"Soviet Robots in the Solar System"provides a history of the Soviet robotic lunar and planetary exploration program from its inception, with the attempted launch of a lunar impactor on September 23, 1958, to the last launch in the Russian national scientific space program in the 20th Century, Mars 96, on November 16, 1996. This title makes a unique contribution to understanding the scientific and engineering accomplishments of the Soviet Union s robotic space exploration enterprise from its infancy to its demise with the collapse of the Soviet Union. Theauthors provide a comprehensive account of Soviet robotic exploration of the Solar System for both popular space enthusiasts and professionals in the field. Technical details and science results are provided and put into an historical and political perspective in a single volume for the first time. The book is divided into two parts. Part I describes the key players and the key institutions that build and operate the hardware, the rockets that provide access to space, and the spacecraft that carry out the enterprise. Part II is about putting these pieces together to enable space flight and mission campaigns. Part II is written in chronological order beginning with the first launches to the Moon. Each chapter covers a particular period when specific mission campaigns were undertaken during celestially-determined launch windows. Each chapter begins with a short overview of the flight missions that occurred during the time period and the political and historical context for the flight mission campaigns, including what the Americans were doing at the time. The bulk of each chapter is devoted to the scientific and engineering details of that flight campaign. The spacecraft and payloads are examined with as much technical detail as is available today, the progress is described, and a synopsis of the scientific result is given.

In July 1969 the 'amiable strangers' that made up the crew of the historic Apollo 11 flight successfully achieved the first manned lunar landing. Several months later, three close friends set off on an even more challenging mission. Free of the burden of making history, the Apollo 12 astronauts were determined to really enjoy their experience while taking care of business. This is the story of their mission, told largely in their own words. Their exploits and accomplishments showed how conservative the inaugural mission had been. With its two moonwalks, deployment of the first geophysical station on the Moon, and geological sampling, Apollo 12 did what many had hoped would be achieved by the first men to land on the Moon. The Apollo 12 mission also spectacularly demonstrated the precision landing capability required for success in future lunar surface explorations. In addition to official documents, published prior to and after the mission, APOLLO 12 - ON THE OCEAN OF STORMS draws on the flight transcript and post-mission debriefing to recreate the drama.

This book presents a thorough treatment of plasma physics, beginning at an introductory level and proceeding to an extensive discussion of its applications in thermonuclear fusion research. The physics of fusion plasmas is explained mainly in relation to recent progress in tokamak research, but other plasma confinement schemes, such as stellarators and inertial confinement, are also described. The unique and systematic presentation will help readers to understand the overall structure of plasma theory.

The book gives an extended review of theoretical and observational aspects of neutron star physics. With masses comparable to that of the Sun and radii of about ten kilometres, neutron stars are the densest stars in the Universe. This book describes all layers of neutron stars, from the surface to the core, with the emphasis on their structure and equation of state. Theories of dense matter are reviewed, and used to construct neutron star models. Hypothetical strange quark stars and possible exotic phases in neutron star cores are also discussed. Also covered are the effects of strong magnetic fields in neutron star envelopes.

This is a benchmark reference work on Cryogenic Engineering which chronicles the major developments in the field. Starting with an historical background, this book reviews the development of data resources now available for cryogenic fields and properties of materials. It presents the latest changes in cryopreservation and the advances over the past 50 years. The book also highlights an exceptional reference listing to provide referral to more details.

Observations and physical concepts are interwoven to give basic explanations of phenomena and also show the limitations in these explanations and identify some fundamental questions.

Compared to conventional plasma physics textbooks this book focuses on the concepts relevant in the large-scale space plasmas. It combines basic concepts with current research and new observations in interplanetary space and in the magnetospheres.

Graduate students and young researchers starting to work in this special field of science, will find the numerous references to review articles as well as important original papers helpful to orientate themselves in the literature.

Emphasis is on energetic particles and their interaction with the plasma as examples for non-thermal phenomena, shocks and their role in particle acceleration as examples for non-linear phenomena.

This second edition has been updated and extended. Improvements include: the use of SI units; addition of recent results from SOHO and Ulysses; improved treatment of the magnetosphere as a dynamic phenomenon; text restructured to provide a closer coupling between basic physical concepts and observed complex phenomena.

