Visible to the public Biblio

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2021-03-09
Rojas-Dueñas, G., Riba, J., Kahalerras, K., Moreno-Eguilaz, M., Kadechkar, A., Gomez-Pau, A..  2020.  Black-Box Modelling of a DC-DC Buck Converter Based on a Recurrent Neural Network. 2020 IEEE International Conference on Industrial Technology (ICIT). :456–461.
Artificial neural networks allow the identification of black-box models. This paper proposes a method aimed at replicating the static and dynamic behavior of a DC-DC power converter based on a recurrent nonlinear autoregressive exogenous neural network. The method proposed in this work applies an algorithm that trains a neural network based on the inputs and outputs (currents and voltages) of a Buck converter. The approach is validated by means of simulated data of a realistic nonsynchronous Buck converter model programmed in Simulink and by means of experimental results. The predictions made by the neural network are compared to the actual outputs of the system, to determine the accuracy of the method, thus validating the proposed approach. Both simulation and experimental results show the feasibility and accuracy of the proposed black-box approach.
2020-01-13
Shen, Yitong, Wang, Lingfeng, Lau, Jim Pikkin, Liu, Zhaoxi.  2019.  A Robust Control Architecture for Mitigating Sensor and Actuator Attacks on PV Converter. 2019 IEEE PES GTD Grand International Conference and Exposition Asia (GTD Asia). :970–975.
The cybersecurity of the modern control system is becoming a critical issue to the cyber-physical systems (CPS). Mitigating potential cyberattacks in the control system is an important concern in the controller design to enhance the resilience of the overall system. This paper presents a novel robust control architecture for the PV converter system to mitigate the sensor and actuator attack and reduce the influence of the system uncertainty. The sensor and actuator attack is a vicious attack scenario when the attack signals are injected into the sensor and actuator in a CPS simultaneously. A p-synthesis robust control architecture is proposed to mitigate the sensor and actuator attack and limit the system uncertainty perturbations in a DC-DC photovoltaic (PV) converter. A new system state matrix and control architecture is presented by integrating the original system state, injected attack signals and system uncertainty perturbations. In the case study, the proposed μ-synthesis robust controller exhibits a robust performance in the face of the sensor and actuator attack.
2015-05-01
Luowei Zhou, Sucheng Liu, Weiguo Lu, Shuchang Hu.  2014.  Quasi-steady-state large-signal modelling of DC #8211;DC switching converter: justification and application for varying operating conditions. Power Electronics, IET. 7:2455-2464.

Quasi-steady-state (QSS) large-signal models are often taken for granted in the analysis and design of DC-DC switching converters, particularly for varying operating conditions. In this study, the premise for the QSS is justified quantitatively for the first time. Based on the QSS, the DC-DC switching converter under varying operating conditions is reduced to the linear time varying systems model. Thereafter, the QSS concept is applied to analysis of frequency-domain properties of the DC-DC switching converters by using three-dimensional Bode plots, which is then utilised to the optimisation of the controller parameters for wide variations of input voltage and load resistance. An experimental prototype of an average-current-mode-controlled boost DC-DC converter is built to verify the analysis and design by both frequency-domain and time-domain measurements.