Open Switch Fault Diagnosis in Three-Phase Voltage Source Inverters Using Single Neuron Implementation

• Published in: Processes Vol. 13; no. 4; p. 1070
• Main Authors: Dale, Manisha, Kamble, Vaishali H., Dhumale, R. B., Nanthaamornphong, Aziz
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 03.04.2025
• Subjects: Accuracy; Algorithms; Artificial neural networks; Controllers; Digital signal processors; Discrete Wavelet Transform; Electric inverters; Electric potential; Fault detection; Fault diagnosis; Faults; Fourier transforms; Fuzzy logic; Hardware; Inverters; Methods; Microprocessors; Neural networks; Neurons; Power converters; Real time; Signal processing; Spectrum analysis; Transistors; Voltage; Wavelet transforms; Washington, D.C
• ISSN: 2227-9717; 2227-9717
• DOI: 10.3390/pr13041070

Fault diagnosis in power converters is essential for keeping electrical systems stable, efficient and long-lasting. Park’s Vector Transform, discrete wavelet transform, Artificial Neural Network, Fuzzy Logic and other methods are used to diagnose faults in the power converter in both single and multiple open switch situations. These methods are implemented on the digital signal processor or controller, which needs additional hardware and consumes more processing time. This paper presents a hardware-based open switch fault diagnostic method in a 3ϕ voltage source inverter to minimize fault diagnosis time and cost. An innovative hardware-based approach that utilizes a single neuron for open switch fault diagnosis in 3ϕ voltage source inverters was successfully implemented without using a digital signal processor or controller. A gradient descent algorithm calculates the weight and bias values of a single processing neuron. Furthermore, a high-speed multiplier and adder circuit seamlessly integrate with the single processing neuron, enabling rapid real-time fault diagnosis. This method is capable of diagnosing single and multiple switch open circuit faults in switching devices under variable load conditions at different frequencies. The proposed system ensures good effectiveness and resistivity, detecting faults in less than one cycle with low implementation effort and no tuning or threshold dependence. It achieves 98% accuracy, 96% precision and 95% recall, with a 2% false positive rate. Unlike traditional methods, it eliminates DSP/controller dependency by using a single neuron-based processing circuit, reducing cost and improving real-time fault diagnosis in three-phase voltage source inverters.