English

Rethinking Spatio-Temporal Anomaly Detection: A Vision for Causality-Driven Cybersecurity

Machine Learning 2025-07-14 v1 Artificial Intelligence Emerging Technologies Neural and Evolutionary Computing

Abstract

As cyber-physical systems grow increasingly interconnected and spatially distributed, ensuring their resilience against evolving cyberattacks has become a critical priority. Spatio-Temporal Anomaly detection plays an important role in ensuring system security and operational integrity. However, current data-driven approaches, largely driven by black-box deep learning, face challenges in interpretability, adaptability to distribution shifts, and robustness under evolving system dynamics. In this paper, we advocate for a causal learning perspective to advance anomaly detection in spatially distributed infrastructures that grounds detection in structural cause-effect relationships. We identify and formalize three key directions: causal graph profiling, multi-view fusion, and continual causal graph learning, each offering distinct advantages in uncovering dynamic cause-effect structures across time and space. Drawing on real-world insights from systems such as water treatment infrastructures, we illustrate how causal models provide early warning signals and root cause attribution, addressing the limitations of black-box detectors. Looking ahead, we outline the future research agenda centered on multi-modality, generative AI-driven, and scalable adaptive causal frameworks. Our objective is to lay a new research trajectory toward scalable, adaptive, explainable, and spatially grounded anomaly detection systems. We hope to inspire a paradigm shift in cybersecurity research, promoting causality-driven approaches to address evolving threats in interconnected infrastructures.

Keywords

Cite

@article{arxiv.2507.08177,
  title  = {Rethinking Spatio-Temporal Anomaly Detection: A Vision for Causality-Driven Cybersecurity},
  author = {Arun Vignesh Malarkkan and Haoyue Bai and Xinyuan Wang and Anjali Kaushik and Dongjie Wang and Yanjie Fu},
  journal= {arXiv preprint arXiv:2507.08177},
  year   = {2025}
}

Comments

5 pages, 1 figure, Under Review in Vision Paper Track-ACM SIGSPATIAL 2025

R2 v1 2026-07-01T03:55:36.799Z