Analyzing Radiation-Induced Transient Errors on SRAM-Based FPGAs by Propagation of Broadening Effect

Sio, Corrado De; Azimi, Sarah; Sterpone, Luca; Du, Boyang

doi:10.1109/access.2019.2915136

Cited by 12 publications

(3 citation statements)

References 17 publications

(22 reference statements)

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“…architecture design techniques (also known as radiation hardening by design) are key features in many embedded application domains that must employ COTS for commercial sustainability. In this context, the effective implementation of fault-tolerant soft-processor solutions in static RAM (SRAM) based FPGAs is a significant research target [7], [8].…”

Section: Introductionmentioning

confidence: 99%

Design and Evaluation of Buffered Triple Modular Redundancy in Interleaved-Multi-Threading Processors

et al. 2022

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Fault management in digital chips is a crucial aspect of functional safety. Significant work has been done on gate and microarchitecture level triple modular redundancy, and on functional redundancy in multi-core and simultaneous-multi-threading processors, whereas little has been done to quantify the fault tolerance potential of interleaved-multi-threading. In this study, we apply the temporal-spatial triple modular redundancy concept to interleaved-multi-threading processors through a design solution that we call Buffered triple modular redundancy, using the soft-core Klessydra-T03 as the basis for our experiments. We then illustrate the quantitative findings of a large fault-injection simulation campaign on the fault-tolerant core and discuss the vulnerability comparison with previous representative fault-tolerant designs. The results show that the obtained resilience is comparable to a full triple modular redundancy at the cost of execution cycle count overhead instead of hardware overhead, yet with higher achievable clock frequency.INDEX TERMS Circuit faults, digital integrated circuits, fault detection, fault tolerant computing, field programmable gate arrays, microprocessors, multithreading, radiation hardening (electronics), redundancy, robustness.Open Access funding provided by 'Università degli Studi di Roma ''La Sapienza''' within the CRUI CARE Agreement

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Section: Introductionmentioning

confidence: 99%

Design and Evaluation of Buffered Triple Modular Redundancy in Interleaved-Multi-Threading Processors

et al. 2022

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“…Typically, the longer the PW, the greater the probability that SET will get latched at the clock edge. The studies, [30] [31] [29], indicate that Propagation Induced Pulse Broadening (PIPB) may result in significant SET broadening, and the resulting SETs may be longer than 1000ps. Thus, conservatively, we have selected PW 1000ps for further extensive analysis of both FMQP and BMQP.…”

Section: ) Fault Injection At Rtl Levelmentioning

confidence: 99%

FPGA Implementation of a Fault-Tolerant Fused and Branched CNN Accelerator With Reconfigurable Capabilities

Syed,

Zhao,

Chen

et al. 2024

IEEE Access

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The ImageNet moment was a turning point for Convolutional Neural Networks (CNNs), as it demonstrated their potential to revolutionize computer vision tasks. This triumph of CNNs has motivated solving even more complex problems involving multiple tasks from multiple data modalities. Conventionally, a single CNN accelerator has been optimized to perform just one task or multiple correlated tasks. This study presents a shared-layers approach that leverages the pattern-learning capabilities of CNNs to perform multiple uncorrelated tasks from different modalities using a single hardware accelerator. We overcame the challenge of data imbalance in multi-modal learning by synthetic data generation. We achieved an average classification accuracy above 90% on a single CNN accelerator, which would otherwise require three accelerators. Due to the reliability concerns imposed by transistor shrinking and aging, we extended the shared layers methodology and introduced a fault-tolerant CNN accelerator with reconfigurable capabilities supporting fault-tolerant (FT), high-performance (HP), and de-stress (DS) modes. FT mode provides high reliability against soft errors utilizing double/triple modular redundancy, HP mode offers peak performance of 0.979 TOPs using parallel execution, and DS mode reduces dynamic power consumption by up to 68.6% in clock-gated design and even more using a partial reconfiguration method, contributing to decelerating the aging process of the circuit. We have comprehensively evaluated two different CNN architectures (i.e., fused and branched), for three distinct tasks, in three different operating modes, based on accuracy, quantization, pruning, hardware resource utilization, power, energy, performance, and reliability.

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“…In the last few decades, the growing complexity of electronic systems employed in the automotive, aerospace, military, and generally in safety-critical applications has increased the importance of fault-tolerant design and fault simulation. Moreover, the probability of faults in digital electronic devices has increased with technology scaling, voltage margin reduction, and statistical process variations magnification [1][2][3]. As a consequence, faulttolerance (FT) techniques for functional safety support in microprocessor cores have become a requisite in many system designs.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Dynamic Triple Modular Redundancy in an Interleaved-Multi-Threading RISC-V Core

Barbirotta

Cheikh

Mastrandrea

et al. 2022

JLPEA

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Functional safety is a key requirement in several application domains in which microprocessors are an essential part. A number of redundancy techniques have been developed with the common purpose of protecting circuits against single event upset (SEU) faults. In microprocessors, functional redundancy may be achieved through multi-core or simultaneous-multi-threading architectures, with techniques that are broadly classifiable as Double Modular Redundancy (DMR) and Triple Modular Redundancy (TMR), involving the duplication or triplication of architecture units, respectively. RISC-V plays an interesting role in this context for its inherent extendability and the availability of open-source microarchitecture designs. In this work, we present a novel way to exploit the advantages of both DMR and TMR techniques in an Interleaved-Multi-Threading (IMT) microprocessor architecture, leveraging its replicated threads for redundancy, and obtaining a system that can dynamically switch from DMR to TMR in the case of faults. We demonstrated the approach for a specific family of RISC-V cores, modifying the microarchitecture and proving its effectiveness with an extensive RTL fault-injection simulation campaign.

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Analyzing Radiation-Induced Transient Errors on SRAM-Based FPGAs by Propagation of Broadening Effect

Cited by 12 publications

References 17 publications

Design and Evaluation of Buffered Triple Modular Redundancy in Interleaved-Multi-Threading Processors

Design and Evaluation of Buffered Triple Modular Redundancy in Interleaved-Multi-Threading Processors

FPGA Implementation of a Fault-Tolerant Fused and Branched CNN Accelerator With Reconfigurable Capabilities

Evaluation of Dynamic Triple Modular Redundancy in an Interleaved-Multi-Threading RISC-V Core

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