Litcius/Paper detail

Mitigation and Predictive Assessment of SET Immunity of Digital Logic Circuits for Space Missions

Ygor Quadros de Aguiar, F. Wrobel, Jean‐Luc Autran, Paul Leroux, Frédéric Saigné, V. Pouget, Antoine Touboul

2020Aerospace19 citationsDOIOpen Access PDF

Abstract

Due to the intrinsic masking effects of combinational circuits in digital designs, Single-Event Transient (SET) effects were considered irrelevant compared to the data rupture caused by Single-Event Upset (SEU) effects. However, the importance of considering SET in Very-Large-System-Integration (VLSI) circuits increases given the reduction of the transistor dimensions and the logic data path depth in advanced technology nodes. Accordingly, the threat of SET in electronics systems for space applications must be carefully addressed along with the SEU characterization. In this work, a systematic prediction methodology to assess and improve the SET immunity of digital circuits is presented. Further, the applicability to full-custom and cell-based design methodologies are discussed, and an analysis based on signal probability and pin assignment is proposed to achieve a more application-efficient SET-aware optimization of synthesized circuits. For instance, a SET-aware pin assignment can provide a reduction of 37% and 16% on the SET rate of a NOR gate for a Geostationary Orbit (GEO) and the International Space Station (ISS) orbit, respectively.

Topics & Concepts

Computer scienceSingle event upsetSet (abstract data type)Digital electronicsReduction (mathematics)Very-large-scale integrationCombinational logicElectronic engineeringElectronic circuitComputer engineeringGeostationary orbitEvent (particle physics)Logic gateReal-time computingEmbedded systemEngineeringAlgorithmElectrical engineeringComputer hardwareSatelliteMathematicsAerospace engineeringPhysicsGeometryQuantum mechanicsProgramming languageStatic random-access memoryRadiation Effects in ElectronicsLow-power high-performance VLSI designCCD and CMOS Imaging Sensors