Advances over the past decades in space flight technology have allowed U.S., Russian, and other space programs to not only increase the frequency of manned space flights but also to increase the duration of these flights. As such, a large body of knowledge has been developed regarding the ways in which space flight affects the health of the personnel involved. Now, for the first time, this body of clinical knowledge on how to diagnose and treat conditions that either develop during a mission or because of a mission has been compiled by Drs. Michael R. Barratt and Sam L. Pool of the NASA/Johnson Space Center. This text is a must have for all those associated with aerospace medicine.

Former NASA Astronaut Harrison Schmitt advocates a private, investor-based approach to returning humans to the Moon to extract Helium 3 for energy production, to use the Moon as a platform for science and manufacturing, and to establish permanent human colonies there in a kind of stepping stone community on the way to deeper space. With governments playing a supporting role just as they have in the development of modern commercial aeronautics and agricultural production Schmitt believes that a fundamentally private enterprise is the only type of organization capable of sustaining such an effort and, eventually, even making it pay off.

A comprehensive description of hybrid plasma simulation models providing a very useful summary and guide to the vast literature on this topic.

The purpose and motivation of these lectures can be summarized in the following two questions: * What is the ground state (and its properties) of dense matter? * What is the matter composition of a compact star? The two questions are, of course, strongly coupled to each other. Depending on your point of view, you can either consider the ?rst as the main question and the second as a consequence or application of the ?rst, or vice versa. If you are interested in fundamental questions in particle physics you may take the former point of view: you ask the question what happens to matter if you squeeze it more and more. This leads to fundamental questions because at some level of suf?cient squeezing you expect to reach the point where the fundamental degrees of freedom and their interactions become important. That is, at some point you will reach a form of matter where not molecules or atoms, but the constituents of an atom, namely neutrons, protons, and electrons, are the relevant degrees of freedom.

Today's astronauts require many different abilities. They must not only be expert in performing flight simulations but must also be proficient in such dissimilar subjects as photography, thermodynamics, electrical repairs, flight procedures, oceanography, public affairs, and geology. In Prepare for Launch, the author introduces the technologies and myriad activities that constitute or affect astronaut training, such as the part-task trainers, emergency procedures, the fixed-based and motion-based simulators, virtual environment training, and the demands of training in the Weightless Environment Training Facility. With plans to return to the Moon and future missions to Mars, the current selection criteria and training are very different from those used for short duration mission Space Shuttle crews. Dr. Erik Seedhouse in this book focuses on how astronaut candidates are taught to cope with different needs and environments (for example, hibernation, artificial gravity, and bioethics issues) and also includes brief discussions of the astronaut application and selection process.

The world s most populous nation views space as an asset, not only from a technological and commercial perspective, but also from a political and militaristic one. The repercussions of this ideology already extend far beyond Washington. China vs. United States offers a glimpse of future Chinese aspirations in space and the politico-militaristic implications of a looming space race, and explains why an interplanetary spaceship called the Tsien Hsue Shen might one day travel to the outer planets.

Until China successfully launched taikonauts into orbit, China s space program had attracted little international attention. The book opens with an analysis of the short fifteen-year history of the China National Space Administration and its long list of accomplishments. Chapter 2 assesses Sino-U.S. technological and commercial interests in space and their implications in fuelling a potential space race. The national security objectives of the U.S. and China are examined, showing how their intentions are increasingly leading to the military integration of space technologies. Chapter 3 describes China s anxieties about U.S. space power, its obsession with national prestige, and how manned spaceflight is viewed as a crucial element to sustain the legitimacy of the Communist Party. China is currently focusing on similar goals to those of NASA s Constellation Program - lunar and Mars exploration. The following chapter examines the ambitious plans of both nations, and evaluates whether China s bold goal of landing taikonauts on the Moon by 2020 is matched by the necessary capability.

In Chapter 5 Dr Seedhouse describes the space hardware being developed by the U.S. and China and the strides taken by China in its attempt to match the technological capability of the U.S. The following chapter provides an overview of China s introductory manned spaceflights and shows how, despite a lack of experience, the Chinese may soon be in a position to challenge the U.S. in a race to the Moon. In Chapter 7, the author discusses how China s manned space program can boost the country s international prestige and also examines the notion of manned spaceflight as a risky way to boost national status and the potential implications of a disaster akin to Challenger and Columbia.

Chapter 8 addresses the questions of alliances and cooperation between NASA and ESA and China and Russia, or, alternatively, the U.S. and China pursuing their space ambitions alone. The implications of each way forward in the context of a looming competition in space are considered. Chapter 9 discusses the repercussions of a Chinese space program overtaking NASA and whether the U.S. has the political will to advance its own space program to prevent its position as sole space superpower being usurped. Given the mutual suspicions existing in both countries, it is perhaps inevitable that Washington and Beijing are on a collision course in space. The final chapter describes the implications of such a confrontation and discusses what, if anything, can be done to avert a new space race.

