Near-Threshold Computing embodies an intriguing choice for mobile processors due to the promise of superior energy efficiency, extending the battery life of these devices while reducing the peak power draw. However, process, voltage, and temperature variations cause a significantly high failure rate of Level One cache cells in the near-threshold regime a stark contrast to designs in the super-threshold regime, where fault sites are rare.
This thesis work shows that faulty cells in the near-threshold regime are highly clustered in certain regions of the cache. In addition, popular mobile benchmarks are studied to investigate the impact of run-time workloads on timing faults manifestation. A technique to mitigate the run-time faults is proposed. This scheme maps frequently used data to healthy cache regions by exploiting the application cache behaviors. The results show up to 78% gain in performance over two other state-of-the-art techniques

Mugisha, Dieudonne Manzi

English

Historically, the increase of transistor devices per area of chip has been one of the key drivers of microprocessor performance. While the transistor count per chip keeps increasing, today’s microprocessor power budget limits the number of devices that can be turned on. This issue stems from the fact that new device technologies dissipate more power in form of heat—a problem that can cause circuit breakdown due to excessive temperatures.
Near-Threshold Computing (NTC), where the operating voltage is reduced near the threshold voltage that turns on a transistor, is a popular research topic. NTC significantly reduces the power consumption and allows a higher number of devices to be used given a certain power budget. Although it is energy efficient, NTC suffers from a high rate of circuit failures induced by both manufacturing imperfections and the operating environment. Static Random Access Memory (SRAM) arrays are the most affected components of a microprocessor, and consequently require robust design techniques. This thesis proposes a technique that exploits the software use of SRAM arrays in order to reduce circuit failure in NTC

DigitalCommons@USU

Exploiting Application Behaviors for Resilient Static Random Access Memory Arrays in the Near-Threshold Computing Regime

https://digitalcommons.usu.edu/cgi/viewcontent.cgi?article=5579&amp;context=etd

Exploiting Application Behaviors for Resilient Static Random Access Memory Arrays in the Near-Threshold Computing Regime

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