U-SCAD: An Unsupervised Method of System Call-Driven Anomaly Detection for Containerized Edge Clouds

U-SCAD: An Unsupervised Method of System Call-Driven Anomaly Detection for Containerized Edge Clouds

Container technology is currently one of the mainstream technologies in the field of cloud computing, yet its adoption in resource-constrained, latency-sensitive edge environments introduces unique security challenges. While existing system call-based anomaly-detection methods partially address thes...

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Bibliographic Details
Main Authors: Jiawei Ye, Ming Yan, Shenglin Wu, Jingxuan Tan, Jie Wu
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Future Internet
Subjects:
anomaly detection
container security
system calls
edge computing
Online Access:https://www.mdpi.com/1999-5903/17/5/218
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Summary:Container technology is currently one of the mainstream technologies in the field of cloud computing, yet its adoption in resource-constrained, latency-sensitive edge environments introduces unique security challenges. While existing system call-based anomaly-detection methods partially address these issues, they suffer from high false positive rates and excessive computational overhead. To achieve security and observability in edge-native containerized environments and lower the cost of computing resources, we propose an unsupervised anomaly-detection method based on system calls. This method filters out unnecessary system call data through automatic rule generation and an unsupervised classification model. To increase the accuracy of anomaly detection and reduce the false positive rates, this method embeds system calls into sequences using the proposed Syscall2vec and processes the remain sequences in favor of the anomaly detection model’s analysis. We conduct experiments using our method with a background based on modern containerized cloud microservices. The results show that the detection part of our method improves the F1 score by 23.88% and 41.31%, respectively, as compared to HIDS and LSTM-VAE. Moreover, our method can effectively reduce the original processing data to 13%, which means that it significantly lowers the cost of computing resources.
ISSN:1999-5903

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