David Harland proposes a series of books on the theme of NASAs Moon Program of the 1960s and early 1970s. Presented chronologically, NASAs Moon Program The Early Years will outline the Mercury and Gemini manned missions, the unmanned lunar probes and the Apollo missions leading up to Apollo 11, covering that mission only as a postscript. The First Men on the Moon The Story of Apollo 11 due for release in September 2006 is devoted solely to that mission. Apollo The Definitive Sourcebook published in 2006 covered all the missions, including the unmanned tests, in an encyclopaedic style which cited facts and figures in a stylised manner. Exploring the Moon The Apollo Expeditions was published in 1999, focusing on the final three Apollo missions, and covered only their activities on the lunar surface. A fully re-illustrated second edition with colour illustrations will be released in 2008. The individual mission books in this series will relate to the planning, flight and results, and be written in the same style as The First Men on the Moon The Story of Apollo 11; i.e. using dialogue from the in-flight transcripts (including some conversations never broadcast) to bring their stories to life. With the release of the book on Apollo 11 David Harland will then cover the other five missions that landed on the Moon, concluding by 2012 the 40th anniversary of the last Apollo mission. Each of the Apollo missions that reached the Moon deserves its own book-lenth account covering planning, the flight, and the scientific results. This series will become the definitive account of the Apollo era. It will give the Springer/Praxis list unrivalled coverage of the Apollo era of space explorationas the 40th anniversary approaches in 2009 and the world looks back with a sense of wonderment at the achievement. Plans are already in train for a return to the Moon by 2020 to create a Moonbase.

Martian Outpost provides a detailed insight into the various technologies, mission architectures, medical requirements, and training needed to send humans to Mars. It focuses on mission objectives and benefits, and the risks and complexities that are compounded when linked to an overall planet exploration program involving several expeditions and setting up a permanent presence on the surface.

The first section provides the background to sending a human mission to Mars. Analogies are made with early polar exploration and the expeditions of Shackleton, Amundsen, and Mawson. The interplanetary plans of the European Space Agency, NASA, and Russia are examined, including the possibility of one or more nations joining forces to send humans to Mars. Current mission architectures, such as NASA s Constellation, ESA s Aurora, and Ross Tierney s DIRECT, are described and evaluated.

The next section looks at how humans will get to the Red Planet, beginning with the preparation of the crew. The author examines the various analogues to understand the problems Mars-bound astronauts will face. Additional chapters describe the transportation hardware necessary to launch 4-6 astronauts on an interplanetary trajectory to Mars, including the cutting edge engineering and design of life support systems required to protect crews for more than a year from the lethal radiation encountered in deep space. NASA s current plan is to use standard chemical propulsion technology, but eventually Mars crews will take advantage of advanced propulsion concepts, such as the Variable Specific Impulse Magnetoplasma Rocket, ion drives and nuclear propulsion.

The interplanetary options for reaching Mars, as well as the major propulsive maneuvers required and the trajectories and energy requirements for manned and unmanned payloads, are reviewed . Another chapter addresses the daunting medical problems and available countermeasures for humans embarking on a mission to Mars: the insidious effects of radiation on the human body and the deleterious consequences of bone and muscle deconditioning. Crew selection will be considered, bearing in mind the strong possibility that they may not be able to return to Earth. Still another chapter describes the guidance, navigation, and control system architecture, as well as the lander design requirements and crew tasks and responsibilities required to touch down on the Red Planet.

Section 3 looks at the surface mission architectures. Seedhouse describes such problems as radiation, extreme temperatures, and construction challenges that will be encountered by colonists. He examines proposed concepts for transporting cargo and astronauts long distances across the Martian surface using magnetic levitation systems, permanent rail systems, and flying vehicles. In the penultimate chapter of the book, the author explains an adaptable and mobile exploration architecture that will enable long-term human exploration of Mars, perhaps making it the next space-based tourist location.

