Design a system to transfer alternating electric current using six channels of laser as an embedding and transmitting source

Design a system to transfer alternating electric current using six channels of laser as an embedding and transmitting source

This study introduces a novel approach to transmit alternating electric current through the air utilizing six optical channels LASER setup at 632 nm wavelength. Unlike traditional methods, this approach employs direct modulation within the laser to modulate the alternating current (AC) on an optical...

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Bibliographic Details
Main Authors: Edwar Basma Bashar, Ali Abdulkareem Kadhim, Edwar Balsam Bashar
Format: Article
Language:English
Published: De Gruyter 2025-03-01
Series:Open Engineering
Subjects:
laser power transmission
wireless power transfer
capacitive power transfer
inductive power transfer
microwave power transfer
electric vehicles
unmanned aerial vehicles
high-intensity laser power beam
photovoltaic
light dependent resistor
direct modulation
Online Access:https://doi.org/10.1515/eng-2024-0079
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Summary:This study introduces a novel approach to transmit alternating electric current through the air utilizing six optical channels LASER setup at 632 nm wavelength. Unlike traditional methods, this approach employs direct modulation within the laser to modulate the alternating current (AC) on an optical wave, enabling efficient transmission over a distance of 15 m. Experimental results reveal a measurable decrease in optical power at the utilized wavelength, providing insights into the system’s performance. Through practical analysis utilizing the EasyEDA tool, the various examined factors, including voltage and current in both transmitter and receiver circuits, contributed to the system’s design. Notably, the system is uniquely tailored for transmitting optical signals using single-phase AC, offering a cost-effective and straightforward circuit implementation with precise control. Despite encountered challenges such as coupling loss, this approach demonstrates promising benefits, underscoring its potential for applications demanding efficient and affordable optical signal transmission.
ISSN:2391-5439

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