DDMT: Denoising Diffusion Mask Transformer Models for Multivariate Time
Series Anomaly Detection
- URL: http://arxiv.org/abs/2310.08800v2
- Date: Mon, 30 Oct 2023 06:23:59 GMT
- Title: DDMT: Denoising Diffusion Mask Transformer Models for Multivariate Time
Series Anomaly Detection
- Authors: Chaocheng Yang and Tingyin Wang and Xuanhui Yan
- Abstract summary: We introduce a novel Adaptive Dynamic Neighbor Mask (ADNM) mechanism and integrate it with the Transformer and Denoising Diffusion Model.
The ADNM module is introduced to mitigate information leakage between input and output features during data reconstruction.
The Denoising Diffusion Transformer (DDT) employs the Transformer as an internal neural network structure for Denoising Diffusion Model.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Anomaly detection in multivariate time series has emerged as a crucial
challenge in time series research, with significant research implications in
various fields such as fraud detection, fault diagnosis, and system state
estimation. Reconstruction-based models have shown promising potential in
recent years for detecting anomalies in time series data. However, due to the
rapid increase in data scale and dimensionality, the issues of noise and Weak
Identity Mapping (WIM) during time series reconstruction have become
increasingly pronounced. To address this, we introduce a novel Adaptive Dynamic
Neighbor Mask (ADNM) mechanism and integrate it with the Transformer and
Denoising Diffusion Model, creating a new framework for multivariate time
series anomaly detection, named Denoising Diffusion Mask Transformer (DDMT).
The ADNM module is introduced to mitigate information leakage between input and
output features during data reconstruction, thereby alleviating the problem of
WIM during reconstruction. The Denoising Diffusion Transformer (DDT) employs
the Transformer as an internal neural network structure for Denoising Diffusion
Model. It learns the stepwise generation process of time series data to model
the probability distribution of the data, capturing normal data patterns and
progressively restoring time series data by removing noise, resulting in a
clear recovery of anomalies. To the best of our knowledge, this is the first
model that combines Denoising Diffusion Model and the Transformer for
multivariate time series anomaly detection. Experimental evaluations were
conducted on five publicly available multivariate time series anomaly detection
datasets. The results demonstrate that the model effectively identifies
anomalies in time series data, achieving state-of-the-art performance in
anomaly detection.
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