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Auteurs principaux: Mahmud, Tahmin, Santos Jr, Euzeli Cipriano Dos
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2509.06279
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author Mahmud, Tahmin
Santos Jr, Euzeli Cipriano Dos
author_facet Mahmud, Tahmin
Santos Jr, Euzeli Cipriano Dos
contents Component ageing is a critical concern in power electronic converter systems (PECSs). It directly impacts the reliability, performance, and operational lifespan of converters used across diverse applications, including electric vehicles (EVs), renewable energy systems (RESs) and industrial automation. Therefore, understanding and monitoring component ageing is crucial for developing robust converters and achieving long-term system reliability. This paper proposes a data-driven digital twin (DT) framework for DC-DC buck converters, integrating deep neural network (DNN) with the spider monkey optimization (SMO) algorithm to monitor and predict component degradation. Utilizing a low-power prototype testbed along with empirical and synthetic datasets, the SMO+DNN approach achieves the global optimum in 95% of trials, requires 33% fewer iterations, and results in 80% fewer parameter constraint violations compared to traditional methods. The DNN model achieves $R^2$ scores above 0.998 for all key degradation parameters and accurately forecasts time to failure ($t_{failure}$). In addition, SMO-tuned degradation profile improves the converter's performance by reducing voltage ripple by 20-25% and inductor current ripple by 15-20%.
format Preprint
id arxiv_https___arxiv_org_abs_2509_06279
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle DNN-based Digital Twin Framework of a DC-DC Buck Converter using Spider Monkey Optimization Algorithm
Mahmud, Tahmin
Santos Jr, Euzeli Cipriano Dos
Systems and Control
Component ageing is a critical concern in power electronic converter systems (PECSs). It directly impacts the reliability, performance, and operational lifespan of converters used across diverse applications, including electric vehicles (EVs), renewable energy systems (RESs) and industrial automation. Therefore, understanding and monitoring component ageing is crucial for developing robust converters and achieving long-term system reliability. This paper proposes a data-driven digital twin (DT) framework for DC-DC buck converters, integrating deep neural network (DNN) with the spider monkey optimization (SMO) algorithm to monitor and predict component degradation. Utilizing a low-power prototype testbed along with empirical and synthetic datasets, the SMO+DNN approach achieves the global optimum in 95% of trials, requires 33% fewer iterations, and results in 80% fewer parameter constraint violations compared to traditional methods. The DNN model achieves $R^2$ scores above 0.998 for all key degradation parameters and accurately forecasts time to failure ($t_{failure}$). In addition, SMO-tuned degradation profile improves the converter's performance by reducing voltage ripple by 20-25% and inductor current ripple by 15-20%.
title DNN-based Digital Twin Framework of a DC-DC Buck Converter using Spider Monkey Optimization Algorithm
topic Systems and Control
url https://arxiv.org/abs/2509.06279