Evaluation of the Suitability of NEON SIMD Microprocessor Extensions Under Proton Irradiation

Lindoso, Almudena; García-Valderas, M.; Entrena, Luis; Morilla, Yolanda; Martín-Holgado, Pedro

doi:10.1109/tns.2018.2823540

Cited by 16 publications

(15 citation statements)

References 21 publications

(18 reference statements)

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“…The most recent applications of the CNA 60 Co irradiator have been mainly focussed in to analyze dose effects in different electronic systems: unclonable functions implemented in FPGAs [37] and SIMD microprocessors [38,39].…”

Section: Co-60 Irradiatormentioning

confidence: 99%

Research facilities and highlights at the Centro Nacional de Aceleradores (CNA)

et al. 2021

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The Centro Nacional de Aceleradores is a user-oriented accelerator facility in Seville, Spain. Its main facilities are a 3 MV tandem accelerator, an 18 MeV proton Cyclotron, a tandetron used for AMS, a compact accelerator used for radiocarbon measurements, a $$^{60}$$ 60 Co irradiator and a PET/CT scanner. The technical specifications and research applications of these facilities are described. A neutron beam line associated to a charged pulsed beam in the tandem allows for time of flight measurements which determine the neutron energy. The use of an adequate stripper gas in the AMS tandetron permits to measure heavy radionuclides with very low detection levels, allowing to perform environmental studies using these radionuclides as tracers. The use of the microbeam in the tandem accelerator allows to apply the ion beam-induced current technique to investigate the spectroscopic properties and radiation hardness of different semiconductor detectors.

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Section: Co-60 Irradiatormentioning

confidence: 99%

Research facilities and highlights at the Centro Nacional de Aceleradores (CNA)

et al. 2021

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“…In this particular case, the DUT was placed at 53.5 cm from the exit nozzle, so that the final energy at the surface was 15.2 MeV, with an estimated spread in the order of 300 KeV. The device package was not removed, as the energy range of incident protons in the silicon active area (8 to 10 MeV) was sufficient to produce events, which has previously been validated by the CNA group in similar campaigns conducted with these types of boards [7]. The final energy of the incident beam on the surface and in the active area was obtained with energy-loss data calculated with the SRIM2013 code [39].…”

Section: B Facilities -Lansce and Cnamentioning

confidence: 99%

“…In addition, the resulting custom hardware is targeted at a specific device and therefore a very expensive solution. In contrast, Software-Implemented Hardware Fault Tolerance (SIHFT) [7], [8] is a software programming approach to deal with faults affecting the hardware. These approaches are less expensive and have shorter development timelines than the hardware approaches.…”

Section: Introductionmentioning

confidence: 99%

Empirical Mathematical Model of Microprocessor Sensitivity and Early Prediction to Proton and Neutron Radiation-Induced Soft Errors

Serrano-Cases

Reyneri

Morilla

et al. 2020

IEEE Trans. Nucl. Sci.

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A mathematical model is described to predict microprocessor fault tolerance under radiation. The model is empirically trained by combining data from simulated faultinjection campaigns, and radiation experiments, both with protons (at the CNA facilities, Seville, Spain) and with neutrons (at the LANSCE Weapons Neutron Research facility at Los Alamos, USA). The sensitivity to soft errors of different blocks of commercial processors is identified to estimate the reliability of a set of programs that had previously been optimized, hardened, or both. The results showed a standard error under 0.1, in the case of the ARM processor, and 0.12, in the case of the MSP430 microcontroller.

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“…In this case, the DUT was placed at 53.5 cm from the exit nozzle with a mylar foil window of 125µm, so that the final energy at the surface was 15.2 MeV, with an estimated spread of ∼300 KeV. Previous tests at the CNA have shown that the energy range of incident protons in the silicon active area, 10 to 8 MeV, is sufficient to produce events without thinning them [24]. The final energy of the incident beam at the surface and in the active area was obtained by using the energy loss data calculated with the SRIM2013 code [25].…”

Section: B Mooga Parametersmentioning

confidence: 99%

Nonintrusive Automatic Compiler-Guided Reliability Improvement of Embedded Applications Under Proton Irradiation

Serrano-Cases

Morilla

Martín-Holgado

et al. 2019

IEEE Trans. Nucl. Sci.

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A method is presented for automated improvement of embedded application reliability. The compilation process is guided using Genetic Algorithms and a Multi-Objective Optimization Approach (MOOGA). Even though modern compilers are not designed to generate reliable builds, they can be tuned to obtain compilations that improve their reliability, through simultaneous optimization of their fault coverage, execution time, and memory size. Experiments show that relevant reliability improvements can be obtained from efficient exploration of the compilation solutions space. Fault-injection simulation campaigns are performed to assess our proposal against different benchmarks and the results are assessed against a real ARM-based System on Chip under proton irradiation.

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Evaluation of the Suitability of NEON SIMD Microprocessor Extensions Under Proton Irradiation

Cited by 16 publications

References 21 publications

Research facilities and highlights at the Centro Nacional de Aceleradores (CNA)

Research facilities and highlights at the Centro Nacional de Aceleradores (CNA)

Empirical Mathematical Model of Microprocessor Sensitivity and Early Prediction to Proton and Neutron Radiation-Induced Soft Errors

Nonintrusive Automatic Compiler-Guided Reliability Improvement of Embedded Applications Under Proton Irradiation

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