IFAC SYMPOSIA SERIES Editor-in-Chief JANOS GERTLER, Department of Electrical Engineering, George Mason University, Fairfax, Virginia 22030, USA JOHNSON et al.\ Adaptive Systems in Control and Signal Processing {1990, No. 1) ISIDORI: Nonlinear Control Systems Design {1990, No. 2) AMOUROUX & EL JAI: Control of Distributed Parameter Systems {1990, No. 3) CHRISTODOULAKIS: Dynamic Modelling and Control of National Economies {1990, No. 4) HUSSON: Advanced Information Processing in Automatic Control {1990, No. 5) NISHIMURA: Automatic Control in Aerospace {1990, No. 6) RIJNSDORP et al: Dynamics and Control of Chemical Reactors, Distillation Columns and Batch Processes (DYCORD '89) {1990, No. 7) UHI AHN: Power Systems and Power Plant Control {1990, No. 8) REINISCH & THOMA: Large Scale Systems: Theory and Applications {1990, No. 9) KOPPEL: Automation in Mining, Mineral and Metal Processing {1990, No. 10) BAOSHENG HU: Analysis, Design and Evaluation of Man-Machine Systems {1990, No. 11) PERRIN: Control, Computers, Communications in Transportation {1990, No. 12) PUENTE 8c NEMES: Information Control Problems in Manufacturing Technology {1990, No. 13) NISHIKAWA & KAYA: Energy Systems, Management and Economics {1990, No. 14) DE CARLI: Low Cost Automation: Components, Instruments, Techniques and Applications {1990, No. 15) KOPACEK, MORITZ & CENSER: Skill Based Automated Production {1990, No. 16) COBELLI 8c MARIANI: Modelling and Control in Biomedical Systems {1989, No. 1) MACLEOD 8c HEHER: Software for Computer Control (SOCOCO '88) {1989, No. 2) RANTA: Analysis, Design and Evaluation of Man-Machine Systems {1989, No. 3) MLADENOV: Distributed Intelligence Systems: Methods and Applications {1989, No. 4) LINKENS 8c ATHERTON: Trends in Control and Measurement Education {1989, No. 5) KUMMEL: Adaptive Control of Chemical Processes {1989, No. 6) CHEN ZHEN-YU: Computer Aided Design in Control Systems {1989, No. 7) CHEN HAN-FU: Identification and System Parameter Estimation {1989, No. 8) CALVAER: Power Systems, Modelling and Control Applications {1989, No. 9) REMBOLD: Robot Control (SYROCO '88) {1989, No. 10) JELLALI: Systems Analysis Applied to Management of Water Resources {1989, No. 11) Other IFAC Publications AUTOMATICA the journal of IFAC, the International Federation of Automatic Control Editor-in-Chief: G. S. Axelby, 211 Coronet Drive, North Linthicum, Maryland 21090, USA IFAC WORKSHOP SERIES Editor-in-Chief: Pieter Eykhoff, University of Technology, NL-5600 MB Eindhoven, The Netherlands Full list of IFAC Publications appears at the end of this volume NOTICE TO READERS If your library is not already a standing/continuation order customer or subscriber to this series, may we recommend that you place a standing/ continuation or subscription order to receive immediately upon publication all new volumes. Should you find that these volumes no longer serve your needs your order can be cancelled at any time without notice. Copies of all previously published volumes are available. A fully descriptive catalogue will be gladly sent on request. ROBERT MAXWELL Publisher A U T O M A T IC C O N T R OL IN A E R O S P A CE Selected papers from the IFAC Symposium, Tsukuba, Japan, 17-21 July 1989 Edited by T. NISHIMURA Institute of Space and Astronautical Science, Sagamihara, Japan Published for the INTERNATIONAL FEDERATION OF AUTOMATIC CONTROL by PERGAMON PRESS Member of Maxwell Macmillan Pergamon Publishing Corporation OXFORD · NEW YORK · BEIJING · FRANKFURT SAO PAULO · SYDNEY · TOKYO · TORONTO U.K. Pergamon Press pic, Headington Hill Hall, Oxford OX3 OBW, England U.S.A. Pergamon Press, Inc., Maxwell House, Fairview Park, Elmsford, New York 10523, U.S.A. PEOPLE'S REPUBLIC Pergamon Press, Room 4037, Qianmen Hotel, Beijing, People's Republic of China OF CHINA FEDERAL REPUBLIC Pergamon Press GmbH, Hammerweg 6, D-6242 Kronberg, Federal Republic of Germany OF GERMANY BRAZIL Pergamon Editora Ltda, Rua Ega de Queiros, 346, CEP 04011, Paraiso, Sao Paulo, Brazil AUSTRALIA Pergamon Press Australia Pty Ltd., P.O. Box 544, Potts Point, N.S.W. 2011, Australia JAPAN Pergamon Press,. 5th Floor, Matsuoka Central Building, I-7-1 Nishishinjuku, Shinjuku-ku, Tokyo 160, Japan CANADA Pergamon Press Canada Ltd., Suite No. 271, 253 College Street, Toronto, Ontario, Canada M5T 1R5 Copyright© 1990 IFAC AU Rights Resenied. No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means: electronic, electrostatic, magnetic tape, mechanical, photocopying, recording or other­ wise, without permission in wnting from the copyright holders. First edition 1990 Library of Congress Cataloging in Publication Data Automatic control in aerospace: selected papers from the IFAC symposium, Tsukuba, Japan, 17-21 July 1989/edited by T. Nishimura. —1st ed. p. cm.