Adjustable robust optimal power flow with the price of robustness for large-scale power systems

DC optimal power flow (DCOPF) has been widely used in modern power system operation and planning. With the consideration of the stochastic renewable resources integration, an adjustable robust DCOPF is studied in this work in combination with generator participation factors to obtain an optimal solution that can immunise against all realisations of the renewable resource output variability. However, the robust optimisation may lead to an extreme conservative optimal solution compared to the traditional deterministic optimisation. Therefore, the price of robustness is taken into account which provides a tradeoff between the robust optimal solution and the traditional optimal solution for decision makers. According to the duality theory, the robust DCOPF is transformed into a convex quadratic program, which has a large number of linear constraints. In order to efficiently solve the robust DCOPF for applications in large-scale power systems, an inactive constraints reduction technique is introduced to identify the inactive security constraints before solving the proposed model, which greatly improves the computational performance. Numerical results on the IEEE 14-bus, 118-bus and other six large Polish test systems validate the effectiveness of the proposed method.

[1]  Han Yu,et al.  An Optimal Power Flow Algorithm to Achieve Robust Operation Considering Load and Renewable Generation Uncertainties , 2012, IEEE Transactions on Power Systems.

[2]  Melvyn Sim,et al.  The Price of Robustness , 2004, Oper. Res..

[3]  A.G. Bakirtzis,et al.  A decentralized implementation of DC optimal power flow on a network of computers , 2005, IEEE Transactions on Power Systems.

[4]  A. Papavasiliou,et al.  Reserve Requirements for Wind Power Integration: A Scenario-Based Stochastic Programming Framework , 2011, IEEE Transactions on Power Systems.

[5]  Yue Yuan,et al.  Optimal operation strategy of energy storage unit in wind power integration based on stochastic programming , 2011 .

[6]  R D Zimmerman,et al.  MATPOWER: Steady-State Operations, Planning, and Analysis Tools for Power Systems Research and Education , 2011, IEEE Transactions on Power Systems.

[7]  S. H. Madaeni,et al.  The impacts of stochastic programming and demand response on wind integration , 2013 .

[8]  T. S. Chung,et al.  Optimal active power flow incorporating power flow control needs in flexible AC transmission systems , 1999 .

[9]  I. Erlich,et al.  A Stochastic Model for the Optimal Operation of a Wind-Thermal Power System , 2009, IEEE Transactions on Power Systems.

[10]  J. Watson,et al.  Multi-Stage Robust Unit Commitment Considering Wind and Demand Response Uncertainties , 2013, IEEE Transactions on Power Systems.

[11]  Xiaohong Guan,et al.  Fast Identification of Inactive Security Constraints in SCUC Problems , 2010, IEEE Transactions on Power Systems.

[12]  Xu Andy Sun,et al.  Adaptive Robust Optimization for the Security Constrained Unit Commitment Problem , 2013, IEEE Transactions on Power Systems.

[13]  A. Conejo,et al.  Multi-area coordinated decentralized DC optimal power flow , 1998 .

[14]  Rabih A. Jabr,et al.  Adjustable Robust OPF With Renewable Energy Sources , 2013, IEEE Transactions on Power Systems.

[15]  Jianhua Chen,et al.  A Robust Wind Power Optimization Method for Look-Ahead Power Dispatch , 2014, IEEE Transactions on Sustainable Energy.