A Study of Efficient & Optimized Wave Network in Optical Fiber

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Published: Sep 1, 2022
Keywords:
efficient, optimized, wave network, optical fiber, dielectric strength, bandwidth, fiber optic communication, automated distribution systems, fiber optic cabling, wireless communication, broadcasting technologies, technological advancement, growing population, demand for BW, communication scientists, data transmission, mediums of communication, optical fiber fundamentals, electrical interference, shielding high-voltage communication devices, tap-resistance, short-distance connections, TOSLINK standard, audio via optical fiber

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Authors

Vaibhav Jain

Research Scholar, Shri Krishna University, Chhatarpur M.P.

Dr. Girish Padhan

Associate Professor, Shri Krishna University, Chhatarpur M.P.

Abstract

Due to its high dielectric strength and large bandwidth (BW), fiber optic communication hasfound primary application in the design and construction of automated distribution systems. This paperpresents a comprehensive analysis of optical fiber, dissecting its fundamentals, applications, and rootcauses in the development and deployment of fiber optic cabling. This study details the prerequisitesand draws comparisons to optical fiber methods. Wireless communication and broadcastingtechnologies have enabled the continuous global expansion of multinational corporations. In terms oftechnological advancement, fiber-optic communication stands out as the most recent and cutting-edgeoption available. Since then, the growing population has steadily increased the demand for BW incommunications. In order to motivate scientists working in communication to seek out new options, everlarge BWs were required. Researchers in the field of communication were scouring the globe for amedium of data transmission that was both wireless and minimal in loss, hoping to recover as muchinformation as quickly as possible at the expense of quality. This unceasing exploration of potentialtransmission mediums ultimately resulted in the advent of optical fiber. First, let's take a short glanceback at what's been said. Since the signals on the several cables don't mix, there's no chance for anybackground noise to be gathered. Electrical interference does not affect fibers. Due to the electric natureof unarmored fiber cables, they can effectively shield high-voltage communication devices, such asthose found in power plants or in areas where metal communications are vulnerable to lightning. It canalso be employed in environments where there is a risk of explosive gases without the need for any kindof ignition source. The tap-resistance of these concentrated dual-core fibers is similar to that of electricalconnections, although it involves a more involved process (in this case, fiber tapping). Fibers arecommonly used for short-distance connections between devices. Since most modern HDTVs provide anoptical digital audio Input. Utilizing the TOSLINK standard, audio can be sent via optical fiber.

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Article Details

Issue

Vol. 19 No. 3 (2022): Journal of Advances in Science and Technology (JAST)

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