—(IFAC symposia series: 1990, no. 6) I. Airplanes—Control system—Congresses. 2. Space vehicles— Control systems—Congresses. I. Nishimura, T. (Toshimitsu), 1930- II. International Federation of Automatic Control. III. Series. TL678.A93 1990 629.132'6—dc20 90-31776 British Library Cataloguing in Publication Data Automatic control in aerospace I. Space vehicles. Automatic control I. Nishimura, T. II. International Federation of Automatic Control III. Series 629.4742 ISBN 0-08-037027-6 These proceedings were reproduced by means of the photo-offset process using the manuscripts supplied by the authors of the different papers. The manuscripts have been typed using different typewriters and typefaces. The lay-out, figures and tables of some papers did not agree completely with the standard requirements: consequently the reproduction does not display complete uniformity. To ensure rapid publication this discrepancy could not be changed: nor could the English be checked completely. Therefore, the readers are asked to excuse any deficiencies of this publication which may be due to the above mentioned reasons. The Editor Printed in Great Britain by BPCC Wheatons Ltd, Exeter IFAC SYMPOSIUM ON A U T O M A T IC CONTROL IN AEROSPACE sponsored by Technical Committee on Aerospace (IFAC) Co-sponsored by The Japan Society for Aeronautical and Space Sciences Liaison Committee with IFAC TC Aerospace Society of Instrument and Control Engineers of Japan Technical Committee on Guidance and Control in Aerospace Institute of Electronics, Information and Communication Engineers Technical Group on Space, Aeronautical and Navigational Electronics Organized by Japanese IFAC Aerospace Symposium Organizing Committee International Programme Committee D. B. DeBra, USA (Chairman) A. H. Reynaud, Canada G. Bertoni, Italy J.J. Rodden, USA E. Gottzein, FRG A. J. Sarnecki, UK S. C. Gupta, India D. N. Soo W. Haeussermann, USA T. Tanabe, Japan M. Higashiguchi, Japan H. Tolle, FRG J. W. Hursh, USA I. N. Vasiljev, USSR Yangjia-Chi, PRC P. Y. Willems, Belgium P. Kant, The Netherlands W. Wimmer K. R. Lorell, USA H.-D. Zago M.J. Pelegrin, France National Organizing Committee T. Tanabe (Chairman) T. Nakao K. Fukuizumi K. Ninomiya M. Higashiguchi T. Nishimura H.Ihara M. Ghara M.Ikeuchi Y. Ohkami M. Kamata S. Sakano K. Kanai R. Seo Y. Kosaka M. Shigehara H. Koshiishi J. Tabata T. Kumazawa Y. Takizawa H. Kurokawa M. Torii M. Kusanagi N. Yajima K. Machida H. Yamamoto S. Manabe T. Yasaka N. Nagao Advisers T. Godai H. Maeda H. Nagasu T. Nomura Copyright © IFAC Automatic Control in PLENARY SESSION Aerospace, Tsukuba, Japan, 1989 NASDA'S LONG-RANGE PLAN AND AUTOMATIC CONTROL M. Nagatomo Program Planning and Management Department, National Space Development Agency of Japan (Ν AS DA), Tokyo, Japan Abstract. A long-range plan of NASDA's space development, until the beginning of the 21st century and thereafter, is outlined, and automatic control-related features and technologies of the space systems appearing in this long-range plan are described. Currently, NASDA is developing world-level rockets and satellites such as the H-II rocket and the Engineering Test Satellite-VI (ETS-VI). And, NASDA is about to develop the Japanese Experiment Module (JEM) participating in the International Space Station (ISS) program. In the future, NASDA intends to place emphasis on the development of the space infrastructure including such future space systems as the H-II Orbiting Plane (HOPE), the H-II derived rockets, the Rocket Plane (RP), space-to-space transportation systems, the Data Relay and Tracking Satellite (DRTS), manned space facilities, various platforms, etc. And, the space infrastructure around the earth will be extended to the moon and planets. The space infrastructure will be developed economically by employing unmanned systems as much as possible, safely by employing fully-automatic, manned systems, and efficiently by promoting international cooperation with autonomy. keywords. Actuators; Attitude control; Guidance systems; Manipulation; Navigation; Robots; Satellites, artificial; Sensors; Space vehicles; Strapdown systems. 