of ejection passage on parent vehicle 320 mm Deviation of center of gravity from geometric axis of satellite normal to launching base 0.35 mm maximum Linear overload along longitudinal axis of parent vehicle 10 G Linear overload along other normal axes 1.5 G Vibration along all axes 5-10 Hz 0.2-1G 10-30 Hz 1-4G 30-80 Hz 4-6G 80-1500 Hz 6-lOG About half of the interior is taken up by the satellite's scientific equipment. ~ The remainder holds the telemetric and monitoring system. The scientific equip- ment includes receivers for measuring the magnetic and electrical components of electromagnetic fields in a band from 0.1 to 16 kHz, a device for measuring the electric field in a band from 0.01 to 80 Hz, a unit for measuring the resonance properties of plasma surrounding the satellite at frequencies up to 8 kHz, and equipment for recording ~the flux of charged particles with erYergies above 30,000 eV in the earth's longitudinal and transverse magnetic fields. Tt~e te].emetry and monitoring system lias two transmitters. One operates at 400.57 MHz with an output of 1.5 W, and the other at 137.15 MHz with an outgut of 150 mW. A memory unit can be used to record measurement and monitoring data when out of range of the ground-based telemetry stations. The command receivers, decoding equipment ancl p.rogram switching unit make it possible to control indi- vidual parts of the equipment in various ~odes when the satellite is p assing through the radio reception region. 7 FOR OFFICIAL USE ONLY ~ APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 FOR OFFICIAL USE ONLY The batteries are charged by solar cells which cover almost the entire surface of the satellite. The energy produced by these cells is relatively small, not exceeding 3 W. Part of the energy (about 0.7 W) is consumed by the constantly- on units, while the rest is used to charge 2 onboard batteries, each consistit~g of 10 NiCd cells and having a capacity of 4 ampere-hours. The scientific appa- ratus draws about 1.5 W; the most ~ower is drawn by the 400 MHz-band transmitter, . which accordingly only operates at certain intervals. The individual components of the onboard apparatus are on standakdized boards with planar contacts and are connected by knife-type plug-in connections. Four permanent magnet bars 12 mm ~ in diameter and a magnetic loop of permalloy tape under the solar cells stabilize the satellite in the earth's magnetic field. ~ The speed of ejection of the Magion from the Interkosmos 18 vehicle was chosen as 0.5 m/sec. The ejection is effected by four microswitches whose combined force of release is equivalent to the desired ejection force. The use of a lever mechanism made it possible to decrease the force of release t about one- tenth of the original v~lue, and increased travel distance was used, providing reliable action of the ejection equipment. Because the satellite was ejected through a narrow opening in the parent vehicle, the center of gravity could not deviate more than 0.35 mm from its geometric axis. To measure the deviation of the center of gravity, a balancing device based on the principle of slow damped _ vibrations was produced. Precise balancing of the satellite led to positive re- sults in mechanical tests, in which no undesirable resonances were fusnd. Particuiar attention had to be devoted to the temperature regime and energy balance of the satellite. This required many tests, for which it was necessary to d~asi.gn and produce various accessories, including a solar illumination simula- tor. In particular, it was necessary to find out what materials and surface pr~~tection should be used for the Magion. The result of the work is a framework consisting of aluminum alloy sheets of different thicknesses. The parts are con- nected by rivets and screws. The frame is anodized black, and the outer surfaces which are exposed to solar radiation are faced with gold-plated brass sheet whose surface was subjected to polishing between applications. A shiny layer of alumi- num is vacuum-applied to the inner surface of the cap of the constant temperature chamber, forming a thermal mirror. For the most part, materials with bonded cher~~cal substances were used as insulators. Tests and the experiment with the ~:agion sat~llite confirmed the correctness of the concept that was chosen. Findings Obtained The results of the scientific tests and measurements obtained during the experi- ment are dealt with in separate publications. In view of the considerably great- er lifetime of the satellite than was initially assumed, the amount of information obtained has also increased greatly. Accordingly, we may state that from the , scientific point of view the Magion expariment exceeded the expected goals. The technical yield of the experiment may be similarly evaluated. The research and development of a satellite with sophisticated technical characteristics, made with