Next-Generation Ground Network Architecture for Communications and Tracking of Interplanetary Smallsats

Kar-Ming Cheung; Douglas Abraham; Belinda Arroyo; Eleanor Basilio; Alessandra Babuscia; Courtney Duncan; Dennis Lee; Kamal Oudrhiri; Timothy Pham; Robert Staehle; Stefan Waldherr; Gregory Welz; Jay Wyatt; Marco Lanucara; Benjamin Malphrus; John Bellardo; Jordi Puig-Suari; Sabrina Corpino

Citation

Abstract

As small spacecraft venture out of Earth orbit, they will encounter challenges not experienced or addressed by the numerous low Earth orbit (LEO) CubeSat and smallsat missions staged to date. The LEO CubeSats typically use low-cost, proven CubeSat radios, antennas, and university ground stations with small apertures. As more ambitious yet costconstrained space mission concepts to the Moon and beyond are being developed, CubeSats and smallsats have the potential to provide a more affordable platform for exploring deep space and performing the associated science. Some of the challenges that have, so far, slowed the proliferation of small interplanetary spacecraft are those of communications and navigation. Unlike Earth-orbiting spacecraft that navigate via government services such as North American Aerospace Defense Command’s (NORAD’s) tracking elements or the Global Positioning Satellite (GPS) system, interplanetary spacecraft would have to operate in a fundamentally different manner that allows the deep-space communications link to provide both command/telemetry and the radiometric data needed for navigation. Another challenge occurs when smallsat and CubeSat missions would involve multiple spacecraft that require nearsimultaneous communication and/or navigation, but have a very limited number of ground antenna assets, as well as available spectrum, to support their links. To address these challenges, the Jet Propulsion Laboratory (JPL) and the Deep Space Network (DSN) it operates for NASA are pursuing the following efforts: (1) Developing a CubeSat-compatible, DSN-compatible transponder — Iris — which a commercial vendor can then make available as a product line. (2) Developing CubeSat-compatible high-gain antennas — deployable reflectors, reflectarrays, and inflatable antennas. (3) Streamlining access and utilization processes for DSN and related services such as the Advanced Multi-Mission Operations System (AMMOS). (4) Developing methodologies for tracking and operating multiple spacecraft simultaneously, including spectrum coordination. (5) Coordination and collaboration with non-DSN facilities. This article further describes the communications and tracking challenges facing interplanetary smallsats and CubeSats, and the next-generation ground network architecture being evolved to mitigate those challenges.

Details

Volume: 42-202
Published: August 15, 2015
Pages: 1–47
File Size: 1.8 MB