SCIENTIA SINICA Informationis, Volume 48 , Issue 10 : 1333-1347(2018) https://doi.org/10.1360/N112018-00016

Bilevel planning of active distribution networks considering demand-side management and DG penetration

More info
  • ReceivedJan 16, 2018
  • AcceptedApr 12, 2018
  • PublishedOct 8, 2018


Funded by






[1] Zhan H, Wang C, Wang Y. Relay Protection Coordination Integrated Optimal Placement and Sizing of Distributed Generation Sources in Distribution Networks. IEEE Trans Smart Grid, 2016, 7: 55-65 CrossRef Google Scholar

[2] Mohtashami S, Pudjianto D, Strbac G. Strategic Distribution Network Planning With Smart Grid Technologies. IEEE Trans Smart Grid, 2017, 8: 2656-2664 CrossRef Google Scholar

[3] Zha Y B, Zhang T, Huang Z, et al. Analysis of energy Internet key technologies. Sci Sin Inform, 2014, 44: 702--713. Google Scholar

[4] Al Kaabi S S, Zeineldin H H, Khadkikar V. Planning Active Distribution Networks Considering Multi-DG Configurations. IEEE Trans Power Syst, 2014, 29: 785-793 CrossRef ADS Google Scholar

[5] Zhou L, Li F, Tong X. Active network management considering wind and load forecasting error. IEEE Trans Smart Grid, 2017, 8: 2694-2701 CrossRef Google Scholar

[6] Capitanescu F, Ochoa L F, Margossian H. Assessing the Potential of Network Reconfiguration to Improve Distributed Generation Hosting Capacity in Active Distribution Systems. IEEE Trans Power Syst, 2015, 30: 346-356 CrossRef ADS Google Scholar

[7] Olivier F, Aristidou P, Ernst D. Active Management of Low-Voltage Networks for Mitigating Overvoltages Due to Photovoltaic Units. IEEE Trans Smart Grid, 2016, 7: 926-936 CrossRef Google Scholar

[8] Martins V F, Borges C L T. Active distribution network integrated planning incorporating distributed generation and load response uncertainties. IEEE Trans Power Syst, 2011, 26: 2146--2172. Google Scholar

[9] Ravadanegh S N, Roshanagh R G. On optimal multistage electric power distribution networks expansion planning. Int J Electrical Power Energy Syst, 2014, 54: 487-497 CrossRef Google Scholar

[10] Cheng H, Zeng P, Xing H. Active distribution network expansion planning integrating dispersed energy storage systems. IET Gener Transm Distrib, 2016, 10: 638-644 CrossRef Google Scholar

[11] Shen X, Shahidehpour M, Han Y. Expansion Planning of Active Distribution Networks With Centralized and Distributed Energy Storage Systems. IEEE Trans Sustain Energy, 2017, 8: 126-134 CrossRef ADS Google Scholar

[12] Aien M, Fotuhi-Firuzabad M, Rashidinejad M. Probabilistic optimal power flow in correlated hybrid wind-photovoltaic power systems. IEEE Trans Smart Grid, 2014, 5: 130-138 CrossRef Google Scholar

[13] Cao Y, Zhang Y, Zhang H. Probabilistic Optimal PV Capacity Planning for Wind Farm Expansion Based on NASA Data. IEEE Trans Sustain Energy, 2017, 8: 1291-1300 CrossRef ADS Google Scholar

[14] Ran X, Miao S. Three-phase probabilistic load flow for power system with correlated wind, photovoltaic and load. IET Gener Transm Distrib, 2016, 10: 3093-3101 CrossRef Google Scholar

[15] Li X, Chen H J, Du D J. Study on the impact of charging/discharging strategy of electric vehicles on voltage level of active distribution system considering multi-period and variable correlations. Proc CSEE, 2018, 38: 526--536. Google Scholar

[16] Ai X, Zhou S P, Chen Z Q, et al. Research on optimal schedualing model and solving method for power system with interruptible load considering multi stochastic factors. Proc CSEE, 2017, 37: 2231--2241. Google Scholar

[17] Zhu L, Zhou X Y, Tang L J, et al. Multi-objective optimal operation for microgrid considering interruptible loads. Power Syst Technol, 2017, 41: 1847--1854. Google Scholar

[18] Wang Y, Ai X, Tan Z. Interactive Dispatch Modes and Bidding Strategy of Multiple Virtual Power Plants Based on Demand Response and Game Theory. IEEE Trans Smart Grid, 2016, 7: 510-519 CrossRef Google Scholar

[19] Picciariello A, Alvehag K, Soder L. Impact of Network Regulation on the Incentive for DG Integration for the DSO: Opportunities for a Transition Toward a Smart Grid. IEEE Trans Smart Grid, 2015, 6: 1730-1739 CrossRef Google Scholar

[20] Gill S, Kockar I, Ault G W. Dynamic optimal power flow for active distribution networks. IEEE Trans Power Syst, 2014, 29: 121--131. Google Scholar

[21] Salih S N, Chen P. On Coordinated Control of OLTC and Reactive Power Compensation for Voltage Regulation in Distribution Systems With Wind Power. IEEE Trans Power Syst, 2016, 31: 4026-4035 CrossRef ADS Google Scholar

[22] Luo T, Dolan M J, Davidson E M. Assessment of a New Constraint Satisfaction-Based Hybrid Distributed Control Technique for Power Flow Management in Distribution Networks with Generation and Demand Response. IEEE Trans Smart Grid, 2015, 6: 271-278 CrossRef Google Scholar

[23] Fang C, Zhang X, Cheng H Z, et al. Framework planning of distribution network containing distributed generation considering active management. Power Syst Technol, 2014, 38: 823--829. Google Scholar

[24] Liu S J, Li T R, Horng S J, et al. Complex network construction based on matrix operation. Sci Sin Inform, 2016, 46: 610--626. Google Scholar

[25] Yang H, Yang S, Xu Y. Electric Vehicle Route Optimization Considering Time-of-Use Electricity Price by Learnable Partheno-Genetic Algorithm. IEEE Trans Smart Grid, 2015, 6: 657-666 CrossRef Google Scholar

[26] Xinsheng Lai , Yuren Zhou , Jun He . Performance Analysis of Evolutionary Algorithms for the Minimum Label Spanning Tree Problem. IEEE Trans Evol Computat, 2014, 18: 860-872 CrossRef Google Scholar

[27] Hou Y S, Wang X L, Duan J, et al. Transmission lines de-icing optimal scheduling considering system risk. Proc CSEE, 2014, 34: 6101--6108. Google Scholar

[28] Wei Z N, Ji C, Sun G Q, et al. Interior-point optimal power flow of AC-DC system with VSC-HVDC. Proc CSEE, 2012, 32: 89--95. Google Scholar

[29] Torquato R, Shi Q, Xu W. A Monte Carlo Simulation Platform for Studying Low Voltage Residential Networks. IEEE Trans Smart Grid, 2014, 5: 2766-2776 CrossRef Google Scholar

[30] Zhang J, Fan H, Tang W. Planning for distributed wind generation under active management mode. Int J Electrical Power Energy Syst, 2013, 47: 140-146 CrossRef Google Scholar

[31] Zhang S X, Li K, Cheng H Z, et al. Siting and sizing planning of distributed wind generators under active management mode. Autom Electr Power Syst, 2015, 39: 208--214. Google Scholar