domestically produced compunents, and its prolonged activity in space, have unquestionably demonstrated that correctly designed, carefully manufactured and thoroughly tested nonsealed objects can operate well and reliably in orbit and 8 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPR~VED F~R RELEASE: 2007/02/09: CIA-RDP82-04850R000400040007-6 FOR OFFIClAL USE: ONL1' furnish valuable information. This experience can be used in planning and implementing new experiments with separable objects, but also in accomplishing other tasks in other areas of electronics. Conclusion The Magion satellite has lived up to expectations. The experiment has made it ~ possible to obtain valuable experience and has created good conditions ror more extensive projects. One of them may be the simultaneous launching of two or more such satellites. The instruments developed and fabricated for the experi- ment gave a good account of themselves and operated reliably. The results ~.on- firm that the electronics industry is capable of producing instruments with excellent capabilities and of using its findings effectively in the performance of other tasks. This is a specific and direct benefit of informal cooperation in the Interkosmos program. COPYRIGHT: SNTL, Nakladatelstvi Technicke Literatury, Prague, 7981 Transmitting Equipment Described Prague SLABOPROUDY OBZOR in Czech No 4, Apr 81 pp 162-166 [Article by Eng Jozef Plzak, CSc, TESLA-WST: "Trar.smitting Equipment for the - Magion Satellite"; bibliography not reproduced] [Text] This article describes the co~unications system of the Magion project and the conception and design of the com- ma.nd link transmitters and of the onboard 137-MHz ar,.d 400-MHz transmitters. l. Introduction The Magion satellite is a small satellite, but the range of its basic functions is comparable to that of large scientific satellites. Accordingly, the communi- cations system must perform all the basic functions of large satellite communi- cations systems. Thus, one-way telemetric and identification communication is insufficient: the control center must have the capability of controlling the satellite's operating mode by means of a command link, supported by a distance- measuring system and having the possibility of checking from the ground the transmission parameters of the command and telemetric communications. Tl~e transmitters of the Magion project were developed by our institute. Tre 200-watt command transmitter operates in the 150 MHz band, the onboard 0.3-watt transmitter in the 137 MHz band and the onboard 2-watt transmitter in the 400 MHz band. 2. The Command Link The command link is intended to transmit commands from the ground station to the satellite. It consists of the command transmitter, the transmitting antenna, 9 FOR OFF[C[AL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00854R004400040007-6 - FOR OFFICIAL USE ONLY the receiving antenna and the command receiver. The command transmitter is connected with the control console and the command receiver is connected to _ the unit controlling the operating mode of the satellite. The cou~and-link is characterized by the following b asic figures: working frequency 150 MHz modulation narrow band FM , modulation swing fm~ 5 kHz modulation frequency 100-3,500 Hz~ gain of directional transmitting antenna G1 = 15 dB maximum distance k= 3,500 km receiver noise figure n= SkTp gain of satellite receiving antenna G2 = 1 dB losses from nonidentical antenna , polarization Lpol ~ - 3 dB ma:cinum gain difference as a result of directionality of satellite antenna ~L ~-15 dB losses in cables and connections I.X x 1 dB = Reference 1 gives the foll~wing figures: noise figure of receiving system n = 11.1 noise power at receiving antenna NS =-151.6 dB~ required power at receiving antenna Np =-141.6 dBr,,l (for a 10 dB noise interval at limiter) attenuation in free space Lp 147 dB required transmitter power N~ ~ 9.6 W On closer inspection, it is evident that it would be very difficult to improve the parameters of the onboard part of the communications system (i.e., the re- _ ceiving antenna and command receiver). Similarly, the transmitter antenna gain is an optimal compromise between directionality, dimensions and flexibility. Accordingly, the only realistic remaining potential lies in the command trans- - mitter power. In practice, the power of command transmitters is many times higher than the required value. It is chosen as high as 15 kW, which provides a reserve for reception under extreme conditions such as powerful interference signals, decreased receiver parameters resulting from extreme temperatures, a - decreased feed voltage and the like. 3. The Command Transmitter The command transmitter is used to transmit coded commands from the control cen- ter to the satellite, to measure the distance to the satellite and to measure - the entire communications path. The