Abstract
The real-time broadband properties of impedance in power line communication (PLC) systems are one of the essential characteristics of future smart grids, which would enable the smart online systems to implement fault detection/forecast or the PLC channel health monitoring in the grid. In the current paper, a novel technique was proposed to track impedance only by the channel frequency response (CFR). The CFR can be treated as a known quantity and is normally calculated by the channel estimation algorithms in PLC devices for communication purposes. The relationship between CFR and impedance behavior was first studied in detail, and it was found that the variations in certain key factors, such as the frequency characteristics and the values of peak-valley difference, of the CFR curves could be used to the track real-time impedance. Then, the proposed impedance estimation algorithm harnessed the variational mode decomposition (VMD) as a feature extraction method to obtain useful frequency properties. The machine learning (ML)-based impedance model was also synthesized in the proposed approach. The performance of the proposed impedance tracking method was examined under two different scenarios, and the obtained simulation results demonstrated the efficiencies of the formulated algorithms.
Highlights
The power line communication (PLC)-based smart grids (SGs) are a very competitive alternative for future grid upgrades and can provide easy and effective communication between two random pairs of electrical nodes
SIMULATION RESULTS the effectiveness of the proposed inversion modeling is demonstrated based on the results of numerical simulations for impedance estimation
RANDOMLY GENERATED PLC CHANNEL (CFR AND IMPEDANCE) The network scenario illustrated in Figs. 1 and 2 was used during numerical simulations
Summary
The power line communication (PLC)-based smart grids (SGs) are a very competitive alternative for future grid upgrades and can provide easy and effective communication between two random pairs of electrical nodes. One salient feature of future SGs is the ability of pervasive monitoring and control of different types of electrical events, such as grid anomalies and cable aging [1]–[3]. Relevant methods have been developed to use power line communication devices as communication equipment and grid sensors to monitor the operation status of SGs [4]. Different strategies have been proposed to detect and distinguish different electrical events that are traditionally solved by the phasor measurement unit (PMU), and the abundant broadband information enables PLC devices to perform additional functions. The proper usage of impedance information is one of the main issues in the field of multifunctional SG communication.
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