A Low-Latency DMR Architecture with Fast Checkpoint Recovery Scheme

This paper presents a novel architecture for a fault-tolerant and dual modular redundancy (DMR) system using a checkpoint recovery approach. The architecture features exploitation of SRAM with simultaneous copy and instantaneous compare function. It can perform low-latency data copying between dual...

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Veröffentlicht in:	IEICE transactions on electronics 2015-05, Vol.E98.C (4), p.333-339
Hauptverfasser:	Matsukawa, Go, Nakata, Yohei, Sugure, Yasuo, Oho, Shigeru, Kimi, Yuta, Shimozawa, Masafumi, Yoshida, Shuhei, Kawaguchi, Hiroshi, Yoshimoto, Masahiko
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Sprache:	jpn
Schlagworte:	Architecture Copying Fault tolerance Power consumption Recovery Redundancy Reproduction Tasks
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container_title	IEICE transactions on electronics
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creator	Matsukawa, Go Nakata, Yohei Sugure, Yasuo Oho, Shigeru Kimi, Yuta Shimozawa, Masafumi Yoshida, Shuhei Kawaguchi, Hiroshi Yoshimoto, Masahiko
description	This paper presents a novel architecture for a fault-tolerant and dual modular redundancy (DMR) system using a checkpoint recovery approach. The architecture features exploitation of SRAM with simultaneous copy and instantaneous compare function. It can perform low-latency data copying between dual cores. Therefore, it can carry out fast backup and rollback. Furthermore, it can reduce the power consumption during data comparison process compared to the cyclic redundancy check (CRC). Evaluation results show that, compared with the conventional checkpoint/restart DMR, the proposed architecture reduces the cycle overhead by 97.8% and achieves a 3.28% low-latency execution cycle even if a one-time fault occurs when executing the task. The proposed architecture provides high reliability for systems with a real-time requirement.
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subjects	Architecture Copying Fault tolerance Power consumption Recovery Redundancy Reproduction Tasks
title	A Low-Latency DMR Architecture with Fast Checkpoint Recovery Scheme
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