苛刻工业条件下基于mram的BER弹性量化边缘人工智能网络

2021 IEEE 3rd International Conference on Artificial Intelligence Circuits and Systems (AICAS) Pub Date : 2021-06-06 DOI:10.1109/AICAS51828.2021.9458528

V. Parmar, M. Suri, K. Yamane, T. Lee, Nyuk Leong Chung, V. B. Naik

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引用次数: 2

摘要

我们研究了基于22nm FD-SOI嵌入式mram (eMRAM)的边缘ai推理(EAI)架构，使用量化神经网络(QNN)在具有强磁场和宽工作温度(-40 ~ 125°C)的恶劣工业条件下进行推理应用。量化卷积神经网络(QCNN)和量化多层感知器(QMLP)的最佳案例测试准确率分别达到98.99%和89.94%，超过了MNIST数据集上文献报道的结果。通过利用QNN的误码弹性，我们发现基于eMRAM的EAI在125°C下提供了≈700 Oe(≈98%的精度)的优越磁抗扰度，而不使用ECC, QCNN和QMLP分别节省了≈14%和≈11%的能量。详细分析了保留时间、写入能量和推理精度之间的权衡。

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MRAM-based BER resilient Quantized edge-AI Networks for Harsh Industrial Conditions

We investigate Edge-AI Inference (EAI) architectures based on 22nm FD-SOI embedded-MRAM (eMRAM) using quantized neural networks (QNN) for inference applications in harsh industrial conditions having strong magnetic field and wide operating temperature (-40∼125 °C). We achieved best case test accuracy of 98.99% with Quantized-Convolutional Neural Network (QCNN) and 89.94% with Quantized-Multi-layer Perceptron (QMLP) surpassing prior reported results in literature on MNIST dataset. By exploiting BER resilience of QNN, we show that eMRAM based EAI offers a superior magnetic immunity of ≈ 700 Oe at 125 °C (≈ 98% accuracy) without the use of ECC and significant energy saving of ≈ 14% for QCNN and ≈ 11% for QMLP. A detailed analysis on the tradeoff between retention time, write energy and inference accuracy is presented.

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2021 IEEE 3rd International Conference on Artificial Intelligence Circuits and Systems (AICAS)

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