- 1Power China Huadong Engineering Co. Ltd., Hangzhou, China
- 2Department of Electrical Engineering, Bahria University, Islamabad, Pakistan
- 3Department of Electrical Engineering, Quaid-e-Azam College of Engineering and Technology, Sahiwal, Pakistan
- 4Department of Electrical Engineering, University of Engineering and Technology, Mardan, Pakistan
- 5 Department of Electrical Engineering, College of Engineering, King Khalid University, Abha, Saudi Arabia
This paper introduces a novel control strategy called Finite-time Integral Terminal Sliding Mode Control (FITSMC), explicitly designed for a permanent-magnet synchronous generator (PMSG)-based standalone Wind Energy Conversion System (WECS). The primary objective of the FITSMC strategy is to regulate the operation of the wind turbine efficiently and maximize power extraction from the WECS. To achieve this, the system is driven onto a sliding surface within a predefined terminal time, ensuring rapid convergence and overall stability. An important advantage of the FITSMC strategy is its ability to maintain a standalone wind power system close to the maximum power point, even under varying wind conditions and load changes. In addition, the controller demonstrates robustness against uncertainties and disturbances, making it highly suitable for real-world applications. Extensive simulations and analyses have been conducted to validate the effectiveness of the proposed FITSMC. The results show a superior control performance compared to traditional methods. Consequently, the FITSMC strategy represents a promising advancement in control techniques for standalone wind power systems, providing an efficient and reliable approach for harnessing power from wind energy.
1 Introduction
Increasing global population and economic development have led to the establishment of new power plants to meet rising energy demands. However, the energy crisis, higher oil prices, and climate change underscore the significance of Renewable Energy Resources (RESs) (Anjum et al., 2022). Governments worldwide are now prioritizing effective, sustainable, and environmentally friendly renewable energy systems. Renewable energy sources, such as wind and solar energy systems, have grown substantially, catering to energy demand while considering environmental concerns and the finite nature of nonrenewable energy sources.
Wind energy, being green and environmentally friendly, offers a promising solution for reducing the dependence on fossil fuels and mitigating their negative impacts (Dali et al., 2021). Technological advancements in wind energy have played a crucial role in power system integration, control theory, aerodynamic designs, mechanical systems, and power electronic converters. Extracting the maximum power (MP) from wind power systems (WPS) is a crucial research area. Wind speed sensorless Maximum Power Point Tracking (MPPT) control has gained considerable attention for optimizing power extraction without physically altering the wind turbine or system components. Various techniques and design considerations have been explored for WPSs (Cullen, 2000; Raj and Kumar, 2018; Costanzo et al., 2019).
In the existing literature, robust controllers have been developed and studied for extracting maximum power Pmax from the wind (Aboudrar et al., 2019; Syahputra and Soesanti, 2019; Cheikh et al., 2020; Saidi et al., 2020; Khan et al., 2021; Alam et al., 2022; Khan et al., 2022; Chand et al., 2023). Some studies have focused on reactive power and maximum inverter power extraction without wind speed sensors (Abdullah et al., 2012), whereas others have explored adaptive MPPT schemes and improved control techniques for grid-connected wind turbines (Jaramillo-Lopez et al., 2016; Pan and Shao, 2020; Hawkins and McIntyre, 2021). Furthermore, numerous other MPPT control approaches have been developed for wind energy systems, enhancing their efficiency and reliability (Chu et al., 2014). These techniques fall into three categories: conventional methods, population-based algorithms, and artificial intelligence (AI) strategies. However, maintaining the maximum power output across all wind speeds remains challenging because of inherent nonlinear characteristics (Tafticht et al., 2006; Soetedjo et al., 2011). Various estimation techniques have been employed, but some may introduce vulnerabilities owing to modelling inaccuracies (Lee et al., 2009; Ullah et al., 2023; Ullah et al., 2021).
Sliding mode control (SMC) is widely considered as a robust nonlinear MPPT control strategy. However, the chattering and asymptotic convergence issues have led to criticism. To address these challenges, a solution has been presented in the form of an integral sliding mode control (ISMC) strategy (Ullah S. et al., 2020), which enhances robustness and diminishes chattering. Despite its advantages, tuning the switching gain parameter in the ISMC remains challenging. In the study described in (Wang et al., 2019), a novel adaptive Lyapunov stability-based backstepping control technique was proposed for MPPT of a variable-speed PMSG-WECS. The control strategy is designed to provide robustness against uncertainties even without prior knowledge of the upper bounds. Overall, the backstepping technique offers a fast dynamic response and robustness. However, it also presents challenges regarding design complexity, real-time implementation feasibility, and the possibility of controlling the signal chattering. Overcoming these limitations and effectively applying backstepping control in practical systems require careful consideration and precise tuning.