Astronauts, cosmonauts, and a very limited number of people have experienced eating space food due to the unique processing and packaging required for space travel. This book allows anyone with a normal kitchen to prepare space food. Since some of the processing such as freeze dehydration, and packaging cannot be accomplished in the normal kitchen, many of the recipes will not produce the food that would be launched in space, but will prepare food similar to what the astronauts would eat after they had added the water to the food in space. Many of the space foods are prepared to the point of ready to eat, and then frozen and freeze dried. Food preparation in this book stops at the point of ready to eat before the freezing and dehydrating takes place. Recipes in this book are extracted from the NASA food specifications and modified for preparation in a normal kitchen. The book will contain the following chapters: Introduction, Appetizers, Beverages, Bread and Tortillas, Cookies, Sandwiches, Desserts, Main Dishes, Soups and Salads, Vegetables, and Future Space Foods. Interesting tidbits of space food history will be spread throughout the book. Examples like; did NASA invent Tang?, who was the first person to eat in space?, the Gemini sandwich fiasco, why there is no alcohol in U.S. space food systems, astronauts favorite food, etc.

Lunar Outpost provides a detailed account of the various technologies, mission architectures, medical requirements and training needed to return humans to the Moon within the next decade. It focuses on the means by which a lunar outpost will be constructed and also addresses major topics such as the cost of the enterprise and the roles played by private companies and individual countries. The return of humans to the surface of the Moon will be critical to the exploration of the solar system. The various missions are not only in pursuit of scientific knowledge, but also looking to extend human civilization, economic expansion, and public engagement beyond Earth. As well as NASA, Chinaa (TM)s Project 921, Japana (TM)s Aerospace Exploration Agency, Russia, and the European Space Agency are all planning manned missions to the Moon and, eventually, to Mars. The Ares-I and Ares-V are the biggest rockets since the Saturn V and there is much state-of-the-art technology incorporated into the design of Orion, the spacecraft that will carry a crew of four astronauts to the Moon. Lunar Outpost also describes the human factors, communications, exploration activities, and life support constraints of the missions.

Paolo Ulivi and David Harland provide in "Robotic Exploration of the Solar System" a detailed history of unmanned missions of exploration of our Solar System As in their previous book Lunar Exploration, the subject will be treated wherever possible from an engineering and scientific standpoint. Technical descriptions of the spacecraft, of their mission designs and of instrumentations will be provided. Scientific results will be discussed in considerable depth, together with details of mission management.

The books will cover missions from the 1950s until the present day, and some of the latest missions and their results will appear in a popular science book for the first time. The authors will also cover many unflown projects, providing an indication of the ideas that proved to be unfulfilled at the time but which may still be proven and useful in the future.

Just like Lunar Exploration, these books will use sources only recently made available on the Soviet space program, in addition to some obscure and rarely used references on the European space program.

The project will deliver three volumes totaling over 1000 pages that will provide comprehensive coverage of the topic with thousands of references to the professional literature that should make it the 'first port of call' for people seeking information on the topic.

This book will cover in great detail the newest construction and uses of the International Space Station. The new volume will continue on from the end of Creating the International Space Station by David Harland and John Catchpole (published in January 2002 by Springer Praxis), providing flight by flight details and relevant political and "behind the scenes" activities as are necessary to explain why certain decisions, including flight re-scheduling and crew-reassignment, are made.

Part 1 will open with a chapter recounting the political history of the ISS, including how and why the program came into being. Chapter 2 will look at the four partners involved (USA, Russia, ESA, and Brazil), with a brief account of what each partner is bringing to the program. Chapter 3 will study the initial goals of the program, how they have changed and whether they have been met. Chapter 4 will summarize the program at the end of Creating the International Space Station.

Part 2 will look at the findings and recommendations of the International Space Station Management and Cost Evaluation Task Force. Part 3 will examine the original flight coverage, including the beginning of the construction of the Integrated Truss Structure, and will cover the stationa (TM)s occupation from the start of Expedition 4, through to the end of Expedition 6. Part 4 will start with the loss of STS-107 a" Columbia a" and explain its effect on both the International Space Station and the American space effort in general. It will cover the Expedition 7 occupation through to the beginning of Expedition 13, concentrating on the work of the two-person "Caretaker Crews."

Part 5 will study the recovery fromthe STS-107 tragedy and the re-commencement of the ISS construction, overcoming the grounding of the Space Shuttle fleet. It will cover the remainder of the Expedition 13 occupation, the return to three-person occupation, through to the end of Expedition 15 and the installation of Node-2, the final American module.

Part 6 will briefly look forward to the installation of the International Partnera (TM)s modules as well as the introduction of the European and Japanese robotic cargo vehicles. The book will end with a glance at plans for the Orion spacecraft and Ares-1 launch vehicle, and the delivery of Node-2, the final piece of American hardware.

