Tensor-Based Multi-Scale Correlation Anomaly Detection for AIoT-Enabled Consumer Applications

IF 4.3 2区计算机科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Consumer Electronics Pub Date : 2024-12-17 DOI:10.1109/TCE.2024.3519437

Jiuzhen Zeng;Laurence T. Yang;Chao Wang;Xianjun Deng;Xiangli Yang

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引用次数: 0

Abstract

Artificial Intelligence of Things (AIoT) is an innovative paradigm expected to enable various consumer applications that is transforming our lives. While enjoying benefits and services from these applications, we also face serious security issues due to malicious cyber attacks on the massive growth of AIoT consumer devices. Accurate anomaly detection is one of the critical tasks for the trustworthy AIoT removing those obstacles. However, limited by the vector-based data pattern and ill-considered factors for anomalous samples analysis, existing methods suffer from the low detection performance. In this paper, a multi-scale correlation tensor convolutional Gaussian mixture network (named as MTCGM) is presented for ameliorating this actuality. Specifically, MTCGM suggests to construct the multi-scale correlation tensor by stacking one self-correlation matrix and multiple surrounding-correlations of different scales, which well characterizes the network status of AIoT. Subsequently, a 3D-convolutional autoencoder (3DCA) is designed for capturing inter-feature correlations, and followed with a Gaussian mixture probability (GMP) network for the observations likelihood estimation. Moreover, low-dimensional space features, relative Euclidean distance and tensor cosine similarity (TCS) are adopted in MTCGM as the multi-factor to boost the likelihood estimation. Extensive experiments on public benchmark datasets verify the validity of MTCGM, and demonstrate its superiority over the state-of-the-art baselines even in presence of contaminated training samples and input noise.

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基于张量的多尺度相关异常检测用于支持aiiot的消费者应用

物联网人工智能（AIoT）是一种创新范式，有望实现各种消费者应用，改变我们的生活。在享受这些应用带来的好处和服务的同时，我们也面临着严重的安全问题，因为大量增长的AIoT消费设备受到恶意网络攻击。准确的异常检测是可信AIoT消除这些障碍的关键任务之一。然而，现有的异常样本分析方法受限于基于向量的数据模式和考虑不充分的因素，检测性能较低。为了改善这一现状，本文提出了一种多尺度相关张量卷积高斯混合网络（MTCGM）。具体而言，MTCGM建议将一个自相关矩阵与多个不同尺度的周围相关矩阵叠加构成多尺度相关张量，可以很好地表征AIoT的网络状态。随后，设计了3d -卷积自编码器（3DCA）来捕获特征间的相关性，然后使用高斯混合概率（GMP）网络进行观测值的似然估计。此外，MTCGM采用低维空间特征、相对欧氏距离和张量余弦相似度（TCS）作为多因素来增强似然估计。在公共基准数据集上的大量实验验证了MTCGM的有效性，并证明了即使存在受污染的训练样本和输入噪声，它也优于最先进的基线。

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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来源期刊

IEEE Transactions on Consumer Electronics 工程技术-电信学

CiteScore

7.70

自引率

9.30%

发文量

审稿时长

3.3 months

期刊介绍： The main focus for the IEEE Transactions on Consumer Electronics is the engineering and research aspects of the theory, design, construction, manufacture or end use of mass market electronics, systems, software and services for consumers.