This study contributes significantly to three key areas. 1) Introducing an FITSMC methodology for a fixed-pitch, variable-speed, 3 kW standalone PMSG-WECS in the presence of measurement noise to optimize power output by tracking the MPP. The FITSMC method is novel in the aforesaid system due to its innovative control approach, addressing nonlinear dynamics and uncertainties. This ensures rapid and accurate control of wind energy systems, enhancing performance and reliability, even under variable wind conditions. The FITSMC reduces mechanical and electrical stresses, extends component lifetimes, and promotes system sustainability. This adoption in PMSG-WECS contributes significantly to renewable energy and control systems, advancing wind energy integration into the power grid for a cleaner, sustainable energy transition. 2) Transforming the dynamical model of the considered PMSG-WECS system into a control-convenient input-output form serves as the basis for designing the control methodology. 3) Validation of the efficacy and performance of the proposed control technique through extensive simulation experiments in MATLAB. The obtained results are meticulously compared with established literature results, solidifying the evidence of the effectiveness and advantages of the proposed control design.
The remainder of this paper is organized as follows. Section 2 presents the equivalent model of a PMSG-WECS and provides the essential mathematical preliminaries. In Section 3, a control algorithm is derived to achieve the maximum power extraction from the PV array, ensuring optimal efficiency. A discussion of the simulation results, which show the robustness of the proposed control law, can be found in Section 4. Finally, Section 5 offers concluding remarks, summarizing the findings and contributions of this study.
1.1 Mathematical notations and variables
The analysis of the PMSG-WECS involves a wide array of constants and parameters. These include critical factors such as the mechanical power output of the turbine (PM), wind speed expressed in meters per second (Vwind), air density (ρ), and area swept by the turbine blades (A). Additionally, the conversion of the wind turbine rotor power is governed by the wind turbine rotor power conversion coefficient (Γwind) and the blade radius is represented by
Turning to the modeling of the PMSG itself, a meticulous examination of the electrical properties was conducted. This includes variables such as the stator resistance
Control strategies played an integral role in the analysis. A control input (u) is introduced into the system, and the design incorporates constants such as
2 Dynamical modeling of the standalone PMSG-WECS
This section describes the dynamical modelling of the system under study. As illustrated in Figure 1, the system schematic encompasses essential components such as the power electronic converter, gearbox, variable speed wind turbine (VSWT), PMSG coupled with the VSWT, and load. We aim to examine the behavior of the system and the interplay between these components, ultimately formulating mathematical models that facilitate control design and performance assessment.
2.1 Dynamical modeling of the wind turbine
The following set of mathematical equations describes a wind turbine with fixed-pitch configuration Zafran et al. (2020); Khan et al. (2021):
where PM represents the turbine output mechanical power, Vwind is the wind speed in m/s, ρ denotes the air density, and A is the area swept by the blades. The parameter Γwind is defined as:
The dynamic modelling of the variable-speed standalone PMSG-WECS involves key parameters such as the blade radius
For the variable speed wind turbine reported in Munteanu et al. (2009), Cp can be determined by the numerical following approximation while considering β = 00:
The VSWT is optimized to track the maximum value of Cp, denoted as
In this study, the critical wind turbine parameters include the air density ρ (set to 1.25 kg/m3), gears ratio or transmission ratio i (equal to 7), blade radius
Having discussed the essential rotor blade parameters, the next section briefly explores them.
2.2 Modelling of the permanent magnet synchronous generator
A simplified dq model of the three-phase PMSG in the dq-reference frame, neglecting the zero components, is utilized for the dynamical modelling of the variable speed standalone WECS. The dq-axis voltages represent output variables. The following set of differential equations describes the PMSG model.
where vd and vq represent the voltages along the dq-axes,
where p denotes the number of pole pairs,
The system, characterized by its input vector
The nonlinear smooth state vector field
Now, by utilizing Equations 6, 7, we can represent the PMSG-WECS model in state-space form as follows:
where
To determine the relative degree r of the considered system, one can ensure the satisfaction of the following equation is satisfied:
where
By implementing (Eq. 9), the following expressions are obtained.
This confirms that the studied system had a relative degree of 2. Subsequently, we transform the system into an input-output form in the following subsection and design the control input u accordingly.
2.3 Input-output form transformation
Prior to expressing the system in a standard canonical form (normal form or input-output form), a coordinate transformation for the system is required. This transformation is performed as follows:
where
and the inverse coordinates transform are
Now, the system dynamics in the
where
Note that the control input u will be designed with the help of a fast integral terminal SMC scheme, and we check the stability of the system’s third internal dynamic state in the following subsection.
