Modeling of Capacity Enhancement of Heterogeneous Few Mode Multi-Core Fiber: A Review

Anshu*, Sharad Mohan Shrivastava**, Vikas Sahu***, Aakash Joshi****, Anamika Bhadra*****, Anjali S. Sanghvi******, Nirmala Tirkey*******
*,****-******* PG Scholar, Department of Electronics & Telecommunication Engineering, Shri Shankaracharya Technical Campus, Bhilai, India.
**,*** Assistant Professor, Department of Electronics & Telecommunication Engineering, Shri Shankaracharya Technical Campus, Bhilai, India.
Periodicity:October - December'2016
DOI : https://doi.org/10.26634/jdp.4.4.8315

Abstract

This paper aims to make understand the fundamentals and recent advancement in Multi-core Fiber Technology using Space Division Multiplexing. Few Mode Multi-core Fiber (FM-MCF) that enable Space Division Multiplexing (SDM) have greater potential to improve the transmission capacity compared to Single Spatial Mode Fiber (SSMF). The concept of Heterogeneous Few Mode Multi-core Fibers has paved its way in optical communication system by replacing Homogeneous Few Mode Multi-core Fibers which were previously opted. The uncoupled Multi-core Fibers (MCFs) which can utilize multiple cores are arranged in a fiber as spatial transmission channels and then is used for the SDM transmission. Design of 36 core and 3 mode is also demonstrated. Measurement of Inter-core XT for different bending radius is studied. And to give the readers a glimpse of recent development in Multi-core Fiber (MCF) technology, some noticeable research papers have also been discussed. System implementations based on MCF are mentioned along with future research directions.

Keywords

SDM (Space Division Multiplexing), MCF (Multi-Core Fiber), FMF (Few Mode Fiber), DMD (Differential Mode Delay), (IC-XT) Inter-Core Crosstalk

How to Cite this Article?

Anshu, Shrivastava, S, M, Sahu, V, Joshi, A, Bhadra, A, Sanghvi, A. S, and Tirkey, N (2016). Modeling Of Capacity Enhancement of Heterogeneous Few Mode Multi-Core Fiber: A Review. i-manager’s Journal on Digital Signal Processing, 4(4), 35-46. https://doi.org/10.26634/jdp.4.4.8315

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