Evaluating Read Disturb Effect on RRAM based AI Accelerator with Multilevel States and Input Voltages

2022 IEEE International Symposium on Defect and Fault Tolerance in VLSI and Nanotechnology Systems (DFT) Pub Date : 2022-10-19 DOI:10.1109/DFT56152.2022.9962345

J. Wen, Andrea Baroni, E. Pérez, Markus Ulbricht, C. Wenger, M. Krstic

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引用次数: 2

Abstract

RRAM technology is a promising candidate for implementing efficient AI accelerators with extensive multiply-accumulate operations. By scaling RRAM devices to the synaptic crossbar array, the computations can be realized in situ, avoiding frequent weights transfer between the processing units and memory. Besides, as the computations are conducted in the analog domain with high flexibility, applying multilevel input voltages to the RRAM devices with multilevel conductance states enhances the computational efficiency further. However, several non-idealities existing in emerging RRAM technology may degrade the reliability of the system. In this paper, we measured and investigated the impact of read disturb on RRAM devices with different input voltages, which incurs conductance drifts and introduces errors. The measured data are deployed to simulate the RRAM based AI inference engines with multilevel conductance states and input voltages. Device-to-device variability is also taken into consideration to assess the accuracy drop. Two convolutional neural networks, LeNet-5 and VGG-7, are benchmarked with MNIST and CIFAR-10 datasets, respectively. Our results show that mapping weights with differential pairs yields better robustness to read disturb and variability effects.

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基于多电平状态和输入电压的RRAM AI加速器的读干扰效应评估

RRAM技术是实现具有广泛乘法累加运算的高效人工智能加速器的有前途的候选技术。通过将RRAM器件缩放到突触横杆阵列，可以就地实现计算，避免了处理单元和存储器之间频繁的权重传递。此外，由于计算是在模拟域中进行的，具有很高的灵活性，因此对具有多电平电导状态的RRAM器件施加多电平输入电压进一步提高了计算效率。然而，新兴RRAM技术中存在的一些非理想性可能会降低系统的可靠性。在本文中，我们测量和研究了不同输入电压下读干扰对RRAM器件的影响，它会引起电导漂移和引入误差。将测量数据用于模拟具有多电平电导状态和输入电压的基于RRAM的AI推理引擎。在评估精度下降时，还考虑了设备间的可变性。两个卷积神经网络LeNet-5和VGG-7分别使用MNIST和CIFAR-10数据集进行基准测试。我们的研究结果表明，用差分对映射权重对读取干扰和可变性效应具有更好的鲁棒性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE International Symposium on Defect and Fault Tolerance in VLSI and Nanotechnology Systems (DFT)

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