JPL Deep-Space Communications and Navigation

Based on years of research conducted at the NASA Jet Propulsion Laboratory, Low-Energy Lunar Trajectory Design provides high-level information to mission managers and detailed information to mission designers about low-energy transfers between Earth and the moon. The book answers high-level questions about the availability and performance of such transfers in any given month and year. Low-energy lunar transfers are compared with various other types of transfers, and placed within the context of historical missions. Using this book, designers may reconstruct any transfer described therein, as well as design similar transfers with particular design parameters. An Appendix, "Locating the Lagrange Points," and a useful list of terms and constants completes this technical reference. • Surveys thousands of possible trajectories that may be used to transfer spacecraft between Earth and the moon, including transfers to lunar libration orbits, low lunar orbits, and the lunar surface • Provides information about the methods, models, and tools used to design low-energy lunar transfers • Includes discussion about the variations of these transfers from one month to the next, and the important operational aspects of implementing a low-energy lunar transfer • Additional discussions address navigation, station-keeping, and spacecraft systems issues

DEEP SPACE COMMUNICATIONS A COLLECTION OF SOME OF THE JET PROPULSION LABORATORY'S SPACE MISSIONS SELECTED TO REPRESENT THE PLANETARY COMMUNICATIONS DESIGNS FOR A PROGRESSION OF VARIOUS TYPES OF MISSIONS The text uses a case study approach to show the communications link performance resulting from the planetary communications design developed by the Jet Propulsion Laboratory (JPL). This is accomplished through the description of the design and performance of six representative planetary missions. These six cases illustrate progression through time of the communications system's capabilities and performance from 1970s technology to the most recent missions. The six missions discussed in this book span the Voyager for fly-bys in the 1970s, Galileo for orbiters in the 1980s, Deep Space 1 for the 1990s, Mars Reconnaissance Orbiter (MRO) for planetary orbiters, Mars Exploration Rover (MER) for planetary rovers in the 2000s, and the MSL rover in the 2010s. Deep Space Communications: • Provides an overview of the Deep Space Network and its capabilities • Examines case studies to illustrate the progression of system design and performance from mission to mission and provides a broad overview of the mission systems described • Discusses actual flight mission telecommunications performance of each system Deep Space Communications serves as a reference for scientists and engineers interested in communications systems for deep-space telecommunications link analysis and design control.

UNIQUE RESOURCE EXPLORING HOW SPACECRAFT IMAGERY PROVIDES PROFESSIONALS WITH ACCURATE ESTIMATES OF SPACECRAFT TRAJECTORY, WITH REAL-WORLD EXAMPLES AND DETAILED ILLUSTRATIONS Spacecraft Optical Navigation provides detailed information on the planning and analysis of spacecraft imagery to help determine the trajectory of a spacecraft. The author, an experienced engineer within the field, addresses the entirety of celestial targets and explains how a spacecraft captures their imagery. Aimed at professionals within spacecraft navigation, this book provides an extensive introduction and explains the history of optical navigation, reviewing a range of optical methods and presents real world examples throughout. With the use of mathematics, this book discusses everything from the orbits, sizes, and shapes of the bodies being imaged, to the location and properties of salient features on their surfaces. Specific sample topics covered in Spacecraft Optical Navigation include: • History of various past spacecraft, including Mariner and Viking, Voyager, Galileo, NEAR Shoemaker, and Cassini, and flight hardware, star catalogs, and stereophotoclinometry • Cameras, covering the gnomonic projection (and deviations from it), creation of a digital picture, picture flattening, and readout smears • Modeling optical navigation observables, covering apparent directions to an object, star, and limbs or terminators, and orientation of cameras • Obtaining optical navigation observables, covering centerfinding for stars and resolved and unresolved bodies, and using opnav data in orbit determination Spacecraft Optical Navigation is an ideal resource for engineers working in spacecraft navigation and optical navigation, to update their knowledge of the technology and use it in their day-to-day. The text will also benefit researchers working with spacecraft, particularly in navigation, and professors and lecturers teaching graduate aerospace courses.

Explore the development and state-of-the-art in deep space exploration using radio science techniques In Radio Science Techniques for Deep Space Exploration, accomplished NASA/JPL researcher and manager Sami Asmar delivers a multi-disciplinary exploration of the science, technology, engineering, mission operations, and signal processing relevant to deep space radio science. The book discusses basic principles before moving on to more advanced topics that include a wide variety of graphical illustrations and useful references to publications by experts in their respective fields. Complete explanations of changes in the characteristics of electromagnetic waves and the instrumentation and technology used in scientific experiments are examined. Radio Science Techniques for Deep Space Exploration offers answers to the question of how to explore the solar system with radio links and better understand the interior structures, atmospheres, rings, and surfaces of other planets. The author also includes: • Thorough introductions to radio science techniques and systems needed to investigate planetary atmospheres, rings, and surfaces • Comprehensive explorations of planetary gravity and interior structures, as well as relativistic and solar studies • Practical discussions of instrumentation, technologies, and future directions in radio science techniques Perfect for students and professors of physics, astronomy, planetary science, aerospace engineering, and communications engineering, Radio Science Techniques for Deep Space Exploration will also earn a place in the libraries of engineers and scientists in the aerospace industry.