command link must make possible control of satellite operation by means of the requisite number of unambiguous commands during the entire period of radio visibility of the satellite. The reserve power for unfavorable receiving conditions and extreme situations should be sufficient to avoid production of spurious radio commands by an undesirable signal from another command, or by a chance modulation structure. Particularly great emphasis is laid on the reliability of the command link. 10 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400044447-6 NOR OFFICIAI. USE ONLY Careful consideration of the limiting factors on board the satellite (dimensions, power consumption, extreme working conditions) and availability of components led to adoption of an economical coding system. The command combination consists of ' a serial combination of thr~:e tones chosen from four differez~t possibilities. Immunity to random interference signals is assured by a fixed address which pre- cedes the command combination and a system of tone detectors which are inzer- ference-resistant. The entire command combination is transmitted during an - interval of less than a second. There are 24 command combinations available. This simple commanc: system makes it possible to design simnle onboard evaluating circuits with satisfactory properties. More detailed informat~on on the coding and evaluation of commands is given in reference 1. In addition to discrete commands, 400 and 500 Hz signals can be emitt~d for dis- tance measurement. Finally, both transmission 1i~zks (command and telemetric) can be checked by means of a modulating signal fr~nn an external source or a 1-kHz internal signal. The distance to the satellite can be measured by phase comparison of the emitted and returning 400 and 5U0 Hz signals, which are switched at intervals of 1/20 second. The entire communications path can be checked by a permanently-on 1 kHz modulating signal which is sent back by the telemetry transmitter, or by any other external modulation. The cotnmand transmitter consists of two units. The control section is a compo- nent of the control station, which is located about 100 meters away fram the antenna system. The output section of the transmitter is built into the antenna system and forms a unit with the transmitting antenna. Because of the extra- ordinary requirement for command-link reliability, the output stage consists of four parallel output modules. Figure 1 is a block diagram of.~i-ie control section. In addition to the signal- emitting circuit, the modulation circuit and the control components, it contains radio-frequency exciter circuits. Figure 2 is a photograph of the unit. a b c d Key: merem tes~lova a. Command COdeS � kody povelu . vrddlenosh 1 kHz ~~ryfi disple/ iosu b. Distance measurement ' ' ` c. Extr:rnal modulation amplifier d. Tin.e display ~ * e. Limiter a~to~~ 3 kHr ~ ~ D~ ' 3~D 5 V"~t f. Mod~ilation monitor/decoder saR g. Am plifier out put control f - h. Tempe~rature monitor, mon~rar mo- w~6dan;.y- ~ interference annunciator Cumce ~~1 ~ nvlowce deROder i. Operation indieator _ _ _ . -o konfrola feplo' M ~ y fr, hlasen~ ' I anruch ~ o �nd~Rare orovotu ' t~ Figure l. Control Section of the Command Transmitter 11 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2407102/09: CIA-RDP82-00850R000400440007-6 FOR OFFICIAI. USI~: ONLY ' , ii . . ~ t: _.~-~-~+r~"'^"~~+ I{ 1 f,~ ~ , ~ ~ i% 'r, . A ~ ~ ..,~^c.~,= ~ r~ _ ~ i l ~st � a � " ,~''.'~.yr, . _ . . r,;~`"r:i�. _ �1� 9 ;�t~ ~ Figure 2. The Command Transmitter. Control section on left, output section at right. ~ The RF exciter signal is fed from the frequency-modulated crystal oscillator through the multiplier to the amplifier stage. The RF exciter feeds a power of 10 W at half the working frequency into the cable which connects the con- trol section with the output section. The exciter output is protected from short circuits and disconnection. The exciter uses conventional semiconductor circuitry. Its specifications are given in Table 1. The control panel, assem- bled from the Mozaika kit, includes all of the transmitter's control and moni- toring components, command buttons and a digital clock. It indicates the cur- rent output power of the exciter and the output and reflected power of the power amplif.ier. The temperature of the output-section cooling devices and of the transformer windings in the power supplies is monitored. If an excessive tem- perature occurs in any location, an audible signal is given. The correctness of the emitted signal is evaluated by comparing the detected and decoded RF sig- nal with the resulting code combination and is indicated visually. The output section is installed in a nonairconditioned vehicle to whose roof the transmitting antenna is attached. Thus it is exposed to temperatures from -25� to +55�C. In formulating the requirements it was assumed that a