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Main Authors: Ying, Jie, Zheng, Mengce, Chen, Jungan, Chen, Ruoxi, Zhua, Zhongjie, Zhu, Tiantian
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2501.00438
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author Ying, Jie
Zheng, Mengce
Chen, Jungan
Chen, Ruoxi
Zhua, Zhongjie
Zhu, Tiantian
author_facet Ying, Jie
Zheng, Mengce
Chen, Jungan
Chen, Ruoxi
Zhua, Zhongjie
Zhu, Tiantian
contents As Advanced Persistent Threat (APT) complexity increases, provenance data is increasingly used for detection. Anomaly-based systems are gaining attention due to their attack-knowledge-agnostic nature and ability to counter zero-day vulnerabilities. However, traditional detection paradigms, which train on offline, limited-size data, often overlook concept drift - unpredictable changes in streaming data distribution over time. This leads to high false positive rates. We propose incremental learning as a new paradigm to mitigate this issue. However, we identify FOUR CHALLENGES while integrating incremental learning as a new paradigm. First, the long-running incremental system must combat catastrophic forgetting (C1) and avoid learning malicious behaviors (C2). Then, the system needs to achieve precise alerts (C3) and reconstruct attack scenarios (C4). We present METANOIA, the first lifelong detection system that mitigates the high false positives due to concept drift. It connects pseudo edges to combat catastrophic forgetting, transfers suspicious states to avoid learning malicious behaviors, filters nodes at the path-level to achieve precise alerts, and constructs mini-graphs to reconstruct attack scenarios. Using state-of-the-art benchmarks, we demonstrate that METANOIA improves precision performance at the window-level, graph-level, and node-level by 30%, 54%, and 29%, respectively, compared to previous approaches.
format Preprint
id arxiv_https___arxiv_org_abs_2501_00438
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle METANOIA: A Lifelong Intrusion Detection and Investigation System for Mitigating Concept Drift
Ying, Jie
Zheng, Mengce
Chen, Jungan
Chen, Ruoxi
Zhua, Zhongjie
Zhu, Tiantian
Cryptography and Security
As Advanced Persistent Threat (APT) complexity increases, provenance data is increasingly used for detection. Anomaly-based systems are gaining attention due to their attack-knowledge-agnostic nature and ability to counter zero-day vulnerabilities. However, traditional detection paradigms, which train on offline, limited-size data, often overlook concept drift - unpredictable changes in streaming data distribution over time. This leads to high false positive rates. We propose incremental learning as a new paradigm to mitigate this issue. However, we identify FOUR CHALLENGES while integrating incremental learning as a new paradigm. First, the long-running incremental system must combat catastrophic forgetting (C1) and avoid learning malicious behaviors (C2). Then, the system needs to achieve precise alerts (C3) and reconstruct attack scenarios (C4). We present METANOIA, the first lifelong detection system that mitigates the high false positives due to concept drift. It connects pseudo edges to combat catastrophic forgetting, transfers suspicious states to avoid learning malicious behaviors, filters nodes at the path-level to achieve precise alerts, and constructs mini-graphs to reconstruct attack scenarios. Using state-of-the-art benchmarks, we demonstrate that METANOIA improves precision performance at the window-level, graph-level, and node-level by 30%, 54%, and 29%, respectively, compared to previous approaches.
title METANOIA: A Lifelong Intrusion Detection and Investigation System for Mitigating Concept Drift
topic Cryptography and Security
url https://arxiv.org/abs/2501.00438