Reducing embedded software radiation-induced failures through cache memories

2014 19th IEEE European Test Symposium (ETS) Pub Date : 2014-05-26 DOI:10.1109/ETS.2014.6847793

Thiago Santini, P. Rech, G. Nazar, L. Carro, F. Wagner

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引用次数: 27

Abstract

Cache memories are traditionally disabled in space-level and safety-critical applications, since it was believed that the sensitive area they introduce would compromise the system reliability. As technology has evolved, the speed gap between logic and main memory has increased in such a way that disabling caches slows the code much more than in the past. As a result, the processor is exposed for a much longer time in order to compute the same workload. In this paper we demonstrate that, on modern embedded processors, enabling caches may bring benefits to critical systems: the larger exposed area may be compensated by the shorter exposure time, leading to an overall improved reliability. We describe the Mean Workload Between Failures, an intuitive metric to evaluate the impact of enabling caches for a given generic application error rate. The proposed metric is experimentally validated through an extensive radiation test campaign using a 28 nm off-the-shelf ARM-based SoC as a case study. The failure probability of the bare-metal application is decreased when the L1 cache is enabled but increased when L2 is also enabled. We also discuss when L2 caches could make the device more reliable.

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通过缓存存储器减少嵌入式软件辐射引起的故障

高速缓存存储器在空间级和安全关键型应用程序中通常是禁用的，因为人们认为它们引入的敏感区域会损害系统的可靠性。随着技术的发展，逻辑和主存之间的速度差距越来越大，禁用缓存使代码的速度比过去慢得多。因此，为了计算相同的工作负载，处理器将暴露更长的时间。在本文中，我们证明，在现代嵌入式处理器上，启用缓存可能会给关键系统带来好处:更大的暴露区域可能会被更短的暴露时间所补偿，从而导致整体可靠性的提高。我们描述了平均故障间工作负载，这是一个直观的指标，用于评估启用缓存对给定通用应用程序错误率的影响。通过广泛的辐射测试活动，以28nm现成的基于arm的SoC为例，对所提出的度量进行了实验验证。启用L1缓存时，裸机应用程序的故障概率会降低，但同时启用L2缓存时，故障概率会增加。我们还讨论了L2缓存何时可以使设备更可靠。

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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2014 19th IEEE European Test Symposium (ETS)

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