Identificador persistente para citar o vincular este elemento: http://hdl.handle.net/10553/112928
Título: Error Mitigation Using Approximate Logic Circuits: A Comparison of Probabilistic and Evolutionary Approaches
Autores/as: Sánchez Clemente, Antonio José 
Entrena, Luis
Hrbacek, Radek
Sekanina, Lukas
Clasificación UNESCO: 330790 Microelectrónica
330703 Diseño de circuitos
Palabras clave: Approximate logic circuit
Error mitigation
Evolutionary computing
Single-event transient (SET)
Single-event upset (SEU)
Fecha de publicación: 2016
Publicación seriada: IEEE Transactions on Reliability 
Resumen: Technology scaling poses an increasing challenge to the reliability of digital circuits. Hardware redundancy solutions, such as triple modular redundancy (TMR), produce very high area overhead, so partial redundancy is often used to reduce the overheads. Approximate logic circuits provide a general framework for optimized mitigation of errors arising from a broad class of failure mechanisms, including transient, intermittent, and permanent failures. However, generating an optimal redundant logic circuit that is able to mask the faults with the highest probability while minimizing the area overheads is a challenging problem. In this study, we propose and compare two new approaches to generate approximate logic circuits to be used in a TMR schema. The probabilistic approach approximates a circuit in a greedy manner based on a probabilistic estimation of the error. The evolutionary approach can provide radically different solutions that are hard to reach by other methods. By combining these two approaches, the solution space can be explored in depth. Experimental results demonstrate that the evolutionary approach can produce better solutions, but the probabilistic approach is close. On the other hand, these approaches provide much better scalability than other existing partial redundancy techniques.
URI: http://hdl.handle.net/10553/112928
ISSN: 0018-9529
DOI: 10.1109/TR.2016.2604918
Fuente: IEEE Transactions on Reliability [ISSN 0018-9529], v. 65(4), p. 1871-1883, (Diciembre 2016)
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