Publications Details

Low Power, Radiation Resilient Synchronous Edge Processing for Remote Monitoring

Xiao, T.P.; Wahby, William; Bennett, Christopher H.; Hughart, David R.; Oh, Sangheon; Fuller, Elliot J.; Talin, Albert A.; Li, Yiyang; Agarwal, Sapan; Hays, Park E.; Siath, Maximilian; Wilson, Donald; Dempsey, Ryan C.; Marinella, Matthew

Next-generation space remote sensing systems may be equipped with imaging arrays that sense data at a rate that outstrips the processing capability of any computing hardware that can operate within a satellite’s power budget. This project developed novel convolutional and recurrent neural networks to detect and estimate point-like events amid clutter, and investigated their efficient and accurate implementation on analog in-memory computing systems that are 10-1000× more energy-efficient than digital processors. This project leveraged two memory devices at different levels of technological maturity: a large-scale analog computing prototype using commercial SONOS charge-trap memory, and electrochemical memory (ECRAM) with intrinsic radiation hardness. We experimentally demonstrated end-to-end analog processing of our neural networks on SONOS and characterized the radiation response of both SONOS and ECRAM. We advanced the state-of-the-art in ECRAM precision and reliability, and developed co-design methods to enable accurate long-term operation of SONOS analog accelerators in space radiation environments.