reserve power of 13 dB would suffice in all extreme cases, and accordingly it was determined that the output power of the command transmitter would be 200 W. The KT 922 V output transistors which were available can put out only 40 W, or 70 W in a balanced connection. The extreme requirements for command-link reliability could be met only by redundancy of the circuits with the lowest reliability. Many years' experience with RF power amplifiers indicates that it is they, and = narticularly their power transistors, which are the most critical part of the transmitter. Accordingly we sought a design which would make it possible to combine the outputs of the main amplifiers in such a way as to achieve the 12 FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2407102/09: CIA-RDP82-00850R000400440007-6 FOR OFFtCIAI. USE ONI,ti' D , ~ 4 :1 KT 922 V ' Dy OZ - SZ D iC H~ H? f:2 ~ 9;! Kr922B 2~1 ~ ~ ~ ~ : < KT 922 V P(W 1 1 10 60 Z(Q) ~ 3~5 2 50 Figure 3. Wiring of Main Power Module operation is different (the power divider must be scaled to a considerably higher power). It is worth noting that the power coupler increa~es resistance to breaks and shorts (it decreases CSV~ to CSV 5). To the output of the paralleler is connected a 7-component Chebyshev low-pass filter, followed by a stripline reflectometer. The reflectometer outputs are used for indication and the reflected power output for protection against mis- matching. The divider is connected to the multiplier and amplifier cascade, which uses conventional circuitry, whose power amplification is controlled by the reflectometer (protection against mismatch). Details of this amplifier de- sign are given in reference 2. Figure 4 shows a block diagram and Figure 5 a photograph of the unit. The importance of this mastering of wideband microwave power amplifier technology and of power coupling on the order of hundreds of watts goes beyond the confines of the Magion project. Altered versions are usable for a number of other applications in the frequency range from 150 to - 185 MHz in both mobile networks, public radiotelephone networks an3 other ground- based radio communications. But in essence the route to transistorization of medium-power transmitters has been opened, and the result in prolonged, demand- ing operation has been positive. z, " " " ' zoo w ~ !50 HHr 50 4 D a ~ 2 D -i~ I~ H1 refl - O.Sw ~ ~lw j~ ?5 HNt ISOHHt yl I ~ I f' ~ ~ 50 4 . , . LL._1J---- _I I I ~ ~S _ , , s! b Pm. Pnl~nC Figure 4. Power Section of Command Transmitter Key: H1. Hybrid divider a. Reflectometer H2. Hybrid coupler b. Reflected power Z1-Z4. Main power modules c. Transmitted power _ 13 FOR OFF[CIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-04850R000400040007-6 FOR OFFICIAL Table 1. Transmitter Specifications Ground-based transmitter Onboard transmitter Specification Exciter Power amplifier 137 MHz 400 Mhz Working frequency (MHz) 74-75 148-150 137.150 400.01 Frequency stability 2 x 10-5 2 x 10-5 2 x 10-5 5 x 10-8 Short-term frequency not spec. not spec. not spec. 3 x 10-11 stability (1 second) Type of modulation FP'I FM ~ M Modulation shift 2.5 kHz 5 kHz 10 kHz 80� Maximum modulating 3.4 3.4 50 kHz 40 kHz frequency (kHz) Modulation distortion 2 2 l 2 (percent) Suppression of spurious 60 60 50 60 emissions (dB) Temperature stability(�C) +5 to ~45 -25 to +55 -50 to +60 -20 to +50 the required power and to assure that the breakdown of one or more amplifiers would not affect the operati~n of the others, and finally so that the amplifier would be operational for a long period even if certain of the power transistors ~ broke down. A solution was found in conphasal paralleling, achieved by means of line ("impedance") transformers. This paralleling arrangement can be made in a rather wide-band design which util- izes the superior isolating properties of the individual amplifier branches. But their output powers can be paralleled only in the case of good conphasality (~~p ~ 5�) and long-term phase stability. But these preconditions can be achieved only with broadband amplifiers. The ultimate design of the basic amplifier module is shown in Figure 3. The amplifier module contains two bypass sections utilizing ]..ine ("impedance") transformers, whose properties and manufacture are described, for example, in ref~rence 3. The amplifier is a two-stage design: the first transistor (exciter) is matched to an input impedance of 50 ohms and feeds a hybrid divider which is connected to the two-element final stage. The impedance of the divider is matched to the base of the final-stage transistors by 4:1 line transformers, while 1:4 line transformers match the collectors to the hybrid coupler, whose output impedance is again 50 ohms. The amplifier is absolutely stable in the entire range of working temperatures and the phas e stability is excellent. At the amplifier output is a circuit which allows the amplifier phase