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"The smallsat and mega-constellation industry is poised to place more smallsats (those with a mass less than 600 kg) in space in the next decade than all the satellites launched since the beginning of the space race. As advances in technology have made the use of space more feasible and economical, the number of smallsats in outer space has increased at an exponential rate. Technology miniaturization has also affected satellite technology and has allowed for the space industry to use smallsats with capabilities that only a few years ago would have required much larger satellites. These smallsats make possible the recent launch and proposal for mega-constellations (networks of over 100 satellites operating together) in Low Earth Orbit (LEO). The United States National Security Space Strategy recognizes that space operations are of vital importance to US national security For the United States Department of Defense, and militaries across the globe, these proposed mega-constellations provide both the potential for un-matched advantages over current architecture, but also numerous potential risks to national security. This thesis examines publicly available, unclassified documents, news articles, journals, publications, governmental reports, international treaties, laws and regulations, and other information to assess the current state of the smallsat and mega-constellation industry, as well as the trends going into the future. Using this information, compared with U.S. space policy and legal documents and the known threats to space systems, this thesis then considers how an increase in smallsats and mega-constellations benefits and threatens the United States National Security and whether current regulations are sufficient to address these changes. Some of the legal aspects discussed relate to space activities that include space situational awareness; cyber-security, intelligence, reconnaissance, and surveillance, on-orbit spying, radio interference, space debris, anti-satellite weapons, and space mines, to name a few"--
In coming years, constellations composed of large numbers of small, less complex, and less costly satellites are likely to become progressively more cost-effective relative to constellations made up of small numbers of large, more complex, and more expensive satellites. Taken together, recent and projected trends in commercial constellation design, miniaturization, launch costs, and anti-satellite capabilities fall short of supporting a dramatic near-term reorientation of U.S. space capabilities. However, those trends do suggest that now is an appropriate time for the U.S. military and intelligence community to at least modestly increase their investment in small satellite capabilities—both as a hedge and to create options.
During much of the Cold War, America's first line of defense was in outer space: a network of secret satellites that could provide instant warning of an enemy missile launch. The presence of these infrared sensors orbiting 22,000 miles above the earth discouraged a Soviet first strike and stabilized international relations between the superpowers, and they now play a crucial role in monitoring the missile programs of China, India, and other emerging nuclear powers. Jeffrey Richelson has written the first comprehensive history of this vital program, tracing its evolution from the late 1950s to the present. He puts Defense Support Program operations in the context of world events - from Russian missile programs to the Gulf War - and explains how DSP's infrared sensors are used to detect meteorites, monitor forest fires, and even gather industrial intelligence by "seeing" the lights of steel mills.
They are on the cutting edge of technology--the top-secret, billion-dollar instruments of super-power espionage. They are spy satellites--the means by which the super-pwers keep tabs on each other in the deep black of space. Excellent . . . Highly recommended --Booklist.
In the past decade, the field of small satellites has expanded the space industry in a powerful way. Hundreds, indeed thousands, of these innovative and highly cost-efficient satellites are now being launched from Earth to establish low-cost space systems. These smallsats are engaged in experiments and prototype testing, communications services, data relay, internet access, remote sensing, defense and security related services, and more. Some of these systems are quite small and are simple student experiments, while others in commercial constellations are employing state-of-the-art technologies to deliver fast and accurate services. This handbook provides a comprehensive overview of this exciting new field. It covers the technology, applications and services, design and manufacture, launch arrangements, ground systems, and economic and regulatory arrangements surrounding small satellites. The diversity of approach in recent years has allowed for rapid innovation and economic breakthroughs to proceed at a pace that seems only to be speeding up. In this reference work, readers will find information pertaining to all aspects of the small satellite industry, written by a host of international experts in the field.
This book calls for the urgent regulation of satellite mega-constellations in outer space, proposing a new model of “international regulatory coordination”, in order to ensure the sustainable balance of science and advanced telecommunications. We are currently witnessing expansion of the Internet off our planet. The proliferation of new space-based internet connectivity has been accompanied by much discussion about the potential impact on astronomy. Scientists are increasingly concerned that mega-constellations proposed by SpaceX, OneWeb, Amazon and Facebook, might wreak havoc on scientific research and transform our view of the stars. These commercial operators plan to launch hundreds of thousands of satellites into Low-Earth Orbit (LEO) in the coming decade, representing a 1000% increase on objects currently in orbit. This book examines this new space race in the context of historical rivalries, for it is clear that mega-constellations are being actively pursued by a US administration determined to dominate LEO as tensions with China rise. This creates a risk of interference with earth-based scientific activities that use optical and radio frequency techniques to study the universe. This book examines these developments in the context of the Outer Space Treaty (OST), which provides all States with the freedom of scientific investigation, exploration and use of outer space, while balancing this with obligations to avoid interference with the space activities of other States. It draws upon interviews with some of Europe’s leading astronomers in order to highlight the extent to which the issue will require legal and regulatory reform of mega-constellation licensing processes, to ensure the integrity of astronomical science is preserved. The race to dominate LEO also comes at a time when the monopolistic power of Facebook, Amazon and other TechGiants, is under renewed scrutiny in western democracies. The author argues that a new governance framework for launch and operational licenses is urgently required, in which impact risk assessments, scale and proportionality, and stakeholder consultation processes should play important roles. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.. It is now vital that the astronomical community – whose skill-set does not generally involve leading regulatory strategies – engage with those who can support its leadership in exerting a renewed influence. The diplomacy of science, which played a vital role during the Cold War and the establishment of global commons, must be reinvigorated for the New Space era.
