Kilcoyne, Deirdre Kathleen2016-06-162016-06-162016-06-15vt_gsexam:7604http://hdl.handle.net/10919/71362In Earth-to-Space communications, well-known propagation effects such as path loss and atmospheric loss can lead to fluctuations in the strength of the communications link between a satellite and its ground station. Additionally, a less-often considered effect of shadowing due to the geometry of the satellite and its solar panels can also lead to link degradation. As a result of these anticipated channel impairments, NASA's communication links have been traditionally designed to handle the worst-case impact of these effects through high link margins and static, lower rate, modulation formats. This thesis first characterizes the propagation environment experienced by a software-defined radio on the NASA SCaN Testbed through a full link-budget analysis. Then, the following chapters propose, design, and model a link adaptation algorithm to provide an improved trade-off between data rate and link margin through varying the modulation format as the received signal-to-noise ratio fluctuates.ETDIn Copyrightlink adaptationadaptive modulationshadowingerror vector magnitudeLink Adaptation for Mitigating Earth-to-Space Propagation Effects on the NASA SCaN TestbedThesis