The rectenna serves as a important device for achieving efficient long-distance wireless capacity transfer. This study contributes to the progress of rectenna technology by introducing a novel receiver configuration: the '3-point star.' In this creative design, a triangular part is seamlessly integrated with three parts of a square microstrip patch antenna, making a distinctive arithmetic. We systematically evaluate the depiction of this '3-point star' design distinguished with the conventional square microstrip patch, two together operating within the 2.4 GHz Wi-Fi band. The judgment encompasses an study of crucial performance limits, including gain, directivity, return misfortune, radiation pattern, and efficiency, all fake using Advanced Design System (ADS) program. Our investigation uncovers interesting insights attributed to the '3-point star' design. Notably, the clever incorporation of the trilateral element (placed side by side with the conventional square patch design) improves the antenna's gain, directivity, and return misfortune. This suggests a potential improvement in strength capture and signal propagation, alive for effective Wi-Fi power transfer systems. Additionally, we longer our scrutiny to the fixing component, wherein we design and simulate a greinacher strength-doubler featuring two HSMS2820 diodes. Spanning a range of recommendation power levels (10 dBm - 34 dBm) and friendly various load resistances (220 Ω, 380 Ω, and 810 Ω), our simulations unveil a maximum change efficiency of 88.02% at 28 dBm recommendation power for the 810 Ω load opposition. The distinctive geometry of the '3-point star' wire design introduces an creative dimension to wireless strength harvesting. Its potential to embellish critical acting metrics, as underscored by our verdicts, augments its importance in modern power transfer arrangements. Through this exploration, our study improves the understanding of rectenna technology, concreting the way for novel advancements in Wi-Fi power transfer requests.
Author(s) Details:
Olowoleni J. O.,
Department
of Electrical and Information Engineering (EIE), College of Engineering,
Covenant University, Ota, Nigeria.
Awosope
C. O. A.,
Kanni
Samah Consultants, Ilupeju, Lagos, Nigeria.
Adoghe A. U.,
Department of Electrical and Information Engineering (EIE), College
of Engineering, Covenant University, Ota, Nigeria.
Okoyeigbo Obinna,
Department of Electrical and Information Engineering (EIE), College
of Engineering, Covenant University, Ota, Nigeria.
Udochukwu Ebubechukwu Udo,
Department
of Electrical and Information Engineering (EIE), College of Engineering,
Covenant University, Ota, Nigeria.
Please see the link here: https://stm.bookpi.org/RADER-V8/article/view/11958
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