Synctium: a Near-Threshold Stream Processor for Energy-Constrained Parallel Applications

Krimer, Evgeni; Pawłowski, Robert; Erez, Mattan; Chiang, Patrick

doi:10.1109/l-ca.2010.5

Cited by 39 publications

(31 citation statements)

References 19 publications

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“…Errors introduced by process variation appear in the form of differences in delay for driven signals and input offset and delay for receiver circuits. However, because these errors are generally static in nature they can potentially be mitigated by embedded measurement and calibration circuits [23], localized adaptive body biasing and voltage scaling [38], or device and block sparing [39].…”

Section: Process Variationmentioning

confidence: 99%

A Survey Addressing On-Chip Interconnect: Energy and Reliability Considerations

Postman

Chiang

2012

ISRN Electronics

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Scaling CMOS process technology continues to enable increased levels of system integration, leading to on-chip communication demands beyond what traditional digital signaling techniques can efficiently provide with sufficient reliability. In this paper we survey the state of the art of on-chip interconnect techniques for improving performance, energy, and reliability and provide a review of interconnect reliability considerations. Finally, we provide a case study to evaluate the efficiency of error correcting codes on a state-of-the-art energy-efficient low-swing interconnect.

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Section: Process Variationmentioning

confidence: 99%

A Survey Addressing On-Chip Interconnect: Energy and Reliability Considerations

Postman

Chiang

2012

ISRN Electronics

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“…Research has shown that minimum energy is typically achieved when V dd enters the near/sub-threshold region, where about a 10× reduction in energy per computation is achievable [7]. In these cases, the impact of static variations become much more extreme and can be very difficult to predict in large CMOS dies [8].…”

Section: Static Variationsmentioning

confidence: 99%

“…These slower speeds lead designers to push sub-threshold processors to a more parallel approach. For example, in [8] the authors use multiple execution lanes to regain the throughput lost by the increased delays of sub-threshold operation. The following subsections will discuss the viability of the techniques under review to operate in the sub-threshold region.…”

Section: Error Detection and Recovery In The Sub/near-threshold Regimementioning

confidence: 99%

Error Detection and Recovery Techniques for Variation-Aware CMOS Computing: A Comprehensive Review

Crop

Krimer

Moezzi-Madani

et al. 2011

JLPEA

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While Moore's law scaling continues to double transistor density every technology generation, new design challenges are introduced. One of these challenges is variation, resulting in deviations in the behavior of transistors, most importantly in switching delays. These exaggerated delays widen the gap between the average and the worst case behavior of a circuit. Conventionally, circuits are designed to accommodate the worst case delay and are therefore becoming very limited in their performance advantages. Thus, allowing for an average case oriented design is a promising solution, maintaining the pace of performance improvement over future generations. However, to maintain correctness, such an approach will require on the fly mechanisms to prevent, detect, and resolve violations. This paper explores such mechanisms, allowing the improvement of circuit performance under intensifying variations. We present speculative error detection techniques along with recovery mechanisms. We continue by discussing their ability to operate under extreme variations including sub-threshold operation. While the main focus of this survey is on circuit J. Low Power Electron. Appl. 2011, 1 335 approaches, for its completeness, we discuss higher-level, architectural and algorithmic techniques as well.

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“…We explore the tradeoffs associated with timing speculation in the context of SIMD designs, and build on our earlier work [13], to develop and evaluate SIMD-and GPU-specific extensions to the timing speculation technique. In our initial work, we observed that naively applying timing speculation to a SIMD pipeline may perform poorly.…”

Section: Introductionmentioning

confidence: 99%

Lane decoupling for improving the timing-error resiliency of wide-SIMD architectures

Krimer¹,

Chiang²,

Erez³

2012

2012 39th Annual International Symposium on Computer Architecture (ISCA)

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A significant portion of the energy dissipated in modern integrated circuits is consumed by the overhead associated with timing guardbands that ensure reliable execution. Timing speculation, where the pipeline operates at an unsafe voltage with any rare errors detected and resolved by the architecture, has been demonstrated to significantly improve the energy-efficiency of scalar processor designs. Unfortunately, applying the same timing-speculative approach to wide-SIMD architectures, such as those used in highlyefficient GPUs, may not provide similar gains.In this work, we make two important contributions. The first is a set of models describing a parametrized general error probability function that is based on measurements of a fabricated chip and the expected efficiency benefits of timing speculation in a SIMD context. The second contribution is a decoupled SIMD pipeline that more effectively utilizes timing speculation and recovery, when compared with a standard SIMD design that uses only conventional timing speculation. The proposed lane decoupling enables each SIMD lane to tolerate timing errors independent of other adjacent lanes, resulting in higher throughput and improved scalability. We validate our models and evaluate our design using a cycle-based GPU simulator, describe the conditions where efficiency improvements can be obtained, and explore the benefits of decoupling across a wide range of parameters. Our results show that timing speculation can achieve up to 10.3% improvement in efficiency.

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Synctium: a Near-Threshold Stream Processor for Energy-Constrained Parallel Applications

Cited by 39 publications

References 19 publications

A Survey Addressing On-Chip Interconnect: Energy and Reliability Considerations

A Survey Addressing On-Chip Interconnect: Energy and Reliability Considerations

Error Detection and Recovery Techniques for Variation-Aware CMOS Computing: A Comprehensive Review

Lane decoupling for improving the timing-error resiliency of wide-SIMD architectures

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