TY - JOUR
T1 - Two-Stage Deep Anomaly Detection With Heterogeneous Time Series Data
AU - Jeong, Kyeong Joong
AU - Park, Jin Duk
AU - Hwang, Kyusoon
AU - Kim, Seong Lyun
AU - Shin, Won Yong
N1 - Publisher Copyright:
© 2013 IEEE
PY - 2022
Y1 - 2022
N2 - We introduce a data-driven anomaly detection framework using a manufacturing dataset collected from a factory assembly line. Given heterogeneous time series data consisting of operation cycle signals and sensor signals, we aim at discovering abnormal events. Motivated by our empirical findings that conventional single-stage benchmark approaches may not exhibit satisfactory performance under our challenging circumstances, we propose a two-stage deep anomaly detection (T-DAD) framework in which two different unsupervised learning models are adopted depending on types of signals. In Stage I, we select anomaly candidates by using a model trained by operation cycle signals; in Stage II, we finally detect abnormal events out of the candidates by using another model, which is suitable for taking advantage of temporal continuity, trained by sensor signals. A distinguishable feature of our framework is that operation cycle signals are exploited first to find likely anomalous points, whereas sensor signals are leveraged to filter out unlikely anomalous points afterward. Our experiments comprehensively demonstrate the superiority over single-stage benchmark approaches, the model-agnostic property, and the robustness to difficult situations.
AB - We introduce a data-driven anomaly detection framework using a manufacturing dataset collected from a factory assembly line. Given heterogeneous time series data consisting of operation cycle signals and sensor signals, we aim at discovering abnormal events. Motivated by our empirical findings that conventional single-stage benchmark approaches may not exhibit satisfactory performance under our challenging circumstances, we propose a two-stage deep anomaly detection (T-DAD) framework in which two different unsupervised learning models are adopted depending on types of signals. In Stage I, we select anomaly candidates by using a model trained by operation cycle signals; in Stage II, we finally detect abnormal events out of the candidates by using another model, which is suitable for taking advantage of temporal continuity, trained by sensor signals. A distinguishable feature of our framework is that operation cycle signals are exploited first to find likely anomalous points, whereas sensor signals are leveraged to filter out unlikely anomalous points afterward. Our experiments comprehensively demonstrate the superiority over single-stage benchmark approaches, the model-agnostic property, and the robustness to difficult situations.
KW - Anomaly detection
KW - Autoregressive processes
KW - Benchmark testing
KW - Hidden Markov models
KW - Long short term memory
KW - Manufacturing
KW - Time series analysis
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U2 - 10.1109/ACCESS.2022.3147188
DO - 10.1109/ACCESS.2022.3147188
M3 - Article
AN - SCOPUS:85124095761
SN - 2169-3536
VL - 10
SP - 13704
EP - 13714
JO - IEEE Access
JF - IEEE Access
ER -