Unsupervised anomaly detection in time series exploiting local and global information

PROCEEDINGS OF THE INTERNATIONAL CONFERENCE OF COMPUTATIONAL METHODS IN SCIENCES AND ENGINEERING 2019 (ICCMSE-2019) Pub Date : 2019-12-10 DOI:10.1063/1.5138100

Emanuele La Malfa, G. Malfa

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Abstract

We introduce a novel machine learning ensemble architecture for anomaly detection, that exploits global and local information from a 1d time series. A double step validation is performed to decide if a time period is anomalous: from one side a Long Short-Term Memory is trained to be reliable at forecasting, hence a parametric test on the forecasting’s error is used spot the anomalies. Concurrently, a Variational Autoencoder is trained to compress both global and local information from the series to a low-dimensional normal distribution, raising an anomaly if a time step’s likelihood is below a threshold. While anomaly detection with deep learning techniques often comes with the assumption that forecasting error is gaussian, we prove that this is in general a wrong assumption: we show that error function is better approximated by a distribution chosen dynamically. We validate our work on some public physical datasets, outperforming the current deep learning methods in terms of precision and recall.We introduce a novel machine learning ensemble architecture for anomaly detection, that exploits global and local information from a 1d time series. A double step validation is performed to decide if a time period is anomalous: from one side a Long Short-Term Memory is trained to be reliable at forecasting, hence a parametric test on the forecasting’s error is used spot the anomalies. Concurrently, a Variational Autoencoder is trained to compress both global and local information from the series to a low-dimensional normal distribution, raising an anomaly if a time step’s likelihood is below a threshold. While anomaly detection with deep learning techniques often comes with the assumption that forecasting error is gaussian, we prove that this is in general a wrong assumption: we show that error function is better approximated by a distribution chosen dynamically. We validate our work on some public physical datasets, outperforming the current deep learning methods in terms of precision and recall.

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利用局部和全局信息的时间序列无监督异常检测

我们引入了一种新的机器学习集成架构用于异常检测，该架构利用了来自一维时间序列的全局和局部信息。执行双步验证以确定时间段是否异常:从一方面训练长短期记忆在预测方面是可靠的，因此使用预测误差的参数测试来发现异常。同时，一个变分自编码器被训练来压缩全局和局部信息从序列到一个低维正态分布，提出一个异常，如果一个时间步长的似然低于阈值。虽然深度学习技术的异常检测通常伴随着预测误差为高斯分布的假设，但我们证明这通常是一个错误的假设:我们表明，动态选择的分布可以更好地近似误差函数。我们在一些公共物理数据集上验证了我们的工作，在精度和召回率方面优于当前的深度学习方法。我们引入了一种新的机器学习集成架构用于异常检测，该架构利用了来自一维时间序列的全局和局部信息。执行双步验证以确定时间段是否异常:从一方面训练长短期记忆在预测方面是可靠的，因此使用预测误差的参数测试来发现异常。同时，一个变分自编码器被训练来压缩全局和局部信息从序列到一个低维正态分布，提出一个异常，如果一个时间步长的似然低于阈值。虽然深度学习技术的异常检测通常伴随着预测误差为高斯分布的假设，但我们证明这通常是一个错误的假设:我们表明，动态选择的分布可以更好地近似误差函数。我们在一些公共物理数据集上验证了我们的工作，在精度和召回率方面优于当前的深度学习方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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PROCEEDINGS OF THE INTERNATIONAL CONFERENCE OF COMPUTATIONAL METHODS IN SCIENCES AND ENGINEERING 2019 (ICCMSE-2019)

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