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Introductory graduate textbook in spacecraft design and how space environment affects operations in space, for space scientists and engineers.
This full-color textbook will help students and professionals understand the space environment and its impacts on spacecraft design, engineering, and performance. While the primary emphasis of the book is the Earth's environment and its effects on spacecraft, it also addresses the extraterrestrial environment and the effects of radiation on humans in space. The book begins with an introduction to the history of spacecraft failures, risk management reliability and quality assurance techniques, and parts reliability. It goes on to provide an overview of the structure of the Sun: the structure, origin, and models of the geomagnetic field; gravitational field of the Earth; Earth's magnetosphere and radiation environment; neutral environment including fundamentals of the kinetic theory of gasses; variation of pressure with altitude and hypoxia of humans; electromagnetic propagation; the effect of atomic oxygen of materials; plasma surrounding the Earth; transport and effects of photon
More than four decades have passed since a human first set foot on the Moon. Great strides have been made in our understanding of what is required to support an enduring human presence in space, as evidenced by progressively more advanced orbiting human outposts, culminating in the current International Space Station (ISS). However, of the more than 500 humans who have so far ventured into space, most have gone only as far as near-Earth orbit, and none have traveled beyond the orbit of the Moon. Achieving humans' further progress into the solar system had proved far more difficult than imagined in the heady days of the Apollo missions, but the potential rewards remain substantial. During its more than 50-year history, NASA's success in human space exploration has depended on the agency's ability to effectively address a wide range of biomedical, engineering, physical science, and related obstacles-an achievement made possible by NASA's strong and productive commitments to life and physical sciences research for human space exploration, and by its use of human space exploration infrastructures for scientific discovery. The Committee for the Decadal Survey of Biological and Physical Sciences acknowledges the many achievements of NASA, which are all the more remarkable given budgetary challenges and changing directions within the agency. In the past decade, however, a consequence of those challenges has been a life and physical sciences research program that was dramatically reduced in both scale and scope, with the result that the agency is poorly positioned to take full advantage of the scientific opportunities offered by the now fully equipped and staffed ISS laboratory, or to effectively pursue the scientific research needed to support the development of advanced human exploration capabilities. Although its review has left it deeply concerned about the current state of NASA's life and physical sciences research, the Committee for the Decadal Survey on Biological and Physical Sciences in Space is nevertheless convinced that a focused science and engineering program can achieve successes that will bring the space community, the U.S. public, and policymakers to an understanding that we are ready for the next significant phase of human space exploration. The goal of this report is to lay out steps and develop a forward-looking portfolio of research that will provide the basis for recapturing the excitement and value of human spaceflight-thereby enabling the U.S. space program to deliver on new exploration initiatives that serve the nation, excite the public, and place the United States again at the forefront of space exploration for the global good.
Spacecraft depend on electronic components that must perform reliably over missions measured in years and decades. Space radiation is a primary source of degradation, reliability issues, and potentially failure for these electronic components. Although simulation and modeling are valuable for understanding the radiation risk to microelectronics, there is no substitute for testing, and an increased use of commercial-off-the- shelf parts in spacecraft may actually increase requirements for testing, as opposed to simulation and modeling. Testing at the Speed of Light evaluates the nation's current capabilities and future needs for testing the effects of space radiation on microelectronics to ensure mission success and makes recommendations on how to provide effective stewardship of the necessary radiation test infrastructure for the foreseeable future.
Propelling Understanding: Your Launchpad to Aerospace Engineering Excellence The realm of aerospace engineering is a confluence of science, ambition, and human endeavor, encapsulating the relentless pursuit of pushing boundaries and transcending terrestrial limitations. It is a domain that continually stretches the fabric of what is possible, melding imagination with the rigors of engineering precision. The Dictionary of Aerospace Engineering, with its extensive compilation of 6,000 meticulously curated titles, serves as a cornerstone for those engaged in this dynamic field, offering a wellspring of knowledge and a pathway to mastery. Embarking on the pages of this dictionary is akin to launching into a voyage through the core principles, advanced methodologies, and the ever-evolving technologies that are the hallmarks of aerospace engineering. Each entry is a beacon, illuminating complex terminologies and nuanced concepts, aiding both the seasoned engineer and the aspiring practitioner in navigating the vast expanse of aerospace engineering knowledge. The Dictionary of Aerospace Engineering is not merely a repository of terms but an edifice of understanding. It is a conduit through which the intricate and the arcane become accessible, where challenging concepts are decoded into comprehensible insights. This dictionary is an endeavor to foster a shared lexicon, to enhance communication, collaboration, and innovation across the aerospace engineering community. This comprehensive reference material transcends being a passive dictionary; it is a dynamic engagement with the multifaceted domain of aerospace engineering. Each term, each title is a testament to the relentless spirit of inquiry and the unyielding drive for innovation that characterizes the aerospace engineering sector. The Dictionary of Aerospace Engineering is an invitation to delve deeper, to engage with the lexicon of flight and space, and to emerge with a richer understanding and a sharpened expertise. It’s a portal through which the uninitiated become adept, the curious become enlightened, and the proficient become masters. Every term, every phrase is a step closer to unraveling the mysteries and embracing the challenges that propel the aerospace engineering domain forward. As you traverse through the entries of The Dictionary of Aerospace Engineering, you are embarking on a journey of discovery. A journey that will not only augment your understanding but will also ignite the spark of curiosity and the drive for innovation that are the hallmarks of excellence in aerospace engineering. We beckon you to commence this educational expedition, to explore the breadth and depth of aerospace engineering lexicon, and to emerge with a boundless understanding and an unyielding resolve to contribute to the ever-evolving narrative of aerospace engineering. Through The Dictionary of Aerospace Engineering, may your quest for knowledge soar to new heights and may your contributions to the aerospace engineering domain echo through the annals of human achievement.