Abstract
With the growing robustness of modern power systems, the occurrence of load curtailment events is becoming lower. Hence, the simulation of these events constitutes a challenge in adequacy indices assessment. Due to the rarity of the load curtailment events, the standard Monte Carlo simulation (MCS) estimator of adequacy indices is not practical. Therefore, a framework based on the enhanced cross-entropy-based importance sampling (ECE-IS) method is introduced in this paper for computing the adequacy indices. The framework comprises two stages. Using the proposed ECE-IS method, the first stage’s purpose is to identify the samples or states of the nodal generation and load that are greatly significant to the adequacy indices estimators. In the second stage, the density of the input variables’ conditional on the load curtailment domain obtained by the first stage are used to compute the nodal and system adequacy indices. The performance of the ECE-IS method is verified through a comparison with the standard MCS method and the recent techniques of rare events simulation in literature. The results confirm that the proposed method develops an accurate estimation for the nodal and system adequacy indices (loss of load probability (LOLP), expected power not supplied (EPNS)) with appropriate convergence value and low computation time.
Highlights
Power system reliability evaluation plays a crucial role in the decision-making process of power system development planning
This paper presents an improved version of theofCE-importance sampling (IS)
This paper presents an improved version the CE-IS
Summary
Power system reliability evaluation plays a crucial role in the decision-making process of power system development planning. The reliability evaluation process invariably involves consideration of adequacy and security concepts [1,2]. Security is explained as “the measure of how an electric power system can withstand sudden disturbances such as electric short circuits or unanticipated. While adequacy is determined as ”a measure of the ability of a bulk power system to supply the aggregate electric power and energy requirements of the customers within component ratings and voltage limits, taking into account scheduled and unscheduled outages of system components and the operating constraints imposed by operations”. Three main functional zones of a power system are highlighted in the part of reliability related to adequacy [1]. HL1 is associated with the total system generation. HL2, in addition to generation facilities, includes transmission facilities. HL3 considers a full power system structure up to individual consumer points
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