Energy-Efficient Wake-Up Signalling for Machine-Type Devices Based on Traffic-Aware Long Short-Term Memory Prediction

Reducing energy consumption is a pressing issue in low-power machine-type communication (MTC) networks. In this regard, the Wake-up Signal (WuS) technology, which aims to minimize the energy consumed by the radio interface of the machine-type devices (MTDs), stands as a promising solution. However,...

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Bibliographic Details
Published in:IEEE internet of things journal 2022-11, Vol.9 (21), p.21620-21631
Main Authors: Ruiz-Guirola, David E., Rodriguez-Lopez, Carlos A., Montejo-Sanchez, Samuel, Souza, Richard Demo, Lopez, Onel L. A., Alves, Hirley
Format: Article
Language:English
Subjects:
Delays
Energy consumption
Energy efficiency
False alarms
Forecasting
Internet of Things
machine-type communication (MTC)
neural network (NN)
Neural networks
Power demand
Power management
Predictive models
Symbols
System dynamics
traffic prediction
Traffic volume
wake-up signal (WuS)
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Summary:Reducing energy consumption is a pressing issue in low-power machine-type communication (MTC) networks. In this regard, the Wake-up Signal (WuS) technology, which aims to minimize the energy consumed by the radio interface of the machine-type devices (MTDs), stands as a promising solution. However, state-of-the-art WuS mechanisms use static operational parameters, so they cannot efficiently adapt to the system dynamics. To overcome this, we design a simple but efficient neural network to predict MTC traffic patterns and configure WuS accordingly. Our proposed forecasting WuS (FWuS) leverages an accurate long short-term memory (LSTM)-based traffic prediction that allows extending the sleep time of MTDs by avoiding frequent page monitoring occasions in the idle state. Simulation results show the effectiveness of our approach. The traffic prediction errors are shown to be below 4%, being a false-alarm and miss-detection probabilities, respectively, below 8.8% and 1.3%. In terms of energy consumption reduction, FWuS can outperform the best benchmark mechanism by up to 32%. Finally, we certify the ability of FWuS to dynamically adapt to traffic density changes, promoting low-power MTC scalability.
ISSN:2327-4662
2327-4662
DOI:10.1109/JIOT.2022.3181889