Presentation
EPIC: Error PredIction and Correction for Power-Efficient Voltage Underscaling Multiply-Accumulate Unit
DescriptionMatrix multiplication dominates the power consumption in compute-intensive applications such as deep neural networks (DNNs), spurring intensive investigations into power-efficient multiply-accumulate (MAC) units. Among the mainstream low-power design methodologies, voltage underscaling can achieve effective power savings yet induce timing errors that may lead to catastrophic accuracy loss. In this paper, we propose an error prediction and correction framework (denoted as EPIC) for arbitrary MAC unit under voltage underscaling, which predicts the timing errors and samples the correct output by using a delay-tunable clock. A prediction bits searching algorithm is proposed to enhance the prediction accuracy with low hardware cost, resulting in up to 100% accuracy. While preserving the accuracy, EPIC achieves up to 52% power savings over the corresponding MAC operating at nominal voltage. With transistor-level optimizations, EPIC incurs only 8% area and 1% power overheads, achieving 100% error correction under a voltage underscaling ratio of 0.74. Compared to state-of-the-art error resilient circuit designs, EPIC consumes 60%-88% less area. Additionally, to achieve the accuracy performance of EPIC in error-resilient applications, we propose a simulation workflow involving precise timing features, enabling an accurate simulation of voltage underscaling MAC in large-scale applications. The experimental results show that, under voltage-underscaling, the MAC with EPIC consumes 11% less power than the one without EPIC, when a same accuracy as exact implementation is required in multi-layer perceptron (MLP).
Event Type
Research Manuscript
TimeTuesday, June 243:30pm - 3:45pm PDT
Location3003, Level 3
DES4: Digital and Analog Circuits
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