2.4 Zero-dynamic stability investigation of the system
After all the calculations and transformation into a
To analyze the stability of the zero-dynamic state, we set the following variables to zero:
where k1 > l1, so
The zero-dynamic state remains stable for all k1 > l1, where k1 is a positive integer.
In the next step, we will design a control algorithm to adjust the duty cycle and maximize power extraction from the wind turbine system.
3 Finite-time sliding mode controller for maximum power point tracking of WECS
This section introduces a novel nonlinear fast integral terminal SMC strategy to regulate the generator speed of a PMSG in a WECS. The primary goal of the proposed control law is to optimize the chop resistance, ensuring that the generator operates at its optimal speed and achieves the maximum power extraction from the PMSG.
3.1 Control design
The first step in the control design is to precisely track the reference speed. To accomplish this, we define the tracking error as
where zd represents the desired or reference value for the variable z. By taking the double derivative of the error, we obtain
The finite-time integral terminal sliding surface is defined as
Here,
By utilizing the values of
Assuming
The strong reachability factor is defined as
Hence, the overall control input becomes
3.2 Stability analysis
To demonstrate the stability of the PMSG-WECS under the FITSMC, we use a Lyapunov-based stability analysis and use the following Lyapunov function to prove the enforcement of the sliding mode:
Taking the derivative of
By substituting the value of
After substituting the controller u(q) value and simplifying it, we obtain
Because
The uncertainty term
We can rewrite inequality (Eq. 32) as:
To solve the Lyapunov function for the sliding surface, we have
By substituting
where
The above inequality signifies rapid finite-time convergence, meaning that, as time progresses,
4 Results and discussion
This section presents crucial simulation results that play a vital role in the design and implementation of a robust control technique for a WECS. We implement the controllers and the system model in MATLAB, connecting them using “goto” and “from” blocks. The simulation results demonstrate the effectiveness of FITSMC in accurately tracking the maximum power curve of the WECS. MATLAB simulations show the successful performance of the controller, ensuring precise speed tracking while incorporating the maximum power coefficient (Cp = 0.4762) and maintaining the tip speed ratio close to its optimal value (λ = 7). We conducted the simulations over a 50-s duration, considering an average wind speed of vw = 7 m/s.
Using the simulation results, we compare three control techniques: Feedback Linearization Control (FLC), Global Sliding Mode Control (GSMC), and finite-time integral terminal SMC. The main focus was on evaluating the tracking performance of the PMSG wind shaft speed with respect to the reference speed. Figures 3, 4 show the results of the performance evaluation. Figure 3 demonstrates that FITSMC outperformed GSMC in terms of the tracking performance. Additionally, Figure 4 illustrates the speed tracking error of the PMSG, showing that both the FLC and FITSMC, along with the GSMC, exhibit finite-time convergence.
In comparison to the FLC and GSMC, the FITSMC demonstrated a significant improvement in the tip speed ratio performance, as depicted in Figure 5. FITSMC exhibits reduced oscillation around the optimal tip speed ratio (λopt) and accurately tracks λopt, making it a promising candidate for achieving MPPT in variable-speed wind turbine systems.
In Figure 6, FITSMC analyzes the power conversion coefficient of the VSWT and compares its results with those of the FLC and GSMC. FITSMC effectively tracks the optimal power conversion coefficient (Cp = 0.4762) throughout the stochastic wind speed profile, thereby ensuring efficient wind power extraction. The zoomed-in regions in Figure 6 visually represent FITSMC’s exceptional tracking performance for Cp(max). The proposed MPPT strategy ensures highly efficient wind power extraction with minimal chattering, surpassing other MPPT approaches, such as FLC and GSMC. It precisely regulates the Tip Speed Ratio (TSR) at λopt = 7 and maintains the maximum power coefficient
In the context of control system performance evaluation, various error metrics play a crucial role in assessing the effectiveness of a control strategy. For the system under study, it is essential to consider various aspects of the control performance. The significance of these error metrics is evident as follows: 1) The Integral Absolute Error (IAE) quantifies the magnitude of the absolute errors over a designated timeframe, offering valuable insights into the overarching capability of the control system for precise tracking. In the context of wind energy, precise tracking is crucial for maximizing energy production by ensuring that wind turbines operate near their maximum power point. A lower IAE indicates the proficiency of the control system in minimizing deviations from the desired performance. 2) The Integral Squared Error (ISE) and Integral Time Squared Error (ITSE) metrics emphasize minimizing both the error magnitude and its persistence over time. While IAE focuses on the absolute error magnitude, ISE and ITSE encompass squared errors accumulated over time. In the context of wind energy, reducing squared errors is critically important to mitigate the effects of prolonged performance deviations, which are vital for maintaining the stability and efficiency of wind turbines that operate continuously for extended periods. 3) The integral of the Time Absolute Error (ITAE) amalgamates both aspects of tracking precision (absolute error) and the control system’s efficiency concerning the response time. In wind energy systems, achieving MPPT requires not only precision, but also rapid adaptation to changing wind conditions. ITAE quantifies overall control efficiency, considering both aspects.