1. INTRODUCTION (l)From now until the first half of the 1990s, the establishment of original and NASDA has been conducting space fundamental technologies for large-scale development in various fields over the rockets and satellites, which Japan should past 19 years. NASDA had developed the own, are to be pursued through the N-I, N-II, and H-I rockets, and has been development of the H-II rocket and the developing the H-II rocket capable of ETS-VI. The development of space launching a two-ton class geostationary Infrastructure, Including the JEM, which satellite and equipped with cryogenic is a foundation for space activities, will (L0X/LH2) engines. And, NASDA has been be pursued. developing communications, broadcasting, meteorological observations, earth (2)From the last half of the 1990s to the observations, and engineering test beginning of the 21st century, the satellites Including the Engineering Test operation of the JEM, and the development Satellite-VI (ETS-VI) weighing about two and operation of space Infrastructure tons in a geostationary orbit and equiped around the manned space station of the ISS with an Ion engine system for nortii-south program will be advanced. This will orbit control. Through the development of promote manned space activities and the H-II rocket and the ETS-VI, NASDA Is encourage the space Industry to become well on Its way to acquire world-level self-supporting. The exploration of the technologies of lauch vehicles and moon and planets will be also started. satellites. In addition to the activities mentioned above, NASDA has been conducting Under these basic directions, a long-range the First Material Processing Test (FMPT) plan on the development of space program utilizing the Space Shuttle, and infrastructure and the evolution of manned is about to start the development of the space activities, extended until the Japanese Experiment Module (JEM) attached beginning of the 21st century, has been to the manned space station of the investigated as follows: International Space Station (ISS) program. From now until the first half of the Based on the space development conducted 1990s, the development of the JEM will be so far, NASDA will pursue Its space advanced. At the same time, the development in line with the following utilization of the Space Flyer Unit (SFU) directions, solely for peaceful purposes, for microgravity experiments, the aiming at acquiring the capability to acquirement of manned support technologies promote autonomous space activities by through the FMPT program, the preparation developing world-level, domestic of training facilities required for manned technologies and extending positively space systems, and the preparation of the International cooperation suitable to support systems to promote the utilization Japan's role in international society: of microgravity environment in space will be accomplished. Furthermore, the research 1 Μ. Nagatomo and development of inter-satellite entirely with domestic technologies to communications will be promoted for the contribute to world space activities. The operation of the JEM, etc. Besides, the H-II rocket and the H-II derived rockets development of the H-II rocket equipped under study will be used not only to with a strapped-down inertial guidance launch satellites but also to support the system utilizing laser-gyros will be operation of space infrastructure. advanced. And, the research and development of an unmanned, winged (1) H-I Rocket recovery vehicle launched by the H-II rocket (HOPE), capable of performing The H-I rocket is a current Japan's main rendezvous-docking and automatic landing« launch vehicle. Four launches of the will be promoted. Furthermore, the rocket have been successfully made to precursor research and development of a launch a geodetic satellite, an rocket plane, a fully-resusable, winged engineering test satellite and two rocket, and a space plane will be also communications satellites since the first promoted. one was successfully made in August 1986. In the latter half of the 1990s, the The H-I rocket is a two or three-stage operation of the JEM/ISS will be rocket capable of launching an about 550 commenced. The development of an orbital kg satellite into a geostationary orbit. maneuvering vehicle equipped with robot It is about 40 meters in total length and arms, the development and operation of a 2.5 meters in outside diameter. Its co-orbiting platform enabling long lift-off weight is about 140 tons. The duration experiments under better first stage, strap on boosters and microgravity environment, and the payloard fairing are the same as those of development of a Japan's own polar the former N-II rocket. However, the orbiting platform forming a community of second stage, the third stage and the international polar orbiting platforms inertial guidance system were newly will be implemented. And, materials will developed using Japanese own technologies. be trnsported using the H-II rocket, the The second stage is equipped with a