Enhancing the spatial resolution for wire fault detection systems using multi-carrier signals
Résumé
Recently, the world is witnessing a vast daily development in technology accompanied with more and more complex electronic systems. They are hosting cumulated lengths of electrical cables that are subject one day or another to the occurrence of wiring faults. Accordingly, wire diagnosis became essentially important for ensuring safety, security, integrity, and optimal performance. On the other hand, the emergence of sensor networks and connected objects has created the need for embedded and non invasive fault diagnosis solutions. Notably, multi-carrier reflectometry methods have shown promising and efficient results in locating upcoming defects on wires in an online manner. Nevertheless, their precision stays within the physical limits of their components, especially the sampling frequency of their analog/digital transitions.
In this paper, we will propose several approaches combining multi-carrier reflectometry with phase analysis techniques to overcome this limit. Accordingly, an improvement in the precision of the fault localization and a high spatial resolution is obtained. Based on an FPGA implementation, our novel methods and the resulting systems have proven a five-time better accuracy than the state-of-the-art methods on the same platform.
Mots clés
cable
Power cables
electrical cables
complex electronic systems
wire network
electric wire
sensor network
Sensor system
fault detection
Circuit faults
wiring fault diagnosis
fault location
fault localization
cable
fault position
defect
diagnosis
complex wiring
reflectometry
transferometry
multi-carrier reflectometry
phase analysis
analog-digital transitions
phase analysis technique
FPGA
multicarrier signals
wire fault detection systems
spatial resolution
field programmable gate arrays
phase measurement
OFDM
Testing
Fourier transform
multi-carrier
defect diagnosis
high precision sensing
Reflectometry
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