Performance Analysis of Optical Add Drop Multiplexer for Higher Bit Rate by Using Different Modulation Format Surinder Singh, Meenakshi, Veerpal Kaur.

Slides:

Advertisements

Similar presentations

NortelNortel's WDM System. Fiber-optic communications is based on the principle that light in a glass medium can carry more information over longer distances.

Advertisements

1 Fiber Optic Communications Systems From the movie Warriors of the Net Optical Time Division Multiplexing.

E-Photon Summer School 1 Optimization of Wavelength Interleaved Radio-over-Fiber Systems Tiago Silveira, António Teixeira, R. Nogueira, P. André, P. Monteiro,

Razali Ngah and Z Ghassemlooy Optical Communications Research Group

Optical Fiber Communications

E&CE 477 Photonic Communications Systems & Devices Winter 2006 Instructor: Hamed Majedi.

EE 230: Optical Fiber Communication Lecture 15 From the movie Warriors of the Net WDM Components.

Fiber-Optic Communications

1 Improving Chromatic Dispersion Tolerance in Long-Haul Fibre Links using Coherent OOFDM M. A. Jarajreh, Z. Ghassemlooy, and W. P. Ng Optical Communications.

Fiber-Optic Communications

Lightwave Communications Systems Research at the University of Kansas.

Fiber Bragg Gratings Ashwin Reddy M

Fiber Bragg Gratings.

FBG and Applications The Filter that Breaks Grading Broptics Communications Corp.

Photonic Devices - Couplers Optical fibre couplers A basic photonic device used to split or combine light to or from different fibres. A building block.

Optical Components Ajmal Muhammad, Robert Forchheimer

This teaching material is a part of e-Photon/ONe Master study in Optical Communications and Networks Course and module: Author(s): No part of this presentation.

Light Wave Systems Dr Manoj Kumar Professor & Head Department of ECE DAVIET,Jalandhar.

MODULATION AIDA ESMAEILIAN 1. MODULATION  Modulation: the process of converting digital data in electronic form to an optical signal that can be transmitted.

Dense Wavelength Division Multiplexing (DWDM) Technology

1 PHYSICAL IMPAIRMENTS Maruthy Mentireddi Raghu Kalyan Anna.

Intorduction to Lumentis

[1] National Institute of Science & Technology OPTICAL NETWORKING Swagat Kumar Samantaray EC Optical Networks(OPNET) Presented by Swagat Kumar.

1 Razali Ngah, and Zabih Ghassemlooy Optical Communication Research Group School of Engineering & Technology Northumbria University, United Kingdom http:

Chapter 10 Optical Communication Systems

November 18, Traffic Grooming in Optical WDM Networks Presented by : Md. Shamsul Wazed University of Windsor.

Design of Lightwave Communication Systems and Networks

CLIPPING DISTORTION IN LASER DIODE: MODEL, SIMULATIONS AND STATISTICS By: Omar Falou.

Optical Components/Devices

An Approach to Flatten the Gain of Fiber Raman Amplifiers with Multi- Pumping By: Dr. Surinder Singh Associate Professor Electronics & Communication Engg.

Investigations on PMD-induced penalties in 40 Gbps optical transmission link Irfan Ullah Department of Information and Communication Engineering Myongji.

Lecture Note on Optical Components. Optical Couplers Combines & splits signals Light couples from one waveguide to a closely placed waveguide because.

Optical telecommunication networks.  Introduction  Multiplexing  Optical Multiplexing  Components of Optical Mux  Application  Advantages  Shortcomings/Future.

Design of Lightwave Communication Systems and Networks

Photonic Components Rob Johnson Standards Engineering Manager 10th July 2002 Rob Johnson Standards Engineering Manager 10th July 2002.

Presented by, G.RajMohan I Year M-Tech. WHY WDM? Capacity upgrade of existing fiber networks (without adding fibers) Transparency: Each optical channel.

Date of download: 6/1/2016 Copyright © 2016 SPIE. All rights reserved. (a) DB encoder; (b) DBM scheme with precoder. Figure Legend: From: Optical transmission.

Subject Name: Optical Fiber Communication Subject Code: 10EC72 Prepared By: Sreepriya Kurup, Pallavi Adke, Sowmya L(TE) Department: Electronics and Communication.

Courtesy from Significant Technologies Sdn Bhd LIGHT SOURCE & POWER METER/ PASSIVE DEVICES.

