Abstract
Distributed generation including wind turbine (WT) and photovoltaic panel increased very fast in recent years around the world, challenging the conventional way of probabilistic load flow (PLF) calculation. Reliable and efficient PLF method is required to take into account such changing. This paper studies the maximum entropy probabilistic density function reconstruction method based on cumulant arithmetic of linearized load flow formulation, and then develops a maximum entropy based PLF (ME-PLF) calculation algorithm for power system integrated with wind power generation (WPG). Comparing to traditional Gram–Charlier expansion based PLF (GC-PLF) calculation method, the proposed ME-PLF calculation algorithm can obtain more reliable and accurate probabilistic density functions (PDFs) of bus voltages and branch flows in various WT parameter scenarios. It can solve the limitation of GC-PLF calculation method that mistakenly gaining negative values in tail regions of PDFs. Linear dependence between active and reactive power injections of WPG can also be effectively considered by the modified cumulant calculation framework. Accuracy and efficiency of the proposed approach are validated with some test systems. Uncertainties yielded by the wind speed variations, WT locations, power factor fluctuations are considered.
Highlights
CrossCheck date: 15 November 2017Received: 24 December 2016 / Accepted: 15 November 2017 / Published online: 27 February 2018 Ó The Author(s) 2018
This paper proposes a maximum entropy (ME)-probabilistic load flow (PLF) calculation algorithm for power system integrated with wind power generation (WPG)
The proposed algorithm gives more reliable and accurate probabilistic density functions (PDFs) results of bus voltages and branch flows comparing with Gram–Charlier expansion based PLF (GC-PLF) calculation method in scenarios with different wind turbine (WT) parameters
Summary
Load flow calculation is one of the most important tools to analyze static characteristics of electric power systems [1]. The most used technique in PLF calculation is Monte Carlo simulation (MCS) [6, 7] It involves repeated load flow processes with various values of input variables yielded by their PDFs. Based on the MCS, a Latin supercube sampling method have been applied to improve the efficiency of MCS [8]. The combined cumulant (semi-variant) algorithm and Gram–Charlier (GC) expansion theory can be used to convert the complicated convolution calculation into a simple arithmetic process according to the superior properties of cumulants [12] This method greatly enhances the calculation speed and is able to accurately approximate the PDF or CDF of output variables [13,14,15,16,17]. A ME based PLF (ME-PLF) calculation algorithm for power systems integrated with WPG is proposed to improve the PDF accuracy of bus voltages and branch flows.
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