Mostrar registro simples

dc.contributor.advisorKastensmidt, Fernanda Gusmão de Limapt_BR
dc.contributor.advisorAsensi, Sergio Antonio Cuencapt_BR
dc.contributor.authorGomes, Iuri Albandes Cunhapt_BR
dc.date.accessioned2019-04-24T02:34:13Zpt_BR
dc.date.issued2018pt_BR
dc.identifier.urihttp://hdl.handle.net/10183/193344pt_BR
dc.description.abstractTriple Modular Redundancy (TMR) is a well-known mitigation technique, which provides a full masking capability to single faults, although at a great cost in terms of area and power consumption. For that reason, partial redundancy is often applied instead to alleviate these overheads. In this context, Approximate TMR, which is the implementation of TMR with approximate versions of the target circuit, has emerged in recent years as an alternative to partial replication, with the advantage of optimizing the trade-off between error coverage and area overhead. Several techniques for approximate circuit generation already exist in the literature, each one with its pros and con. This work do further study of the ATMR technique that evaluating the cost-benefit between area increase and coverage of approach failures. The first contribution is a new idea for the approximate-TMR approach where all of the redundant modules are approximate version of the original design, therefore allowing the creating o ATMR circuits with very low area overhead, we named this technique as Full-ATMR or just FATMR. The work also presents a novel approach for implementing approximate ATMR, in a automatic way, that combines an approximate gate library (ApxLib) with a Multi-Objective Optimization Genetic Algorithm (MOOGA). The algorithm performs a blind search, over the huge solution space, optimizing error coverage and area overhead altogether. Experiments compare our approach with a state of the art technique showing an improvement of trade-offs for different benchmark circuits. The last contribution is another novel approach to design ATMR circuits, it combines the idea of approximate library and heuristic. The approach uses testability and observability techniques in order to take decision on how to best approximate a circuit.en
dc.format.mimetypeapplication/pdfpt_BR
dc.language.isoengpt_BR
dc.rightsOpen Accessen
dc.subjectMicroeletrônicapt_BR
dc.subjectApproximate Circuitsen
dc.subjectApproximate-TMRen
dc.subjectTolerancia : Falhaspt_BR
dc.subjectAlgoritmos genéticospt_BR
dc.subjectFault Toleranceen
dc.subjectSingle Event Effectsen
dc.titleUse of approximate triple modular redundancy for fault tolerance in digital circuitspt_BR
dc.title.alternativeUso de redundancia modular tripla aproximada para tolerancia a falhas em circuitos digitais pt
dc.typeTesept_BR
dc.identifier.nrb001092238pt_BR
dc.degree.grantorUniversidade Federal do Rio Grande do Sulpt_BR
dc.degree.departmentInstituto de Informáticapt_BR
dc.degree.programPrograma de Pós-Graduação em Microeletrônicapt_BR
dc.degree.localPorto Alegre, BR-RSpt_BR
dc.degree.date2018pt_BR
dc.degree.leveldoutoradopt_BR


Thumbnail
   

Este item está licenciado na Creative Commons License

Mostrar registro simples