HOPE, and H-II derived rockets. The high-performance liquid-oxygen and research and development of a rocket plane liquid-hydrogen engine, called the LE-5 and/or a space plane will be promoted. engine, with a restart capability. The Furthermore, an space operation and data third stage is equipped with a solid system employing data relay satellites for rocket motor. inter-satellite communications, a landing facility from space, etc. will be completed. w In the beginning of the 21st century, the utilization of the JEM/ISS will be extended, a manned platform will be developed and operated, and the development of a rocket plane and/or a space plane will be promoted for operation 1. ?ArL0*3 fAiHiNC : »*^LOAO ATAC FiTTlKC 3 Tt<(fl:$7*c£s:iiow2:o« in the primary stage. Furthermore, the I£. «CCUA.O*ATN{RC fS £SC£TCl:3iOr.'K S SiCOMC STACt tHQ'Hi Geostationary Platform (GPF) and an orbital transfer vehicle to trnsport the 13 $Ti4» OK lOCSTt* U SCIRT SECTIW 15 £7AGt MAIM l»<Cl>is GPF from a low earth orbit to a Fig. 2.1. Congiguration of the H-I rocket geostationary orbit will be developed. The inertial guidance system called NICE The evolution of space activities after is installed at the top of the second the beginning of the 21st century has been stage. It is a stable platform type investigated as follows: inertial guidance system and consists of Inertial Measurement Unit (IMU) and Japan's own space station forming a Inertial Guidance Computer (IGC). IMU community of international space stations consists of Inertial Platform Unit (IPU) will be constructed and operated. And, a and Platform Electronics Unit (PEU). IPU large-scale space factories utilizing the houses three rate-integrating gyros and space station as a base will be three accelerometers mounted on a constructed and operated, while a low-cost 4-gimbal-axis platform. Rate gyros are transportation system will be al^o installed both in the first and second completed and placed in service. stages. The principal functions of NICE Furthermore, exploration activities in are navigation, guidance adopting an space will be extended to ones such as the explicit steering law, attitude control, routine observation of space from an flight sequence control, tank pressure in-orbit astronomical observatory, the control, etc. Attitude control moments are direct exploration of celestial bodies in obtained by the gimbal actuation systems the solar system, and sample returns. of the main and vernier engines for the first stage, and by the gimbal actuation systems of the main engine and the 2. SPACE TRANSPORTATION reaction control systems for the second SYSTEM stage. NASDA has been developing the expendable The H-I rocket will be used as a main satellite launch vehicles of the N-I, launch vehicle of Japan until the N-II. H-I and H-II rockets. The N-I and beginning of the 1990s. Five more launches N-II rockets were already phased out, the of the H-I rocket are scheduled to be made H-I rocket is now under operation, and the from 1989 through 1992 to launch a H-II rocket is now under development. The geostationary meteorological satellite, main parts of the H-I rocket were two earth observation satellites and two developed domestically to meet Japan's broadcasting satellites of Japan. satellite launch demands. On the other hand, the H-II rocket is to be developed NASDA's Long-range Plan and Automatic Control pre-launch inspection and monitor. Guidance accuracy is estimated to be 250 km (3-sigma) in apogee altitude and 0.03 C»*«TC« ^ deg (3-sigma) in inclination angle of a II geostationary transfer orbit. i««swcf«tn U-JT .IHIjJ Payload fairing Payload attachment fitting Guidance section 2nd-stage LH tank 2nd-stage LOX tank Inter-stage 2nd-stage engine '(LE-5A) lst-stage LOX tank Center body seclion Fig. 2.2. Guidance and control system of the H-I rocket ist-stage LH tank (2) H-II Rocket A Japan's main launch vehicle In the 1990s will be the H-II rocket, a successor of the H-I rocket. The H-II rocket is under development aiming at the first test flight in 1992. It is to be developed 1st-stage entirely with Japanese technologies based engine section Auxiliary engine on the experiences obtained through the development of the H-I rocket. lst-stage main enaine Solid rocket (LE-7) The H-II rocket is a two-stage launch booster vehicle capable of launching a geostationary satellite weighing about 2.2 Fig. 2.3. Configuration of the H-II rocket tons. It Is also capable of launching multiple payloads, totaling 2 tons, Μ * in STACC simultaneously into a geostationary orbit. Liquid-oxygen and liquid-hydrogen engines ^v. L ~¥ «···. ^·ττπ.; are adopted both