If you take an interest in military and national security affairs, you have probably read the works of Clausewitz, Sun Tzu, and Thucydides. But what about the books of the underappreciated military strategist Theodor Geisel, also known as Dr. Seuss? Until Dr. Seuss & National Security, the military aspect of Ted Geisel’s biography and his books have been overlooked by scholars and critics alike. Yet Dr. Seuss books possess direct relevance to national security in part because Ted Geisel’s service in the the US Army during WWII made a lasting impact on his worldview. Numerous traces of Ted Geisel’s intense and dangerous wartime experiences can be found in his children’s books. Tucked in between bright and vivid drawings of imaginary animals and whimsical settings, the reader may sometimes encounter foreboding dark forests, ariel bombardment, ruthless authority figures, and other evocations of military life. Each of the chapters in this edited volume employs a Dr. Seuss book to illuminate a national security topic. For example, Oh, the Places You’ll Go helps us understand grand strategy in outer space, I Had Trouble Getting to Solla Sollew puts new light on Clausewitz’s concept of the fog of war, and Hunches in Bunches can be seen as a primer on military intelligence. By using beloved childhood stories to illuminate national security topics, this book offers an entertaining way to approach complex topics that can be understood by specialists and non‐experts alike.
In the past decade, the field of small satellites has expanded the space industry in a powerful way. Hundreds, indeed thousands, of these innovative and highly cost-efficient satellites are now being launched from Earth to establish low-cost space systems. These smallsats are engaged in experiments and prototype testing, communications services, data relay, internet access, remote sensing, defense and security related services, and more. Some of these systems are quite small and are simple student experiments, while others in commercial constellations are employing state-of-the-art technologies to deliver fast and accurate services. This handbook provides a comprehensive overview of this exciting new field. It covers the technology, applications and services, design and manufacture, launch arrangements, ground systems, and economic and regulatory arrangements surrounding small satellites. The diversity of approach in recent years has allowed for rapid innovation and economic breakthroughs to proceed at a pace that seems only to be speeding up. In this reference work, readers will find information pertaining to all aspects of the small satellite industry, written by a host of international experts in the field.
Space-based observations have transformed our understanding of Earth, its environment, the solar system and the universe at large. During past decades, driven by increasingly advanced science questions, space observatories have become more sophisticated and more complex, with costs often growing to billions of dollars. Although these kinds of ever-more-sophisticated missions will continue into the future, small satellites, ranging in mass between 500 kg to 0.1 kg, are gaining momentum as an additional means to address targeted science questions in a rapid, and possibly more affordable, manner. Within the category of small satellites, CubeSats have emerged as a space-platform defined in terms of (10 cm x 10 cm x 10 cm)- sized cubic units of approximately 1.3 kg each called "U's." Historically, CubeSats were developed as training projects to expose students to the challenges of real-world engineering practices and system design. Yet, their use has rapidly spread within academia, industry, and government agencies both nationally and internationally. In particular, CubeSats have caught the attention of parts of the U.S. space science community, which sees this platform, despite its inherent constraints, as a way to affordably access space and perform unique measurements of scientific value. The first science results from such CubeSats have only recently become available; however, questions remain regarding the scientific potential and technological promise of CubeSats in the future. Achieving Science with CubeSats reviews the current state of the scientific potential and technological promise of CubeSats. This report focuses on the platform's promise to obtain high- priority science data, as defined in recent decadal surveys in astronomy and astrophysics, Earth science and applications from space, planetary science, and solar and space physics (heliophysics); the science priorities identified in the 2014 NASA Science Plan; and the potential for CubeSats to advance biology and microgravity research. It provides a list of sample science goals for CubeSats, many of which address targeted science, often in coordination with other spacecraft, or use "sacrificial," or high-risk, orbits that lead to the demise of the satellite after critical data have been collected. Other goals relate to the use of CubeSats as constellations or swarms deploying tens to hundreds of CubeSats that function as one distributed array of measurements.