1 research outputs found
R2F: A Remote Retraining Framework for AIoT Processors with Computing Errors
AIoT processors fabricated with newer technology nodes suffer rising soft
errors due to the shrinking transistor sizes and lower power supply. Soft
errors on the AIoT processors particularly the deep learning accelerators
(DLAs) with massive computing may cause substantial computing errors. These
computing errors are difficult to be captured by the conventional training on
general purposed processors like CPUs and GPUs in a server. Applying the
offline trained neural network models to the edge accelerators with errors
directly may lead to considerable prediction accuracy loss.
To address the problem, we propose a remote retraining framework (R2F) for
remote AIoT processors with computing errors. It takes the remote AIoT
processor with soft errors in the training loop such that the on-site computing
errors can be learned with the application data on the server and the retrained
models can be resilient to the soft errors. Meanwhile, we propose an optimized
partial TMR strategy to enhance the retraining. According to our experiments,
R2F enables elastic design trade-offs between the model accuracy and the
performance penalty. The top-5 model accuracy can be improved by 1.93%-13.73%
with 0%-200% performance penalty at high fault error rate. In addition, we
notice that the retraining requires massive data transmission and even
dominates the training time, and propose a sparse increment compression
approach for the data transmission optimization, which reduces the retraining
time by 38%-88% on average with negligible accuracy loss over a straightforward
remote retraining