Time Series Anomaly Detection for Cyber-physical Systems via Neural
System Identification and Bayesian Filtering
- URL: http://arxiv.org/abs/2106.07992v1
- Date: Tue, 15 Jun 2021 09:11:35 GMT
- Title: Time Series Anomaly Detection for Cyber-physical Systems via Neural
System Identification and Bayesian Filtering
- Authors: Cheng Feng, Pengwei Tian
- Abstract summary: AIoT technologies have led to an increasing popularity of utilizing machine learning algorithms to detect operational failures for cyber-physical systems (CPS)
We propose a novel time series anomaly detection method called Neural System Identification and Bayesian Filtering (NSIBF) in which a specially crafted neural network architecture is posed for system identification.
We show that NSIBF compares favorably to the state-of-the-art methods with considerable improvements on anomaly detection in CPS.
- Score: 1.9924944826583602
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: Recent advances in AIoT technologies have led to an increasing popularity of
utilizing machine learning algorithms to detect operational failures for
cyber-physical systems (CPS). In its basic form, an anomaly detection module
monitors the sensor measurements and actuator states from the physical plant,
and detects anomalies in these measurements to identify abnormal operation
status. Nevertheless, building effective anomaly detection models for CPS is
rather challenging as the model has to accurately detect anomalies in presence
of highly complicated system dynamics and unknown amount of sensor noise. In
this work, we propose a novel time series anomaly detection method called
Neural System Identification and Bayesian Filtering (NSIBF) in which a
specially crafted neural network architecture is posed for system
identification, i.e., capturing the dynamics of CPS in a dynamical state-space
model; then a Bayesian filtering algorithm is naturally applied on top of the
"identified" state-space model for robust anomaly detection by tracking the
uncertainty of the hidden state of the system recursively over time. We provide
qualitative as well as quantitative experiments with the proposed method on a
synthetic and three real-world CPS datasets, showing that NSIBF compares
favorably to the state-of-the-art methods with considerable improvements on
anomaly detection in CPS.
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