Leveraging Ferroelectric Stochasticity and In-Memory Computing for DNN IP Obfuscation

IF 2 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IEEE Journal on Exploratory Solid-State Computational Devices and Circuits Pub Date : 2022-10-25 DOI:10.1109/JXCDC.2022.3217043

Likhitha Mankali;Nikhil Rangarajan;Swetaki Chatterjee;Shubham Kumar;Yogesh Singh Chauhan;Ozgur Sinanoglu;Hussam Amrouch

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引用次数: 1

Abstract

With the emergence of the Internet of Things (IoT), deep neural networks (DNNs) are widely used in different domains, such as computer vision, healthcare, social media, and defense. The hardware-level architecture of a DNN can be built using an in-memory computing-based design, which is loaded with the weights of a well-trained DNN model. However, such hardware-based DNN systems are vulnerable to model stealing attacks where an attacker reverse-engineers (REs) and extracts the weights of the DNN model. In this work, we propose an energy-efficient defense technique that combines a ferroelectric field effect transistor (FeFET)-based reconfigurable physically unclonable function (PUF) with an in-memory FeFET XNOR to thwart model stealing attacks. We leverage the inherent stochasticity in the FE domains to build a PUF that helps to corrupt the neural network’s (NN) weights when an adversarial attack is detected. We showcase the efficacy of the proposed defense scheme by performing experiments on graph-NNs (GNNs), a particular type of DNN. The proposed defense scheme is a first of its kind that evaluates the security of GNNs. We investigate the effect of corrupting the weights on different layers of the GNN on the accuracy degradation of the graph classification application for two specific error models of corrupting the FeFET-based PUFs and five different bioinformatics datasets. We demonstrate that our approach successfully degrades the inference accuracy of the graph classification by corrupting any layer of the GNN after a small rewrite pulse.

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利用铁电性和内存计算实现DNN IP混淆

随着物联网（IoT）的出现，深度神经网络（DNN）被广泛应用于不同领域，如计算机视觉、医疗保健、社交媒体和国防。DNN的硬件级架构可以使用基于内存计算的设计来构建，该设计加载了训练有素的DNN模型的权重。然而，这种基于硬件的DNN系统容易受到模型窃取攻击，其中攻击者反向工程（RE）并提取DNN模型的权重。在这项工作中，我们提出了一种节能防御技术，该技术将基于铁电场效应晶体管（FeFET）的可重构物理不可克隆函数（PUF）与内存中的FeFET XNOR相结合，以阻止模型窃取攻击。我们利用FE域中固有的随机性来构建PUF，当检测到对抗性攻击时，PUF有助于破坏神经网络（NN）的权重。我们通过对图神经网络（GNN）（一种特殊类型的DNN）进行实验来展示所提出的防御方案的有效性。所提出的防御方案是第一个评估GNN安全性的防御方案。对于破坏基于FeFET的PUF的两个特定误差模型和五个不同的生物信息学数据集，我们研究了破坏GNN不同层上的权重对图分类应用程序精度下降的影响。我们证明，我们的方法在小的重写脉冲后破坏了GNN的任何层，从而成功地降低了图分类的推理精度。

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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