Islam Galal Electrical Engineering Department

Veerpal Kaur, Surinder Singh

Discussion today Over the next two class periods we will be designing a ring resonator based 2-channel wavelength division multiplexing (WDM) optical link.

distributed versus discrete amplification

40Gb/s & 100Gb/s Transport in the WAN October 10, 2007

Optical Amplifier.

Design and Simulation of Photonic Devices and Circuits

Sandis Spolitis, Inna Kurbatska, Vjaceslavs Bobrovs

Performance Comparison of High Index Ring Defected Core PCF Air Sensor

Making Networks Light March 29, 2018 Charleston, South Carolina.

The Role of Light in High Speed Digital Design

Discussion today Over the next two class periods we will be designing a ring resonator based 2-channel wavelength division multiplexing (WDM) optical link.

By Engr: S Rehan ali shah

OPTICAL PACKET SWITCHING

Discussion today Using Lumerical INTERCONNECT we will simulate a full 50Gbps (25Gbps X 2) 2-channel WDM optical link. Today we will look at the following:

The University of Adelaide, School of Computer Science

DATA COMMUNICATION Lecture-29.

Problem We need more bandwidth

Leveraging Optical Technology in Future Bus-based Chip Multiprocessors

Optical Fiber Communications

Simultaneous Wavelength Conversion and

Overview of WDM Upgrade Capacity of fiber

Parallel Optical All Pass Filter Equalisers and Implementation by Wisit Loedhammacakra Supervision team Dr Wai Pang Ng Prof R. Cryan Prof. Z. Ghassemlooy.

Optical communications & networking - an Overview

TOAD Switch with Symmetric Switching Window

Fiber Optic Transmission

40Gb/s & 100Gb/s Transport in the WAN October 10, 2007

MCS Multicast Switch for Next Generation ROADM. Multicast optical switch （ MCS ） is based on PLC technology and MEMS technology ， which can route any.

Single Channel Coarse Wavelength Division Multiplexer (patent pending)

Performance Specifications

BASIC WDM OPTICAL NETWORK

Presentation transcript:

