Optimal modulation strategy based on fundamental reactive power for dual-active-bridge converters |
Zhu, Zhichao
(National Key Laboratory of Science and Technology on Vessel Integrated Power System, Naval University of Engineering)
Xiao, Fei (National Key Laboratory of Science and Technology on Vessel Integrated Power System, Naval University of Engineering) Liu, Jilong (National Key Laboratory of Science and Technology on Vessel Integrated Power System, Naval University of Engineering) Chen, Peng (School of Electrical Engineering, Southeast University) Huang, Zhaojie (National Key Laboratory of Science and Technology on Vessel Integrated Power System, Naval University of Engineering) Ren, Qiang (National Key Laboratory of Science and Technology on Vessel Integrated Power System, Naval University of Engineering) |
1 | Wang, Y., Song, Q., Sun, Q., Zhao, B., Li, J., Liu, W.: Multilevel MVDC link strategy of high-frequency-link DC transformer based on switched capacitor for MVDC power distribution. IEEE Trans. Industr. Electron. 64(04), 2829-2835 (2017) DOI |
2 | Tong, A., Hang, L., Li, G., Jiang, X., Gao, S.: Modeling and analysis of a dual-active-bridge-isolated bidirectional DC/DC converter to minimize RMS current with whole operating range. IEEE Trans. Power Electron. 33(06), 5302-5316 (2018) DOI |
3 | Zhao, B., Song, Q., Liu, W., Sun, W.: Current-stress-optimized switching strategy of isolated bidirectional DC-DC converter with dual-phase-shift control. IEEE Trans. Ind. Electron. 60(10), 4458-4467 (2013) DOI |
4 | Segaran, D., Holmes, D.G., McGrath, B.P.: Enhanced load step response for a bidirectional DC-DC converter. IEEE Trans. Power Electron. 28(01), 371-379 (2013) DOI |
5 | Sha, G., Wang, C., Cheng, H., Deng, J., Wang, J.: Unified phasor analytical method for bi-directional dual-active-bridge DC-DC converter under phase-shift control. Trans. China Electrotech. Soc. 32(18), 176-185 (2017) |
6 | Xue, F., Yu, R., Huang, A.Q.: A 98.3% efficient GaN isolated bidirectional DC-DC converter for DC microgrid energy storage system applications. IEEE Trans. Ind. Electron. 64(11), 9094-9103 (2017) DOI |
7 | Zhao, B., Song, Q., Liu, W., Liu, G., Zhao, Y.: Universal high-frequency-link characterization and practical fundamental-optimal strategy for dual-active-bridge DC-DC converter under PWM plus phase-shift control. IEEE Trans. Power Electron. 30(12), 6488-6494 (2015) DOI |
8 | Choi, W., Rho, K., Cho, B.: Fundamental duty modulation of dual-active-bridge converter for wide-range operation. IEEE Trans. Power Electron. 31(06), 4048-4064 (2016) DOI |
9 | Cheng, H., Ma, Z., Wang, C., Sha, G.: Analysis of the RMS current of dual active bridge DC-DC converters based on fourier series modeling. Electr. Power Autom. Equip. 37(05), 14-20 (2017) |
10 | Li, J., Luo, Q., Mou, D., Wei, Y., Sun, P., Du, X.: A hybrid five-variable modulation scheme for dual active bridge converter with minimal RMS current. IEEE Trans. Ind. Electron. 69(01), 336-346 (2022) DOI |
11 | Sun, Q., Li, Y., Liu, G., Wang, Y., Meng, J., Mu, Q.: Multiple-modular high-frequency DC transformer with parallel clamping switched capacitor for flexible MVDC and HVDC system applications. IEEE J. Emerg. Sel. Top. Power Electron. 8(4), 4130-4143 (2020) DOI |
12 | Ren, Q., Ai, S.: A three degree freedom optimal control strategy of dual-active-bridge converters for full range operations. Proc. CSEE. 40(11), 3613-3621 (2020) |
13 | Zhao, B., Yu, Q., Sun, W.: Extended-phase-shift control of isolated bidirectional DC-DC converter for power distribution in microgrid. IEEE Trans. Power Electron. 27(11), 4667-4680 (2012) DOI |
14 | Krismer, F., Kolar, J.W.: Efficiency-optimized high-current dual active bridge converter for automotive applications. IEEE Trans. Ind. Electron. 59(07), 2745-2760 (2012) DOI |
15 | Chen, L., Tarisciotti, L., Costabeber, A., Guan, Q., Wheeler, P., Zanchetta, P.: Phase-shift modulation for a current-fed isolated DC-DC converter in more electric aircrafts. IEEE Trans. Power Electron. 34(09), 8528-8543 (2019) DOI |
16 | Sun, Z., Xiao, L., Wang, Q.: Review research on control technology of output parallel dual-active-bridge-converters. Proc. CSEE. 41(05), 1811-1831 (2021) |
17 | Li, J., Zhao, B., Song, Q., Huang, Y., Sun, Q., Wang, Y., Liu, W.: DC solid state transformer based on multilevel DC link for medium-voltage DC distribution application. Proc. CSEE. 36(14), 3717-3725 (2016) |
18 | Bai, H., Mi, C.: Eliminate reactive power and increase system efficiency of isolated bidirectional dual-active-bridge DC-DC converters using novel dual-phase-shift control. IEEE Trans. Power Electron. 23(06), 2905-2914 (2008) DOI |
19 | Zhao, B., Song, Q., Liu, W.: Efficiency characterization and optimization of isolated bidirectional DC-DC converter based on dual-phase-shift Control for DC distribution application. IEEE Trans. Power Electron. 28(04), 1711-1727 (2013) DOI |
20 | An, F., Song, W., Yang, K.: Multi-objective optimization control scheme based on extended phase-shift of dual-active-bridge DC-DC converters. Proc. CSEE. 39(03), 822-831 (2019) |
21 | Sha, D., Zhang, J., Liu, K.: Leakage inductor current peak optimization for dual-transformer current-fed dual active bridge DC-DC converter with wide input and output voltage range. IEEE Trans. Power Electron. 35(06), 6012-6024 (2020) DOI |
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