Three Appendices will up-date those published in Creating the International Space Station: Appendix A will list ISS hardware descriptions, Appendix B will be a complete ISS Flight Log and Appendix C will be a full ISS Extravehicular Activity Log.

In Space Enterprise - Living and Working Offworld, Dr Philip Harris provides the vision and rationale as to why humanity is leaving its cradle, Earth, to use space resources, as well as pursuing lunar industrialization and establishing offworld settlements. As a management/space psychologist, Dr. Harris presents a behavioral science perspective on space exploration and enterprise. In this his 45th book, Phil has completely revised and updated the two previous editions of this classic, placing new emphasis on the need for more synergy and participation by the private sector. He not only provides a critical review of what is happening in the global space community, but offers specific strategies for lunar economic development. The author analyzes the human factors in contemporary and future space developments, especially relative to the deployment of people aloft. This user-friendly volume offers numerous photographs, diagrams, exhibits, and case studies.

Recent surveys have provided new and updated information into public insights of the nascent space tourism industry. Erik Seedhouse uniquely explores in detail the cutting-edge technologies, spacecraft capabilities, launch vehicles and the training that will define this commercial enterprise and also provides a manual for future suborbital and orbital private space explorers. This overview of the space tourism market is based upon choices the spaceflight participant must make, such as choice of agency, mode and spaceport. A detailed explanation is given of the medical requirements for spaceflight participants, with special reference to potential waiver criteria. Over half of the book is a comprehensive astronaut training/instructional manual that addresses each of the 15 subjects required for suborbital and orbital flight.

Following an Introduction examining the commercial potential for space tourism, Section 1 covers Suborbital Flight. Chapter 1 opens with a description and analysis of the significance of SpaceShipOne. Chapter 2 gives the Suborbital frontrunner profiles, mission architectures and technical aspects from launch to landing while the following chapter details the training and medical requirements for space tourists. Section 2 covers the same aspects for Orbital Flight, including a civilian astronaut training manual, enabling technologies, capabilities and personnel. A description is given of the anticipated on-orbit phases that will introduce the potential spaceflight participant or reader to the capsule, rendezvous, medical support, mission events and de-orbit phase. Section 3 gives a detailed assessment of the future of space tourism based on current technologies, commercial applications, military use and Lunar and Mars missions. Countries without space programs are also included.

Erik Seedhouse provides a much needed, well-rounded understanding of what promises to be the most dynamic, multi-faceted and exciting industry in the world. He shows how seemingly innocuous players are disproving long held beliefs about what can be achieved in space despite the inherent complexities, and why this industry may soon define the new norm in space travel.

Mounting pressure in the early 1960s from the National Academy of Sciences (NAS) to study ways of expanding the role of astronauts to conduct science on future space missions led to NASA's conclusion that flying scientifically trained crewmembers would generate greater returns from each mission.

An updated and expanded new edition of an authoritative book on flight dynamics and control system design for all types of current and future fixed-wing aircraft Since it was first published, Flight Dynamics has offered a new approach to the science and mathematics of aircraft flight, unifying principles of aeronautics with contemporary systems analysis. Now updated and expanded, this authoritative book by award-winning aeronautics engineer Robert Stengel presents traditional material in the context of modern computational tools and multivariable methods. Special attention is devoted to models and techniques for analysis, simulation, evaluation of flying qualities, and robust control system design. Using common notation and not assuming a strong background in aeronautics, Flight Dynamics will engage a wide variety of readers, including aircraft designers, flight test engineers, researchers, instructors, and students. It introduces principles, derivations, and equations of flight dynamics as well as methods of flight control design with frequent reference to MATLAB functions and examples. Topics include aerodynamics, propulsion, structures, flying qualities, flight control, and the atmospheric and gravitational environment. The second edition of Flight Dynamics features up-to-date examples; a new chapter on control law design for digital fly-by-wire systems; new material on propulsion, aerodynamics of control surfaces, and aeroelastic control; many more illustrations; and text boxes that introduce general mathematical concepts. Features a fluid, progressive presentation that aids informal and self-directed study Provides a clear, consistent notation that supports understanding, from elementary to complicated concepts Offers a comprehensive blend of aerodynamics, dynamics, and control Presents a unified introduction of control system design, from basics to complex methods Includes links to online MATLAB software written by the author that supports the material covered in the book

