Modeling and Simulation of Photovoltaic Cell using Single Diode Solar Cell and Double Diode Solar Cell Model

Chandel, Tarana Afrin; Yasin, Mohd Yusuf; Mallick, M.A.

doi:10.35940/ijitee.j8863.0881019

Cited by 11 publications

(7 citation statements)

References 7 publications

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“…The PV cell is configured so that it takes solar irradiance as input and generates electrical energy as output [ 41 ]. Typically, electrical equivalent models of PV cells are presented as either single-diode models [ 42 ] or two-diode models [ 43 ]. The two-diode model, being more complex, requires additional parameters to design a precise model.…”

Section: System Overview and Model Descriptionmentioning

confidence: 99%

Nonlinear control of two-stage single-phase standalone photovoltaic system

Latif,

Khan,

Agha

et al. 2024

PLoS ONE

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This paper presents a single-phase Photovoltaic (PV) inverter with its superior and robust control in a standalone mode. Initially, modeling and layout of the Buck-Boost DC-DC converter by adopting a non-linear Robust Integral Back-stepping controller (RIBSC) is provided. The controller makes use of a reference voltage generated through the regression plane so that the operating point corresponding to the maximum power point (MPP) could be achieved through the converter under changing climatic conditions. The other main purpose of the Buck-Boost converter is to act like a transformer and produce an increased voltage at the inverter input whenever desired. By not using a transformer makes the circuit size more compact and cost-effective. The proposed RIBSC is applied to an H-bridge inverter with an LC filter to produce the sinusoidal wave in the presence of variations in the output to minimize the difference between the output voltage and the reference voltage. Lyapunov stability criterion has been used to verify the stability and finite-time convergence of the overall system. The overall system is simulated in MATLAB/Simulink to test the system performance with different loads, varying climatic conditions and inverter reference voltages. The proposed methodology is compared with a back-stepping controller and Proportional Integral Derivative (PID) controller under rapidly varying climatic conditions. Results demonstrated that the proposed technique yielded a tracking time of 0.01s, a total harmonic distortion of 9.71% and a root means square error of 0.3998 in the case of resistive load thus showing superior control performance compared to the state-of-the-art control techniques.

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Section: System Overview and Model Descriptionmentioning

confidence: 99%

Nonlinear control of two-stage single-phase standalone photovoltaic system

Latif,

Khan,

Agha

et al. 2024

PLoS ONE

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“…DC/DC boost converters offer several advantages in various applications, including voltage boost, efficient power conversion, compact size, regulated output, versatility, power source flexibility, ripple reduction, and control and protection features. These converters en-able step-up voltages, high efficiency, compact size, and regulated output, making them ideal for low input voltage systems like battery-powered devices [26,27] They are also compact and lightweight, making them suitable for space constraints and integrating into various devices. Regulatory output ensures a stable power supply, especially in sensitive electronic circuits.…”

Section: Modelling Of Boost Convertermentioning

confidence: 99%

Artificial Intelligent Maximum Power Point Controller based Hybrid Photovoltaic/Battery System

Kadhim Mohaisen

2023

Int. j. electr. comput. eng. syst. (Online)

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Photovoltaic (PV) cells have non-linear properties influenced by environmental factors, including irradiation and temperature. As a result, a method known as maximum power point tracking (MPPT) was implemented to boost the PV cells' efficiency and make the most of the energy they could provide. The traditional perturb and observe (P&O) approach for determining the maximum power point tracking (MPPT) has various drawbacks, including poor steady-state performance, increased oscillation around the MPP point, and delayed reaction. As a result, this work aims to present a hybrid fuzzy logic (FL) and P&O MPPT approach to improve the PV system's performance coupled to the lithium battery storage system. Matlab/Simulink is used to bring the suggested technique to life, after which its efficacy is evaluated in the context of rapid changes in the irradiance level. According to the findings of the simulations, the suggested strategy has the potential to enhance the steady-state performance of PV systems in terms of oscillation and time response. Finally, the proposed results are compared with that obtained by the conventional P&O technique, and the stress of PV power is limited to ∆P=1kW and the overshoot power is limited to 5%.

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“…The user will depend on the solar system within the daylight hours only to apply its electrical requirements and will use the local electrical gride during the night hours. By using the solar system its electrical bill will decrease by the time [41][42][43][44].…”

Section: { }mentioning

confidence: 99%

Performance analysis of a Silicon PV module (100W) in outdoor conditions: Experimental and Simulation study

Ibrahim

Ramadan

Elsebaei

et al. 2021

Egyptian Journal of Solids

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In this paper, the incident solar radiation on horizontal and tilting surfaces was measured for a year using a pyranometer on the roof of Tanta University's Faculty of Science in Tanta city which is located at Latitude (30° 41`). The average daily global hourly solar radiation values on horizontal surfaces (H) and the global hourly solar radiation values on inclined surfaces (H t ) had been measured in the south direction of the sun for the meteorological variables. Miguel et al. correlation was used to determine hourly values of the beam and diffuse components of solar radiation (SR) from global solar irradiance. In order to attain the best solar module performance throughout the year, the solar energy devices must be tilted south with a tilting angle equal to Tanta city's latitude. The maximum value of H t was 1174.15 Wm -2 in April and the minimum value of H t was 816.11Wm -2 in October. The performance of 100 W solar silicon photovoltaic (PV) module in outdoor conditions can be studied by depending on the incident values of H and H t . The obtained results showed that the efficiencies of the 100 W solar PV module in winter, spring, summer and autumn were 4. 29, 3.78, 7.56 and 4.58 %, respectively. The maximum power point (P max ) was calculated in July and its value was 45.98 W at solar noon and the minimum power point (P min ) was calculated in October with a value equal to 18.56 W at solar noon. Also, the short circuit current (I sc ), the open-circuit voltage (V oc ), the series resistance (R s ), the shunt resistance (R sh ), and other electrical properties help to identify the performance of the solar PV module had been measured. The calculated optimum load resistance (R Lmp ) was 3.42, 3.88, 3.39, and 4.82 Ω, in winter, spring, summer and autumn, respectively. Also, a simulation of three cases of solar photovoltaic systems to generate the electric power for applying the domestic utilization of these systems had been determined. This simulation depends on an application called SolarCT to calculate the requirements of the photovoltaic systems in El-Gharbia province had been used.

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Modeling and Simulation of Photovoltaic Cell using Single Diode Solar Cell and Double Diode Solar Cell Model

Cited by 11 publications

References 7 publications

Nonlinear control of two-stage single-phase standalone photovoltaic system

Nonlinear control of two-stage single-phase standalone photovoltaic system

Artificial Intelligent Maximum Power Point Controller based Hybrid Photovoltaic/Battery System

Performance analysis of a Silicon PV module (100W) in outdoor conditions: Experimental and Simulation study

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