Abstract
Wind speed fluctuations and load demand variations represent the big challenges against wind energy conversion systems (WECS). Besides, the inefficient measuring devices and the environmental impacts (e.g. temperature, humidity, and noise signals) affect the system equipment, leading to increased system uncertainty issues. In addition, the time delay due to the communication channels can make a gap between the transmitted control signal and the WECS that causes instability for the WECS operation. To tackle these issues, this paper proposes an adaptive neuro-fuzzy inference system (ANFIS) as an effective control technique for blade pitch control of the WECS instead of the conventional controllers. However, the ANFIS requires a suitable dataset for training and testing to adjust its membership functions in order to provide effective performance. In this regard, this paper also suggests an effective strategy to prepare a sufficient dataset for training and testing of the ANFIS controller. Specifically, a new optimization algorithm named the mayfly optimization algorithm (MOA) is developed to find the optimal parameters of the proportional integral derivative (PID) controller to find the optimal dataset for training and testing of the ANFIS controller. To demonstrate the advantages of the proposed technique, it is compared with different three algorithms in the literature. Another contribution is that a new time-domain named figure of demerit is established to confirm the minimization of settling time and the maximum overshoot in a simultaneous manner. A lot of test scenarios are performed to confirm the effectiveness and robustness of the proposed ANFIS based technique. The robustness of the proposed method is verified based on the frequency domain conditions that are driven from Hermite-Biehler theorem. The results emphases that the proposed controller provides superior performance against the wind speed fluctuations, load demand variations, system parameters uncertainties, and the time delay of the communication channels.
Highlights
In recent years, great interest has been attracted to generate electricity from various renewable energy sources (RESs)
The proposed technique is compared with different algorithms in the literature to ensure the effectiveness of the proposed adaptive neuro-fuzzy inference system (ANFIS) controller based on mayfly optimization algorithm (MOA)
This proportional integral derivative (PID) controller with its optimized gains can be combined with the Wind energy conversion systems (WECS) to prepare the optimal dataset for the proposed ANFIS
Summary
Great interest has been attracted to generate electricity from various renewable energy sources (RESs). M. Elsisi et al.: Robust Design of ANFIS-Based Blade Pitch Controller for WECS Against Wind Speed Fluctuations effective source to be integrated into both distribution and transmission systems [5], [6]. The common procedure is to control the pitch angle of WECS blades and the rotational speed so that the output generated power can be managed For this target, appropriate approaches must be developed which can increase the WECS efficiency while improving its dynamic performance. Thence, the WECS requires an effective adaptive controller (e.g. the proposed ANFIS based mayfly optimizer) instead of the conventional controllers for blade pitch control (BPC) to overcome the fluctuations of wind speed, which is considered the main motivation of this work that covered here. The results emphases that the proposed controller provides superior performance against the wind speed fluctuations, load demand variations, system parameters uncertainties, and the time delay of the communication channels
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