for the first stage and I -γ- ^ for the second stage, and two large solid boosters are attached to the first stage. The H-II rocket is A meters in diameter and 49 meters in height. Each solid booster is 1.8 meters in diameter and 23 meters in height. The H-II rocket weighs about 260 tons at lift off. A new liquid oxygen and liquid-hydrogen engine, called the LE-7 engine, is under development for the first stage. The LE-7 engine is a high performance engine adopting a high-pressure staged-combustion cycle, and can make a thrust of about 93 tons at sea level. The improved version of the LE-5 engine, called the LE-5A engine, is under development for the second stage. Each solid booster makes a thrust of 160 Fig. 2.4. Guidance and control syste of tons at sea level and is equipped with a the H-II rocket movable nozzle for thrust vector control. The system is installed on the top of the A strapped-down inertial guidance system second stage and consists of Inertial was selected for the guidance and control Measurement Unit (IMU), Inertial Guidance system of the H-II rocket, because of its Computer (IGC), Inertail Guidance Program superior mission flexibility and high (IGP). Data Interface Unit (DIU). Control reliability. The functions of the system Electronics Packages (E-PKGs) and Lateral are initial alignment, navigation, Acceleration Measurement Unit (LAMU). IMU guidance, attitude control, sequence contains three ring laser gyros (RLGs) and control, propulsion system control, three accelerometers. RLG has many Μ. Nagatomo advantages such as wide range of input capability, reliability, launch cost, rate, high reliability, no etc., it will contribute to world acceleration-sensitive drift, etc. over a satellite launch demands. The H-II rocket conventional gyro. LAMU contains two will be used not only for satellite accelerometers on pitch and yaw axes, launches but also for materials supply to whose data are used for load relief the International Space Station. control at the maximum point of dynamic pressure. The IMU's and LAMU's data are (3) H-II Derived Rockets sent to IGC/IGP at a rate of 32 samples per second, and IGC/IGP makes a As the construction and operation of such computation of navigation and guidance at space facilities as the International a rate of 1 Hz and that of attitude Space Station will start, space control at a rate of 32 Hz. transportation demands will increase in the latter half of the 1990s and NASDA plans to launch a total of three thereafter. To cope with this situation, TR-I test rockets which obtain the NASDA is studying the performance necessary technical data, and also confirm improvement of the H-II rocket. The the functions of the subsystems for the easiest option to increase the launch H-II design. The first two TR-Is flew in capability of the H-II rocket is to add summer 1988 and winter 1989. The third, two or four more solid boosters. The last TR-I is scheduled to be launched in option having six solid boosters can lift this summer. There are two main objectives about 15 tons into a 300 km orbit, as of the TR-I mission. The first objective compared to the H-II rocket which lifts is to obtain flight data, such as about 10 tons into the same orbit. aerodynamic pressure , heat, sound and vibration generated by the atmospheric More significant improvement can be effects on the vehicle through flight. The obtained by attaching two large second objective is to confirm the liquid-fuelled boosters with two solid function of the Solid Rocket Booster (SRB) boosters. The option having two liquid separation mechanism. The TR-I is a oxygen and hydrogen boosters each with the single-stage rocket, one-quarter the size LE-7 engine, which is almost equivalent to of the H-II rocket. It is 14.3 meters in the option strapping three H-II first overall length, 1.1 meters in diameter, stages together, can lift about 24 tons and weighs about 11.8 tons. into a 300 km orbit. Even higher performance and lower operation cost will Adapter come from adopting a liquid oxygen and Section hydrocarbon booster. The option having two liquid oxygen and hydrocarbon boosters can lift about 34 tons into a 300 km orbit. SRB Front Separation Sect ion Nose A more advanced option adopting the airbreathing engine such as the Liquid Air Fairing On-board Cycle Engine (LACE) is also studied. An Equipment airbreathing engine has an advantage that Section it can reduce the amount of a liquid On-board oxygen consumption, because it uses air as Equipment an oxidizer during the early phase of its Recovery Section flight. Equipment^ 3. SPACE UTILIZATION SYSTEM Separation Plane Solid Fueled