A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter
The standard methodology to obtain the model of a power electronic converter is achieved by averaging the state-space dynamics of the converter's state variables. But the average of the transformer current is null over a switching cycle in the resonant dc-dc converter. Therefore, the convention...
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sg-ntu-dr.10356-1650092023-03-10T15:40:11Z A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter Iqbal, Mohammad Tauquir Maswood, Ali Iftekhar Tariq, Mohd Iqbal, Atif Verma, Vimlesh Urooj, Shabana School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Bidirectional Converter Dual Active Bridge The standard methodology to obtain the model of a power electronic converter is achieved by averaging the state-space dynamics of the converter's state variables. But the average of the transformer current is null over a switching cycle in the resonant dc-dc converter. Therefore, the conventional method is not suitable for resonant converters, including the phase-shifted bidirectional dual active bridge (PSBDAB) converter. The two-time scale discrete-type models can resolve the problem associated with the standard state-space averaging methodology. The time-scale segregates the dynamics of the PSBDAB converter into fast and slow state variables, which can be modeled separately and eases the analysis of the PSBDAB converter. The effect of the core-loss of the inductor, dead-time of the semiconductor devices, output filter capacitor's equivalent series resistance, semiconductor on-resistance, and the transformer copper loss components are included in the model to improve its steady-state and dynamics characteristics. Moreover, the stability analysis using a bifurcation diagram is carried out for the digitally controlled closed-loop of the system. Furthermore, the critical gain for the stable region with variations in the circuit parameters like load resistance, circuit equivalent inductance, and voltage demand is extensively studied. The modeling and stability analysis is validated in the simulation and experimental setup. The results verify that the proposed method accurately predicts the stable region with variations in the system circuit parameters. Thus this study provides a guide to select and tune the controller parameter to ensure the converter operates within the boundaries of the stable region. Published version This work was supported by Princess Nourah bint Abdulrahman University Researchers Supporting Project PNURSP2022R79, Princess Nourah bint Abdulrahman University, Riyadh. 2023-03-07T07:22:14Z 2023-03-07T07:22:14Z 2022 Journal Article Iqbal, M. T., Maswood, A. I., Tariq, M., Iqbal, A., Verma, V. & Urooj, S. (2022). A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter. IEEE Access, 10, 31868-31884. https://dx.doi.org/10.1109/ACCESS.2022.3151809 2169-3536 https://hdl.handle.net/10356/165009 10.1109/ACCESS.2022.3151809 2-s2.0-85124825124 10 31868 31884 en IEEE Access © 2022 The Authors. This work is licensed under a Creative Commons Attribution 4.0 License. For more information, see https://creativecommons.org/licenses/by/4.0/. application/pdf |
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Engineering::Electrical and electronic engineering Bidirectional Converter Dual Active Bridge Iqbal, Mohammad Tauquir Maswood, Ali Iftekhar Tariq, Mohd Iqbal, Atif Verma, Vimlesh Urooj, Shabana A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter |
| description |
The standard methodology to obtain the model of a power electronic converter is achieved by averaging the state-space dynamics of the converter's state variables. But the average of the transformer current is null over a switching cycle in the resonant dc-dc converter. Therefore, the conventional method is not suitable for resonant converters, including the phase-shifted bidirectional dual active bridge (PSBDAB) converter. The two-time scale discrete-type models can resolve the problem associated with the standard state-space averaging methodology. The time-scale segregates the dynamics of the PSBDAB converter into fast and slow state variables, which can be modeled separately and eases the analysis of the PSBDAB converter. The effect of the core-loss of the inductor, dead-time of the semiconductor devices, output filter capacitor's equivalent series resistance, semiconductor on-resistance, and the transformer copper loss components are included in the model to improve its steady-state and dynamics characteristics. Moreover, the stability analysis using a bifurcation diagram is carried out for the digitally controlled closed-loop of the system. Furthermore, the critical gain for the stable region with variations in the circuit parameters like load resistance, circuit equivalent inductance, and voltage demand is extensively studied. The modeling and stability analysis is validated in the simulation and experimental setup. The results verify that the proposed method accurately predicts the stable region with variations in the system circuit parameters. Thus this study provides a guide to select and tune the controller parameter to ensure the converter operates within the boundaries of the stable region. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Iqbal, Mohammad Tauquir Maswood, Ali Iftekhar Tariq, Mohd Iqbal, Atif Verma, Vimlesh Urooj, Shabana |
| format |
Article |
| author |
Iqbal, Mohammad Tauquir Maswood, Ali Iftekhar Tariq, Mohd Iqbal, Atif Verma, Vimlesh Urooj, Shabana |
| author_sort |
Iqbal, Mohammad Tauquir |
| title |
A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter |
| title_short |
A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter |
| title_full |
A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter |
| title_fullStr |
A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter |
| title_full_unstemmed |
A detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge DC-DC converter |
| title_sort |
detailed full-order discrete-time modeling and stability prediction of the single-phase dual active bridge dc-dc converter |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/165009 |
| _version_ |
1761782029494517760 |