An Enhanced P&amp;O MPPT Algorithm for PV Systems with Fast Dynamic and Steady-State Response under Real Irradiance and Temperature Conditions

International Journal of Photoenergy

Nguimfack–Ndongmo

2023

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Maximum power point tracking (MPPT) is becoming more and more important in the optimization of photovoltaic systems. Several MPPT algorithms and nonlinear controllers have been developed for improving the energy yield of PV systems. On the one hand, most of the conventional algorithms such as the incremental conductance (INC) demonstrate a good affinity for the maximum power point (MPP) but often fail to ensure acceptable stability and robustness of the PV system against fast-changing operating conditions. On the other hand, the MPPT nonlinear controllers can palliate the robust limitations of the algorithms. However, most of these controllers rely on expensive solar irradiance measurement systems or complex and relatively less accurate methods to seek the maximum power voltage. In this paper, we propose a new hybrid MPPT based on the incremental conductance algorithm and the integral backstepping controller. The hybrid scheme exploits the benefits of the INC algorithm in seeking the maximum power voltage and feeds a nonlinear integral backstepping controller whose stability was ensured by the Lyapunov theory. Therefore, in terms of characteristics, the overall system is a blend of the MPP-seeking potential of the INC and the nonlinear and robust potentials of the integral backstepping controller (IBSC). It was noted that the hybrid system successfully palliates the conventional limitations of the isolated INC and relieves the PV system from the expensive burden of solar irradiance measurement. The proposed hybrid system increased the operational efficiency of the PV system to 99.94% and was found better than the INC MPPT algorithm and 8 other recently published MPPT methods. An extended validation under experimental environmental conditions showed that the hybrid system is approximately four times faster than the INC in tracking the maximum power with better energy yield than the latter.

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Section: Resultsmentioning

confidence: 99%

“…In the recent decade, numerous maximum power point tracking algorithms have been deployed in the literature [10][11][12][13][14][15][16][17][18][19][20][21][22]. These algorithms differ in cost, complexity, and performance.…”

Section: Introductionmentioning

confidence: 99%

A New Hybrid MPPT Based on Incremental Conductance-Integral Backstepping Controller Applied to a PV System under Fast-Changing Operating Conditions

International Journal of Photoenergy

Nguimfack–Ndongmo

2023

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“…The equivalent circuit of the PV reference model is shown in Figure 1. It is based on the single diode which offers a good compromise between complexity and performance [17][18][19][20].…”

Section: Modelling Of the Reference Pv Modelmentioning

confidence: 99%

“…Therefore, it becomes imperative to continually track this point and ensure that PV systems operate at their maximum energy potential [20]. In the spirit of optimizing PV systems, numerous maximum power point tracking (MPPT) algorithms/controllers have been developed in this recent decade [19,[30][31][32][33]. The perturb and observe (P&O) and incremental conductance algorithm (INC) are the most popular MPPT algorithms/controllers.…”

Section: Application Of the Pve For Simulating And Validation Of Mppt...mentioning

confidence: 99%

A New High-Performance Photovoltaic Emulator Suitable for Simulating and Validating Maximum Power Point Tracking Controllers

International Journal of Photoenergy

2023

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Photovoltaic (PV) research is rapidly growing, and the need for controlled environments to validate new MPPT controllers is becoming increasingly important. Currently, researchers face several challenges in testing MPPT algorithms due to the unpredictable nature of solar PV power generation. In this paper, we propose a new photovoltaic emulator (PVE) that could replace solar panels and ensure a highly controllable environment suitable for testing photovoltaic (PV) systems. In this PVE, the complex nonlinear equations of the PV cell/module are fast computed and resolved by a new linearization technique which involves the systematic breakdown of the current-voltage ( I - V ) curve of the PV into twelve linear segments. Based on input environmental conditions, an artificial neural network (ANN) was constructed to assist the linearization process by predicting the current-voltage boundary coordinates of these segments. Using simple linear equations, with the segment boundary coordinates, a reference voltage was generated for the PVE. A nonlinear backstepping controller was designed to exploit the reference voltage and stabilize the power conversion stage (PCS). The PVE was optimized using particle swarm optimization (PSO). Several tests have shown that the proposed nonlinear controller provides better dynamic and robust performance than the PI controller, the most reputable and recurrent control method in the area of PVE. The PVE was coupled with a recently proposed integral backstepping MPPT controller and analyzed under several dynamic conditions, including the MPPT test specified by EN 50530. It was found that the accuracy of the proposed PVE measured by its relative error is less than 0.5%, with an MPPT efficiency of greater than 99.5%. The attractive results achieved by this PVE make it especially suitable for simulating and validating MPPT controllers.

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“…Faced with such continuous variation, it is crucial to continuously track the MPP. Consequently, a series of maximum power point tracking (MPPT) algorithms have been reported in different scientific literature MPP [ [2] , [3] , [4] , [5] , [6] ]. As revealed by the literature, the classical conventional algorithm such as perturb and observe (P&O), and incremental conductance algorithm (INC) stand out as the simplest and most popular approaches.…”

Section: Introductionmentioning

confidence: 99%

Solar irradiance estimation and optimum power region localization in PV energy systems under partial shaded condition

Nguimfack–Ndongmo

2023

Heliyon

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