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Embedded neural networks are increasingly deployed in critical applications, such as avionics and autonomous vehicle control.However, their reliability is challenged by various sources of soft errors, including radiation-induced faults from cosmic ray strikes, leading to Single Event Upsets (SEUs).To ensure the reliability of such systems, we present a novel hardwarebased fault protection strategy tailored for embedded neural networks.The idea is based on mitigating faults by adapting at run-time any erroneous values (parameters, intermediate data) due to SEU towards zero upon fault detection.As neural networks exhibit heterogeneous sensitivity to fault direction, our hardware-based approach triplicates the sign bit (TMR) and uses a Voter block based on logical AND/OR gates to handle fault directionality.Through a comprehensive and exhaustive fault injection study, conducted on a Convolutional Neural Network (CNN) model, implemented on FPGA using fixed-point quantization, we show that our method is applicable to various hardware architectures while optimizing hardware cost, a crucial aspect in the context of embedded systems.Obtained results show that VANDOR protection efficiency is near 90.97% for the LeNet-5 CNN inference model, suitable for an embedded system.Additionally, it significantly reduces area overhead compared to existing approaches.
Guillemé et al. (Wed,) studied this question.