Space utilization systems are divided into Rocket Motor space position utilization systems and SRB Rear space environment utilization systems. Separation Dummy SRB Space position utilization systems are the Section space utilization systems which utilize such positions of space as geostationary Tail Fin orbits and polar orbits for communications, broadcasting, Solid Motor meteorological observation and earth Roll Control observation. On the other hand, space Unit (SMRC) environment utilization systems are the space utilization systems which utilize the microgravity environment of space for material processing and life science experiments. Fig. 2.5. Configuration of the TR-I rocket 3.1. Engineering Test Satellites A new launch site for the H-II rocket is Engineering test satellites have been under construction in the Tanegashima developed aiming at the establishment of Space Center located in the southern the basic technologies of satellites to island of Japan. The H-II rocket will be apply those to future practical used as a main rocket of Japan from the satellites. The last engineering test beginning of the 1990s to launch various satellite was Engineering Test Satellite-V payloads. In the first half of the 1990s, (ETS-V) weighing about 550 kg which was an engineering test satellite, a successfully launched into a geostationary microgravity experiment satellite, a orbit using the three-stage H-I test geostationary meteorological satellite and rocket in August 1987. It established the an earth observation satellite of Japan basic technologies needed for are scheduled to be launched using the geostationary three-axis stabilized H-II rocket. Since the H-II rocket is at satellite bus systems and has been high level in such points as launch successfully carrying out mobile satellite NASDA's Long-range Plan and Automatic Control comeunications experiment with aircrafts, has many remarkable features as follows: ships and automobiles taking the The ETS-VI is a box-type satellite with initiative in the world. the design lifetime of 10 years for satellite bus and the end-of-life power of (1) ETS-VI. The Engineering Test 4,100 W at summer solstice. A truss type Satellite-VI (ETS-VI), a three-axis tower to hold three antennas extends about stabilized geostationary satellite 5 meters from the earth-facing panel. Two weighing about 2 tons is under development solar arrays extend about 15 meters each and scheduled to be launched in 1992 using from the south-facing and north-facing the H-II rocket. The main objectives of panels. Each solar array wing has four the ETS-VI project are to establish the hinged light-weight semi-rigid panels with satellite bus system which meets the 50 micron meters thick silicon solar requirements in the field of satellite cells. The payload mass including the communications and broadcasting in the tower is more than 660 kg. Other major 1990s, and to demonstrate advanced design features are use of a restartable technologies on advanced fixed satellite bipropellant 2,000 Ν engine for apogee communications, mobile satellite maneuvers. 25 mN Xenon-fueled ion engines communications, and inter-satellite for north-south station-keeping, communications needed in the 1990s. The large-scale, light-weight body structure, and many Hybrid IC's and LSI's for technologies on inter-satellite reducing components weight. communications will be used for the development of the Data Relay and Tracking Satellite (DRTS) which is a key subsystem The attitude control system (ACS) of the of the Space Operarion and Data System ETS-VI is a microprocessor based zero (SODS) . momentum three-axis control system using four skew-mounted reaction wheels. The ACS has many remarkaible features as follows: TTC Anc«nn« Sol*r Ψ·4ΑΙ· Hi eiab«l«d ikr.t«MM <or -High accuracy attitude control Sin$:« Acne* CeMMAic«ti*ni Attitude control errors are less than 0.05 degrees for roll and pitch axes, and less than 0.15 degrees for yaw axis in S'hiii riMMj Arrey AAMIMA for geostationary orbit. To achieve the Xr.t*r-Mt«i:iM CsMKnicaCion* accuracy, precise earth sensors (ESA) are lSAtrXufc«t-; ae«l* ii9nt--*i5fti tody used mainly for roll and pitch axes control, and a strap down control system •Λ1Λ Silisso with the Inertial Reference Unit (IRU) is se:«r c«::« employed for yaw axis control. -Tree axis control in transfer orbit A three-axis stabilized attitude control system is employed in transfer orbit, too. The Fine Sun Sensor.