Analyzing and Mitigating the Impact of Permanent Faults on a Systolic Array Based Neural Network Accelerator
February 11, 2018 ยท Declared Dead ยท ๐ IEEE VLSI Test Symposium
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Authors
Jeff Zhang, Tianyu Gu, Kanad Basu, Siddharth Garg
arXiv ID
1802.04657
Category
cs.LG: Machine Learning
Cross-listed
cs.AR,
cs.CV,
cs.NE
Citations
146
Venue
IEEE VLSI Test Symposium
Last Checked
4 months ago
Abstract
Due to their growing popularity and computational cost, deep neural networks (DNNs) are being targeted for hardware acceleration. A popular architecture for DNN acceleration, adopted by the Google Tensor Processing Unit (TPU), utilizes a systolic array based matrix multiplication unit at its core. This paper deals with the design of fault-tolerant, systolic array based DNN accelerators for high defect rate technologies. To this end, we empirically show that the classification accuracy of a baseline TPU drops significantly even at extremely low fault rates (as low as $0.006\%$). We then propose two novel strategies, fault-aware pruning (FAP) and fault-aware pruning+retraining (FAP+T), that enable the TPU to operate at fault rates of up to $50\%$, with negligible drop in classification accuracy (as low as $0.1\%$) and no run-time performance overhead. The FAP+T does introduce a one-time retraining penalty per TPU chip before it is deployed, but we propose optimizations that reduce this one-time penalty to under 12 minutes. The penalty is then amortized over the entire lifetime of the TPU's operation.
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