Onboard Processing With Hybrid and Reconfigurable Computing on Small Satellites

Due to the increasing demands of onboard sensor and autonomous processing, one of the principal needs and challenges for future spacecraft is onboard computing. Space computers must provide high performance and reliability (which are often at odds), using limited resources (power, size, weight, and cost), in an extremely harsh environment (due to radiation, temperature, vacuum, and vibration). As spacecraft shrink in size, while assuming a growing role for science and defense missions, the challenges for space computing become particularly acute. For example, processing capabilities on CubeSats (smaller class of SmallSats) have been extremely limited to date, often featuring microcontrollers with performance and reliability barely sufficient to operate the vehicle let alone support various sensor and autonomous applications. This article surveys the challenges and opportunities of onboard computers for small satellites (SmallSats) and focuses upon new concepts, methods, and technologies that are revolutionizing their capabilities, in terms of two guiding themes: hybrid computing and reconfigurable computing. These innovations are of particular need and value to CubeSats and other Smallsats. With new technologies, such as CHREC Space Processor (CSP), we demonstrate how system designers can exploit hybrid and reconfigurable computing on SmallSats to harness these advantages for a variety of purposes, and we highlight several recent missions by NASA and industry that feature these principles and technologies.