(FSS) and the IRU are used for yaw axis control, the FSS and the Rate Integral Gyro (RIGA) are used for pitch axis control, and the IRU is used for rol axis control. The ESA is used for the IRU calibration at specific period in transfer orbit. -Autonomous functions The ACS adopted many autonomous functions, Fig. 3.1.1. Configuration of the ETS-VI some are to eliminate ground operations, others are to increase survivability. The formers are initial acquisition sequences from separation to sun acquisition in :<-b*r.d/C-b*.-ici transfer orbit, auto unloading, auto gyro calibration and auto sun biasing. The latters are fault tolerant functions by duplex CPU operation, auto switching to redundant components in case of failure and auto sun acquisition in case of loss of earth. -Re-programing capability The ACS flight software can be re-programmed on orbit from ground command to change the control parameters or software program if required and it is also used for experimental purpose to evaluate the advanced control technologies. The K-band Single Access (KSA) antenna system is mounted on the earth-facing panel of the main body to demonstrate the advanced technology of inter-satellite communications. The KSA antenna system has the Antenna Pointing Mechanism (APM) to acquire and track low earth orbit satellites such as the Advanced Earth Observing Satallite (ADEOS) and ground stations. The APM employs a 2-axis-gimbal system consisting of a stepping motor, a harmonic drive and a position indicator. Fig. 3.1.2. Exploded view of the ETS-VI M. Nagatomo demands and develop advanced satellite Ε» 3f we communications technologies. The third generation Communications Satellites (CS-3S), consisting of CS-3a and CS-3b, were launched in 1988 using the H-I ACE rocket. The CS-3 is a spin-stabilized RIM satellite weighing about 550kg and consisting of a despun section that is always directed towards the earth and a 90-rpm rotating spin section. The despun section holds a communications antenna while spin section contains transponders, bus equipments, etc. The CS-3 VCE communications subsystem contains ten channels at Ka band and two channels at C -ροε band. -RIU Fig. 3.1.3. Attitude Control System (ACS) of the ETS-VI Fig. 3.1.4. Configuration of the Antenna Pointing Mechanism (APM) Fig. 3.2.1. Configuration of the CS-3 An experiment on modal parameter identification, and attitude and vibration The design life time of CS-3 is seven control is planned to be performed as one years, therefore, the fourth genaration of the flight experiments of the ETS-VI Communications Satellites (CS-4s) will be having flexible appendages of two long necessary in 1995 for the continuation of solar paddles. Three accelerometers are the satallite communications service by mounted on each paddle to measure the the CS-3. As for the CS-4, a 2-ton class in-plane and out-of-plane bending modes. satelite using the ETS-VI bus is As for the modal parameter identification, considered to be necessary for increasing the spacecraft is excited by the thrusters and diversifying communications demands. of the RCS to cause the paddle vibration, and measured acceleration of the paddle 3.3 Broadcasting Satellites vibration is used for off-line modal analysis. As for the attitude and vibration control, controller parameters The direct broadcasting satellite series are tuned to be optimal values based on have been developed to meet increasing the identified modal parameters, and an broadcasting service demands and develop experiment of closed-loop attitude and advanced satellite broadcasting vibration control is performed. technologies. At present, the BS-2b, one of the second generation direct Broadcasting Satellites (BS-2s), is providing satellite broadcasting service. And, the third generation direct Broadcasting Satellites (BS-3s), consisting of BS-3a and BS-3b, are now being developed by NASDA, and scheduled to be launched in 1990 and 1991, respectively, using the H-I rockets. The design life time of the BS-3 is seven years, therefore, the fourth genaration direct Broadcasting Satellites (BS-4s) will be necessary in 1997 and 1998 for the continuation of the satallite broadcasting service by the BS-3. As for the BS-4, a PITCH few concepts including a 2-ton class satelite using the ETS-VI bus are studied to meet increasing and diversifying Fig. 3.1.5. Accelerometer locations for broadcasting demands. the attitude and vibration control experiments (1) BS-3. The BS-3 is a box-type and a The Communications Satellite series have three-axis stabilized satellite weighing been developed to meet increasing and about 550 kg. The BS-3 carries three transponders with the output power of 120 diversifying domestic communications w or more in order to make three channels of color television broadcasting. The BS-3