to be adjusted to the desired value. These four modules are paralleled by means of a conphasal rower coupler at the output and a conphasal power divider at the input. The divider and coupler are similarly connected, and their functions are reciprocal, but their actual ll~ FOR QFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00854R004400040007-6 FOR OFFICIAL USE ONLY o,zs w f37 nHr � -[]--~"-~--0 , 3 ~ D ~ _ moa. ~ ' ~ ~ 4 r ek Figure 5. Group Wirin~ of 137 MHz Transmitter 4. The Onboard Transmitters The transmitters on board the satellite are used to identify the satellite and to transm~t telemetric data of a service character (information on the condi- tion, operating regime and operating conditions of the satellite's onboard equipment) and scientific data and make it possible to measure certain parameters of the satell.ite's orbit. The frequencies in the 137 and 400 MHz bands are re- served for this type of communications. The 137 MHz band is a standard band and all the countries cooperating in the Interkosmos program are equipped for reception in it. The 137 MHz band is, however, relatively crowded, there is interference with other services, and it is designated for only narrow-band transmissions. Nor is it suitable for determining precise orbital parameters, for the ionosphere still affects the phase of the reflected signal. The 400 Mfiz band can be used both for precise orbit determinations and for broadband trans- mission, however, requires a higher transmitter power. In the initial communications design it was necessary to allow also for power levels on the satellite: the average energy drawn from the solar batteries was not to exceed 3 W, including 0.7 W consumed by constantly-on instrumentation. Accordingly it was decided to use the specific properties of both frequency bands and to carry out communications by means of a pair of transmitters. 5. The 137 MHz Transmitter The transmitter in this band was given the role of the basic, constantly oper- ating transmitter, functioning in the "beacon" mode from the moment of separa- tion. In this mode it transmits a keyed carrier with a repetition frequency proportional to the voltage in the onboard electrical system and with a rest- to-signal ratio proportional to the temperature of the satellite. Operation in the "beacon" mode makes it possible to identify thesatellite, track its orbit and perform basic monitoring of the condition of the onboard batteries and the temperature of the satellite. The satellite changes to the telemetry-data-transmission mode only on command from the control station. This involves so-called "slow telemetry," in which a series of service data (up to 200 monitored satellite parameters) and certain slowly-changing output values of the scientific apparatus can be transmitted in time-division form via the subcarrier. In telemetric monitoring it is possible to duplicate the transmission of certain data intended to be transmitted on the other transmitter. Thus the 137 MHz transmitter is the basic piece of satellite 15 FOR OFF[C[AL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2407102/09: CIA-RDP82-00850R000400440007-6 F(DR OFFICIAL USE ONLY instrumentation. If it were to carry out all of the required functions in a widc temperature range (for which only estimated absolute values were available) and in a wide voltage interval with high reliability and low power consumption, it would be necessary to choose a simple, well-tested and nonproblematical design. There was no experience at all with nonsealed, nonclimate-controlled satellites. Accordingly, allowance was made for operating temperatures from -4(i� to +60�C in a temperature regime which guaranteed all parameters between -30� and +50�C, - assuming battery voltage variation between 8 and 13.5 V. The transmitter conception is evident from Figure 6. The paraiaeters are given in Table l. In particular, it is necessary to raise the frequency stability, considering that it involves a modulated oscillator and an extreme operating regime. The oscillator circuitry is given in reference 4. The transmitter not only achieved the required parameters, but also attained operability in a wider range than was required, as shown in Figures 7 and 8. 3 I NI 0, J ~ al 6 N 02 5 4 ~ ' I 2~ ~e/~ ~ , I AU 40 -20 0 +20 * 40 :~['C ~ Figure 6. Output Power and Frequency Stability of 137 MHz Transmitter as a Function of Temperature 3., I . a p 40 rr ~ 0, J 70 ~ _ J, ~ 20 ~ i 0,1 f0 --.r--.~.~ ~ r---r~--r- 5 6 i 8 9 10 11 f2 U[V) 1~ Figure 7. Output Power and Efficiency of 137 MHz Transmitter as a Function of Onboard Power Supply Voltage 16 FOR OFF[CIAL USE ONLY APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-00850R000400040007-6 APPROVED FOR RELEASE: 2007/02/09: CIA-RDP82-04850R000400040007-6 FOR ONFIC'IA1. USN: C)Nl.ti' . ~ f~ _ ~ p- - p -r ~ ~ J ~ � nHZ lo nHr _ ~ D Ht -9F .~W~. O I I ;2 ~ Q ~w _ ~ ~ ~