Fault-Tolerant Quasi Delay Insensitive Combinational Circuits in Commercial FPGA Devices

2021 IEEE 22nd Latin American Test Symposium (LATS) Pub Date : 2021-10-27 DOI:10.1109/LATS53581.2021.9651805

Orlando Verducci, D. L. Oliveira, R. Moreno

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Abstract

Fault tolerance design is an increasing concern due to VLSI technology scaling, which implements more complex systems in a single chip. Each transistor in such systems is more susceptible to the effects of high-energy particle strikes, mainly in reduced power supply applications. Glitches in any node of the circuit caused by a soft error may propagate or even captured by a memory cell components. In FPGA, this issue is particularly concerning because, in such target devices, any digital circuitry is modeled using programmed LUTs (Look Up Tables) where a flipped bit cannot be recovered unless new programming on it. The proposed architecture for combinational circuits in FPGA devices enhances robustness to a QDI (Quasi-Delay Insensitive) digital design inserting a novel output register based on gates that validate each dual-rail variable the system according to the current processing cycle. The reduced penalties in area, power, and latency for the proposed fault-tolerant architecture are interesting compared to Triple Modular Redundancy (TMR), and Dual Modular Redundancy (DMR) approaches.

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商用FPGA器件中的容错准延迟不敏感组合电路

随着超大规模集成电路技术的发展，在单芯片上实现更复杂的系统，容错设计日益受到关注。这种系统中的每个晶体管更容易受到高能粒子撞击的影响，主要是在低功率供电应用中。由软错误引起的电路中任何节点的故障都可能传播甚至被存储单元组件捕获。在FPGA中，这个问题特别令人担忧，因为在这样的目标器件中，任何数字电路都是使用编程的lut(查找表)建模的，其中翻转的位不能恢复，除非对其进行新的编程。提出的FPGA器件组合电路结构增强了对QDI(准延迟不敏感)数字设计的鲁棒性，插入了基于门的新型输出寄存器，根据当前处理周期验证系统的每个双轨变量。与三模冗余(Triple Modular Redundancy, TMR)和双模冗余(Dual Modular Redundancy, DMR)方法相比，所提出的容错架构在面积、功耗和延迟方面的损失更小。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 IEEE 22nd Latin American Test Symposium (LATS)

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