H. BALTSCHEFFSKYChairman Department of Biochemistry and Biophysics, Arrhenius Laboratories, Stockholm University, S-106 91 Stockholm, Sweden. Professor Stanley Miller, Professor K. R. Srinivasan, Organizers and Sponsors of this Conference, Ladies and Gentlemen; WearegettingreadyfortheAbdusSalamLecture, honoringtwomostdistinguishedsci- tists. Bothhaveverysigni?cantlycontributedtotherapidgrowthofthesphereoffun- mentalknowledgeinthesecondhalfofthetwentiethcentury. Abdus Salam, theoreticalphysicist, NobelPrizewinner, creatorandlongtimeleader of The Abdus Salam Center of Theoretical Physics. With his active interest in the origin oflifeheplayedaleadingroleininstigatingtheseconferencesonChemicalEvolutionand theOriginofLifehereinTrieste, whichstillareofsuchprimaryimportanceinthis?eld. Heleftthisworldin1996. And Stanley Miller, whomostgenerously, astheAbdusSalamLecturer, isgoingto giveushis"Recollectionsofthebeginningofchemicalevolutionexperiments" DearStanley, itisagreatprivilege, andindeedapleasuretointroduceyou. Thisisina wayaquiteeasytask, becauseweallalreadyknowthat"theMillerexperiment,"whichis mostappropriatelyplacedinthetitleofthisconference, in1953, exactly50yearsago, was amajorbreakthrough, openingupanewresearch?eldwith, andfor, rationalandadvanced chemicalexperimentationonthemolecularoriginoflife. Itwouldtaketoomuchtimetotrytodescribehereyourscienti?ccarrier, yourprices, yourPresidencyofISSOLandyourmanyothersuccesses. SoIratherwillendthisint- ductionwithacoupleofpersonalrecollections. First I would like to combine something of Abdus Salam and Stanley Miller. Abdus Salamgavethevery?rstinvitedlectureoftheUniversityofStockholmInternationalL- turesonHuman, GlobalandUniversalProblems, in1975. And10yearslater, atLidingo ] closetoStockholm, StanleyMillergavetheopeninglectureofaconferenceontheMol- ularEvolutionofLife. OnapictureItook, asaco-arrangeroftheseevents, Stanleyisseen approachinginhisusual, modestway, morefocussedonscienti?cdiscussionthanonthe camera. Last but not least, I shall tell you the true story about when we learned that Stanley isanenthusiasticenvironmentalist, inthebestsenseoftheword. About25yearsago, in Stockholm, Stanley, my wife and I strolled in the King's Garden. Its elmtrees were full 7 J. Seckbach et al. (eds. ), Life in the Universe,7-8. C 2004 Kluwer Academic Publishers. Printed in the Netherlands. 8 of young people who, some even spending nights in the trees, prevented the authorities from removing the elmtrees, by ax and saw. Also Stanley signed a petition to save the elmtrees-andtheyweresaved Stanley, I believe that your greatness as a scientist and as a friend must be linked to the many facets of your wonderful personality. We much look forward to your lecture. THE BEGINNING OF CHEMICAL EVOLUTION EXPERIMENTS Recollections and Perspectives 1 2 3 S. L. MILLER, J. L. BADA, and A."

In Europe's Space Programme - to Ariane and Beyond, author Brian Harvey begins with the fledgling European rocket effort of the 1930s and the key pioneers of the period, examining the significance of the V-2 and the technological advances represented by its development. He shows how the Russians and Americans put their captured V-2s to work, but the European countries were slower to respond. Both Britain and France developed national space programmes in the 1950s and 1960s and the early attempts at European co-operation for launcher development - ELDO and ESRO - are described. The formation of the European Space Agency and the origins of the successful Ariane launcher programme are discussed and Europe's subsequent success in the world launcher market, its cutting-edge role in space applications and European manned spaceflight, are all described in detail.

In Walking in Space: Development of Space Walking Techniques, David Shayler provides a comprehensive overview and analysis of EVA techniques, available for the first time in a readable form - other than NASA publications. The author draws on original documentation, personal interviews of astronauts with experience of EVAs, and accounts by those involved in suit design, EVA planning and operations. Moving on from the pioneering of EVA techniques during the Gemini programme, the author describes the basic requirements in terms of the equipment that every spacewalker needs, the development of training techniques - currently all completed on Earth - the surface explorations of the Moon by the Apollo astronauts and the numerous activities performed by Shuttle astronauts and those aboard the Salyut and Mir Space Stations, such as satellite servicing, equipment upgrading and repair missions. He also describes the development of techniques for ensuring crew safety during EVAs and looks ahead to future EVAs from the International Space Station and the development of new technology, including robotic assistance.