In the context of control strategy performance, these error metrics become invaluable tools for assessment. Specifically, in the performance evaluation of the FITSMC control strategy, a comparison was made with the results obtained through two other control techniques, FLC and GSMC, via various error metrics, including ISE, ITSE, IAE, and ITAE. The simulation results, as illustrated in Figures 11–14, reveal how FITSMC excels in achieving precise tracking and finite-time convergence, while accumulating reduced errors over time. Through this comparison, it is evident that FITSMC outperforms both FLC and GSMC regarding tracking accuracy and efficiency, demonstrating the effectiveness of the control strategy in wind energy systems.
In summary, a comparative study between FITSMC, FLC, and GSMC provides valuable insights into the control and optimization of Wind Energy Conversion Systems. The FITSMC is a robust and efficient control technique that excels in tracking performance and MPPT capabilities. Its superiority makes it a promising option for enhancing the overall performance and efficiency of wind-energy conversion systems in practical applications. By employing the FITSMC, significant progress can be made in harnessing wind power effectively and promoting sustainability in the energy sector.
5 Conclusion
This paper presented a novel control approach, Finite-time Integral Terminal Sliding Mode Control, designed for standalone wind power systems to efficiently regulate wind turbine operation and maximize power extraction from wind energy. The FITSMC strategy drives the system onto a sliding surface within a predefined terminal time, ensuring rapid convergence and overall stability. Extensive simulations demonstrated the robustness of the controller against uncertainties and disturbances, demonstrating its superiority over conventional methods in extracting the maximum power from wind resources. In future research, an extension of comparative analyses, optimization of FITSMC parameters, real-world experiments, integration of energy storage solutions, and exploration of AI-driven predictive control are envisioned to advance renewable energy technology and sustainability. These efforts are aimed at advance renewable energy technologies and sustainability.
Data availability statement
The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.
Author contributions
L-GH: Formal Analysis, Funding acquisition, Supervision, Investigation, Writing–review and editing. AA: Conceptualization, Data curation, Methodology, Software, Writing–original draft. SU: Conceptualization, Formal Analysis, Methodology, Project administration, Software, Supervision, Validation, Writing–original draft, Writing–review and editing. GH: Software, Supervision, Writing–review and editing. MZ: Formal Analysis, Investigation, Methodology, Writing–review and editing. LJ: Data curation, Funding acquisition, Validation, Writing–review and editing.
Funding
This research was funded by the Deanship of Scientific Research at King Khalid University. Dr. Monji Mohamed Zaidi, the Principal Investigator of the project, received a salary and provided financial support for this work through the Deanship of Scientific Research at King Khalid University. Dr. Monji also actively contributed to the research by collecting data, interpreting the results, and participating in reviewing the writing of the paper. Additionally, the authors acknowledge the Deanship of Scientific Research at King Khalid University for their support through large group Research Project grant (Grant Number: RGP2/105/44).
Acknowledgments
The authors extend their appreciation to the Deanship of Scientific Research at King Khalid University for funding this work through a large-group Research Project under grant number RGP2/105/44.
Conflict of interest
Authors L-GH and LJ are employed by PowerChina Huadong Engineering Corporation Limited, China.
The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
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Keywords: finite-time integral terminal SMC, maximum power point tracking (M.P.P.T), permanent magnet synchronous generator (PMSG), wind turbine (WT), wind energy system (WES)
Citation: Hua L-G, Ali A, Ullah S, Hafeez G, Zaidi MM and Jun LJ (2023) Robust finite-time integral terminal sliding mode control design for maximum power extraction of PMSG-based standalone wind energy system. Front. Energy Res. 11:1293267. doi: 10.3389/fenrg.2023.1293267
Received: 12 September 2023; Accepted: 26 October 2023;
Published: 15 November 2023.
Edited by:
Michael Howard Meylan, The University of Newcastle, AustraliaReviewed by:
Sahaj Saxena, Thapar Institute of Engineering and Technology, IndiaOmveer Singh, Gautam Buddha University, India
Copyright © 2023 Hua, Ali, Ullah, Hafeez, Zaidi and Jun. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Safeer Ullah, dr_safeer_ullah@quaideazam.edu.pk