Abstract
In real-world applications - to minimize the impact of failures - machinery is often monitored by various sensors. Their role comes down to acquiring data and sending it to a more powerful entity, such as an embedded computer or cloud server. There have been attempts to reduce the computational effort related to data processing in order to use edge computing for predictive maintenance. The aim of this paper is to push the boundaries even further by proposing a novel architecture, in which processing is moved to the sensors themselves thanks to decrease of computational complexity given by the usage of compressed recurrent neural networks. A sensor processes data locally, and then wirelessly sends only a single packet with the probability that the machine is working incorrectly. We show that local processing of the data on ultra-low power wireless sensors gives comparable outcomes in terms of accuracy but much better results in terms of energy consumption that transferring of the raw data. The proposed ultra-low power hardware and firmware architecture makes it possible to use sensors powered by harvested energy while maintaining high confidentiality levels of the failure prediction previously offered by more powerful mains-powered computational platforms.
Highlights
Around 50% of all energy generated in the world is consumed by electric induction motors [1]
In this article we propose a novel, low-cost system that is capable of detecting selected types of induction motor faults by utilizing compressed recurrent neural networks
We show the results of our experiments including tests of wireless sensor with ultra-low power consumption used for predictive maintenance of induction motors
Summary
Around 50% of all energy generated in the world is consumed by electric induction motors [1] This leads to increased interest in the topic of fault prediction and detection [2]. Such a solution involves using low-energy IoT devices capable of processing raw data locally, without the need to transfer said data [10]. In this article we propose a novel, low-cost system that is capable of detecting selected types of induction motor faults by utilizing compressed recurrent neural networks. M. Markiewicz et al.: Predictive Maintenance of Induction Motors Using Ultra-Low Power Wireless Sensors and CRNNs.
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