Performance Analysis of Optical Add Drop Multiplexer for Higher Bit Rate by Using Different Modulation Format Surinder Singh, Meenakshi, Veerpal Kaur Department of Electronics and Communication, Sant Longowal Institution of Engineering and Technology, Longowal-148106 (Punjab),India http://ece.sliet.ac.in/kaur.veerpal617@gmail.com/ INSERT LOGO HERE Abstract (b1).On-Off keying (b2) .DPSK keying. Block diagram of Simulation setup In this paper, OADM designed for ultra-high frequency to reduce the crosstalk. Performance analyzed in terms of adding and dropping channels in the network by using different modulation techniques.. Tx OADM Rx Output power meter Scope(added channel) CH-1 Scope( Dropped-channel)CH-1 Introduction . In optical WDM system, crosstalk degrades the system performance. Optical add-drop multiplexer (OADM) is four ports optical device which includes input port, output port, drop port, and add port. Various types of existed OADMs are based on fiber bragg grating, thin film interference filter, circulator and Mach-Zehnder interferometer [3,4]. Wang et al.[1] Mach-Zehnder interferometers (MZI) based OADM has excellent performance in terms of insertion loss, back- reflection and crosstalk. Mizuochi et al.[2] Mach-Zehnder interferometers with fiber bragg grating (MZI-FBG) based OADM has better performance and lower cost. Dewra et al. [5] designed an OADM by using different MZI techniques with 8 × 10 Gbps transmission rate in wavelength division multiplexing. In optical ring network, single optical fiber links all transmitter and receiver nodes and reduces system cost. The optical add drop multiplexer (OADM) supports the wavelength-reuse in optical ring networks and employ to enhance the transmission capacity.[6-8] In this paper, OADM designed for 16 channel with 10 Gbps and 40 Gbps transmission rate using different modulation techniques. Figure 3.(a)Quality factor verse no of channels Figure.3.(b)Quality factor verse no of channels Figure .1. Block diagram of simulation setup Result and Discussion System performance analyzed in tem of Q-factor, output power and eye-diagram by using different modulation format with different number of channel at input side Figure 3.(c) Output power verses no of channels Figure 3.(d) Output power verses no of channels (a)At 16×10 Gbps with different modulation formats Figure 2.FEM Mesh boundary condition. Figure 3.(a)Fundamental mode Figure 3.(b).Cladding mode Research Objectives Figure 3.(e)Eye diagram of dropped channel Figure 3.(f)Eye diagram of dropped channel Conclusion This simulation set up designed for 16 channels with different data rate by using optisystem software. To design OADM system for 16 channel with different modulation format To analysis the system performance in term of Q-factor, output power, eye diagram Simulation results show that RZ-Super Cosine modulation format has high Q-factor and RZ-Raised Cosine and RZ-Rectangular format has better output power by adding channel. Similarly, by added or dropped channel by using DPSK modulation technique has less degradation and less power penalty as compared to on-off keying modulation technique. Figure 2(a). Quality factor verses no of channels Figure 2(b). Output power verses no of channels A B Acknowledgement Simulation Setup and working principle The author would like to thanks AICTE, New Delhi for their funding to research project no.20/AICTE/RIFD/RPS (POLICY1)60/2013-14. Fig. 1 shows block diagram of WDM system with OADM placed between the transmitting and receiving end. 16 channels with different frequencies at 10 Gbps are fed to the input port. A channel with frequency 193.535 THz is dropped to the drop port and the same frequency is added to the add port. At transmitter side low pass Bessel filter with 50 GHz bandwidth used for generation of data source and output side a raised cosine optical filter with 40 GHz bandwidth used to detect the signal. OADM placed between transmitter and receiver end and Performance analyzed by varying the modulation formats such as RZ-Raised Cosine, RZ-Super Cosine, RZ-Soliton, RZ-Rectangular, NRZ-Rectangular and NRZ-Raised Cosine. Figure 2(d). Eye diagram of dropped channel using RZ-Raised Cosine modulation format Figure 2(e). Eye diagram of dropped channel using RZ- Soliton modulation format Figure 2(c). Eye diagram of dropped channel using RZ-Supper Cosine modulation format References Wang Bo, Wu Xiaoping, Wang Hui, Sun Chengcheng and Xie Shizhonge, “Fiber Gratings Based Optical Add/Drop Multiplexer with Low Interferometric Crosstalk”, International Conference on Communication Technology Proceedings, IEEE, .1-5, (1998). T. Mizuochi, T. Kitayama, K. Shimizu and K. Ito, “Interferometric Crosstalk-free Optical Add/Drop Multiplexer using Mach-Zehnder based fiber gratings”, IEEE Journal of Lightwave Technology 16, 265-276, (1998). P. S. Andre, A. Nolasco Pinto, J. L. Pinto, T. Almeida and M. Pousa, “Optical Add-Drop Multiplexer Based on Fiber Bragg Gratings for Dense Wavelength Division Multiplexing Networks”, Journal of optical communication 17, 333-339,(2002) M. Mahiuddin and M.S. Islam, “Performance Limitation in Fiber Bragg Grating Based Optical Add- Drop Multiplexer Due to Crosstalk”, ICCIT, 13th International Conference on Computer and Information Technology (ICCIT), IEEE, 170-174, (2010). Sanjeev Dewra, and R.S. Kaler, “Performance Analysis of Optical Network Based on Optical Add Drop Multiplexers with Different MZI Techniques”, Journal of Light & Optics 124, 347-351, (2013). Ahmed N.Z. Rashed, “Transmission Performance Evaluation of Optical Add-Drop Multiplexers (OADMs) in Optical Telecommunication Ring Networks”, American journal of Engineering and Technology Research 12, 12-21, (2012). S. Singh and R.S. Kaler, “Minimization of Cross Gain Saturation in Wavelength Division Multiplexing by Optimizing Differential Gain in Semiconductor Optical Amplifiers”, Fiber Integrated and Optics 25, 287-303, (2006). Rajneesh Randhawa, J. S. Sohal and R.S. Kaler, “Optimum Performance and Analysis of Ring Networks”, Optik 120, 934-940, (2009). ResearchPosters.co.za www.researchposters.co.za 219 Lower Main Rd Observatory, 7925 Cape Town Tel: 021-447-6783 Fax: 021-447-8475 Email: info@researchposters.co.za Figure 2(g.) Eye diagram of dropped channel using NRZ-RaisedCosine modulation format Figure 2(f). Eye diagram of dropped channel using NRZ-Rectangle modulation format Figure 4. The effective refractive index versus wavelength.