Abstract

Recently, wireless sensor networks (WSNs) have been extensively deployed to monitor environments. Sensor nodes are susceptible to fault generation due to hardware and software failures in harsh environments. Anomaly detection for the time-series streaming data of sensor nodes is a challenging but critical fault diagnosis task, particularly in large-scale WSNs. The data-driven approach is becoming essential for the goal of improving the reliability and stability of WSNs. We propose a data-driven anomaly detection approach in this paper, named median filter (MF)-stacked long short-term memory-exponentially weighted moving average (LSTM-EWMA), for time-series status data, including the operating voltage and panel temperature recorded by a sensor node deployed in the field. These status data can be used to diagnose device anomalies. First, a median filter (MF) is introduced as a preprocessor to preprocess obvious anomalies in input data. Then, stacked long short-term memory (LSTM) is employed for prediction. Finally, the exponentially weighted moving average (EWMA) control chart is employed as a detector for recognizing anomalies. We evaluate the proposed approach for the panel temperature and operating voltage of time-series streaming data recorded by wireless node devices deployed in harsh field conditions for environmental monitoring. Extensive experiments were conducted on real time-series status data. The results demonstrate that compared to other approaches, the MF-stacked LSTM-EWMA approach can significantly improve the detection rate (DR) and false rate (FR). The average DR and FR values with the proposed approach are 95.46% and 4.42%, respectively. MF-stacked LSTM-EWMA anomaly detection also achieves a better F2 score than that achieved by other methods. The proposed approach provides valuable insights for anomaly detection in WSNs by detecting anomalies in the time-series status data recorded by wireless sensor nodes.

Highlights

  • The in situ deployment of large numbers of wireless sensor nodes in areas of interest plays an increasingly important role in the sensing environment owing to recent developments and trends in wireless sensor networks (WSNs)

  • The results demonstrate that compared to other approaches, the median filter (MF)-stacked long short-term memory (LSTM)-exponentially weighted moving average (EWMA) approach can significantly improve the detection rate (DR) and false rate (FR)

  • If the raw value is non-anomalous and it is detected as non-anomalous, it is recorded as a TN; if it is we evaluate the performance of the proposed MF-stacked LSTM-EWMA using detected as anomalous, it is recorded as a FP [42]

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Summary

Introduction

The in situ deployment of large numbers of wireless sensor nodes in areas of interest plays an increasingly important role in the sensing environment owing to recent developments and trends in wireless sensor networks (WSNs). The WSN enables easy deployment of networked environment. Sensors 2020, 20, 5646 monitoring devices, which are able to collect various data and transfer the collected data to datacenters through the Internet in real time [1,2,3]. In IoT-enabled applications, WSNs are the most important component of the global earth observation system of systems (GEOSSs), since fundamental information on both the surrounding environment and the system operation status is recorded by networked sensor nodes [4,5]. A wireless node consisting of a datalogger that connects with various sensors provides the service of environmental monitoring. A solution that can improve the monitoring services of WSNs is needed

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