Maximum Power Point Tracking of Photovoltaic Module for Battery Charging Based on Modified Particle Swarm Optimization

Wahjono, Endro; Anggriawan, Dimas Okky; Sunarno, Epyk; Nugraha, Syechu Dwitya; Tjahjono, Anang

doi:10.15866/iremos.v10i1.11174

Cited by 5 publications

(3 citation statements)

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“…The circuit consists of two RF Schottky diodes to rectify the RF input and two capacitors to duplicate the RF peak value. The RF Schottky diode used is an HSMS2850 which is characterized by a very fast switching speed and zero biasing [14], [16], and [24]. Additionally, this circuit was tested in the frequency range mentioned above and the result indicates that the DC output voltage was approximately equal to 760 mV and the DC output power was equal to 2.74 mW at 400 MHz when 𝑅 𝐿 equal to 100 KΩ.…”

Section: Figure 5 Matching Circuit Representationmentioning

confidence: 99%

“…One of the constraints is the precise design of the energy conversion circuit, especially the matching circuit, [8]- [15]. The circular polarized patch antennas with harmonic rejection with sufficient matching techniques succeeded to collect RF energy at multiple frequencies within a broad frequency band from 350 MHz to 2500 MHz [16]- [23]. In these designs, it is observed that the effect of antenna position on the amount of energy harvested through the solar cells will have a minimum effect during the day.…”

Section: Introductionmentioning

confidence: 99%

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Integrated Solar Mesh Dipole Antenna Based Energy Harvesting System

Morsy

Saleh

2022

IEEE Access

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This paper presents a Sunlight-Radio Frequency (RF) energy harvesting system built on Solar Panel Mesh Dipole Antenna integration. The dipole antenna mesh is mounted on the surface of the solar panel at the separations between the cells. This configuration maximizes the absorption of both solar and RF energies. Further, the multiple mesh antennas are integrated vertically to increase the RF harvested power. Each antenna output is connected to a six-stage RF-Voltage Doubler Rectifier (RF-VDR) circuit to convert the RF signal to a direct current (DC) and added to the solar panel DC output. This paper involves the design analysis of the antenna parameters, the integration process, and the design of the RF matching circuit. Prototype tests show that the proposed mesh dipole antenna has 83% efficiency. This is better than earlier similar designs published. From previous designs, the measured RF to DC conversion efficiency (CE) of the VDR circuit was merely 62% when the RF input equals -14 dBm. Moreover, the solar panel efficiency has been enhanced by 41.3 % when the input RF power density equals 49.16 mW/m 2 . Finally, the results proved that the proposed solar antenna system achieves 28.5 % power CE and outperforms the others that use transparent patch antennas.

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Section: Figure 5 Matching Circuit Representationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Integrated Solar Mesh Dipole Antenna Based Energy Harvesting System

Morsy

Saleh

2022

IEEE Access

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“…Clearly, there is a need to overcome the multiple-peak characteristics with special MPPT technique that can track the GP (i.e., global maximum power point tracking or GMPPT). Several methods were developed to overcome multiple peak problem, such as particle swarm optimization (PSO) [10], [11], firefly algorithm (FA) [12], [13], Grey Wolf algorithm (GWA) [14], [15] etc. Although these methods were able to reach a global peak, it also caused new problems.…”

Section: Introductionmentioning

confidence: 99%

Global Maximum Power Point Tracking of PV Array Under Non-Uniform Irradiation Condition Using Adaptive Velocity Particle Swarm Optimization

Tjahjono¹,

Rofiq²,

Faiz³

et al. 2020

Int. J. Adv. Sci. Eng. Inf. Technol.

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Non-uniform irradiation condition (NUIC) is a condition of differences irradiation level received by each Photovoltaic (PV) on PV array. NUIC of PV array causes the emergence of several power peaks (consisting of several local peaks and one global peak) in the power-voltage (P-V) characteristic curve. This condition can cause several algorithms (hill-climbing / P&O, IC) that are unable to reach the global peak as they are trapped at a local peak. This paper proposes an Adaptive Velocity Particle Swarm Optimization (AVPSO) algorithm to search the global peaks/Global Maximum Power Point (GMPP) of PV arrays under NUIC. The proposed algorithm is a modification of the PSO algorithm. AVPSO algorithm able to adjust its own weight factor values and cognitive acceleration coefficients depend on the distance of the particle's position now with the global best position during the tracking process. Adaptive weight factors can reduce the level of power or voltage oscillation during the tracking process until convergent, while the cognitive acceleration coefficient can prevent particles trapped at the local peak. Thus, the proposed AVPSO algorithm can reach GMPP with faster tracking time and low oscillation rates. In addition, this paper proposed an algorithm that can work both in static and dynamic NUIC patterns; thus, the proposed algorithm can track again when there is a change in global peak value in the PV array.

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Design and Implementation Buck Converter for 540WP Solar Charger Using Fuzzy Logic Control

Sutedjo¹,

Qudsi²,

Ardianto³

et al. 2018

E3S Web Conf.

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This paper presents the details of design and implementation of DC-DC Buck converter as solar charger. This converter is designed for charging a battery with a capacity of 100 Ah (Ampere Hours) which has a charging voltage of 27.4 volts. The constant voltage method is selected on battery charging with the specified set point. To ensure the charging voltage is always on the set point, the duty cycle control of buck converter is set using Fuzzy Logic Control (FLC). The design implementation has been tested on PV (photovoltaic) with 540WP capacity. Based on the test results, this method is quite well implemented on the problem charger

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Maximum Power Point Tracking of Photovoltaic Module for Battery Charging Based on Modified Particle Swarm Optimization

Cited by 5 publications

References 0 publications

Integrated Solar Mesh Dipole Antenna Based Energy Harvesting System

Integrated Solar Mesh Dipole Antenna Based Energy Harvesting System

Global Maximum Power Point Tracking of PV Array Under Non-Uniform Irradiation Condition Using Adaptive Velocity Particle Swarm Optimization

Design and Implementation Buck Converter for 540WP Solar Charger Using Fuzzy Logic Control

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