Modelling, simulation and analysis of optical time domain multiplexing transmission systems

Wietfeld, André Christoph.

January 1900

Erlangen, Nürnberg, Univ., Diss., 2004. / Computerdatei im Fernzugriff.

OTDM

Modelling, simulation and analysis of optical time domain multiplexing transmission systems

Wietfeld, André Christoph.

Unknown Date

Nürnberg, University, Diss., 2004--Erlangen. / Parallelt.: Modellierung, Simulation und Analyse optischer zeitbereichs-multiplexender Übertragungssysteme.

OTDM.

Taktrückgewinnung aus hochratigen optischen RZ-Datensignalen mittels differentieller optischer Signalverarbeitung /

Börner, Christof.

January 2008

Zugl.: Berlin, Techn. Universiẗat, Diss., 2008.

Vzájemná konverze OTDM a WDM systémů / The mutual conversion of the OTDM and WDM systems

Végh, Zoltán

January 2014

The aim of the diploma thesis is to analyze the WDM and OTDM optical telecommunication networks and the possibility of conversion between these two multiplexing methods. In the first chapter were mentioned the basics of optical communication. The next chapter describes the optical fiber. Specifically, their types, linear and nonlinear optical characteristics whitch are limiting transmission e.g. attenuation, dispersion, refraction, FWM, SPM and XPM. Followed by a general description of the multiplexing systems used in optics and individual elements used in various multiplexing systems. The last chapter was devoted to the design of the OTDM - WDM conversion model.

FWM; conversion; OTDM; WDM; konverze

Interferometric gates for all-optical signal processing

Schubert, Colja.

Unknown Date

Techn. University, Diss., 2004--Berlin.

Vzájemná konverze OTDM a WDM / OTDM to WDM conversion

Kupčiha, Lukáš

January 2013

The aim of this thesis was introducing the options of conversion between OTDM and WDM technologies. Since this issue is rather extensive, first of all the principle of optical transmission system is described. One chapter presents the effects influencing the optical transmissions. Material absorption, linear and nonlinear scattering and bending losses are mentioned in terms of fiber losses, followed by description of waveguide, chromatic and polarization-mode dispersion of optical fibers. Last part of the chapter presents nonlinear effects, including self-phase modulation, cross-phase modulation and four-wave mixing. The practical part of the thesis deals with multichannel systems. The principles of frequency, space a hybrid multiplexing are explained. Multichannel systems with optical time domain multiplexing and waveguide multiplexing are described in detail and compared. The elements of the transmission chain of multiplex, such as different types of lasers, detectors, modulators, optical amplifiers, splitters, couplers, MUX and DEMUX are discussed. The next part of the thesis was aimed at suggesting the model of mutual conversion between OTDM and WDM systems. First of all, the previously performed experiments concerning the conversion between OTDM and WTM were evaluated. Then the model of OTDM/WDM/OTDM conversion was designed, with explanation of its parts and their function. The general recommendations for practical implementation were are also included. Due to the limited amount of time reserved for access to the simulation program Optsim, the simulations were performed only for certain parts of the proposed conversion model. At the end of the thesis, the proposed model is evaluated.

Parametry sítí FTTx / Parameters of FTTx Networks

Münster, Petr

January 2014

This thesis examines parameters of FTTx networks and possibilities for increases in limit values of some selected parameters. The first and second chapters describe the necessary theory for understanding the outcomes presented in the rest part of the work. In the practical part of this thesis, analysis of the condition of the optical fibers in the Czech Republic is provided. Based on the results, the impact of the polarization mode dispersion on optical access networks was assessed. The next part of this thesis is focused on the active optical networks design, depending on the cost of implementation and operating costs. The main limiting parameters of the current passive optical networks are bandwidth and insertion loss of the optical distribution network. To increase the bandwidth a system based on optical time-division multiplexing with a bandwidth of 1.28 Tbit/s has been designed and created. By using polarization division multiplexing technique the system is also more tolerant to dispersions. In the last part of this thesis, a remote amplification system was verified by measurement and simulation. Based on the obtained results, a NG-PON2 network with a functional remote amplification system with a gain of more than 10 dB has been designed in the OptiSystem software.

A Comparison and Outline of Tolerances in Performing Optical Time Division Multiplexing using Electro-Absorption Modulators

Owsiak, Mark

18 May 2010

As high bandwidth applications continue to emerge, investigation in technologies that will increase transmission capacity become necessary. Of these technologies, Optical Time Division Multiplexing (OTDM) has been presented as a possible solution, supporting a next generation bit rate of 160 Gbit/s. To perform the demultiplexing task, the use of tandem electro-absorption modulators (EAMs) has been widely studied, and due to its benefits was chosen as the topology of this thesis. To create an effective model of an OTDM system, the vector based mathematical simulation tool MatLab is used. Care was taken to create an accurate representation of an OTDM system, including: the development of a realistic pulse shape, the development of a true pseudo-random bit sequence in all transmitted channels, the optimization of the gating function, and the representation of system penalty. While posing impressive bit rates, various sources of system performance degradation pose issues in an OTDM system, owning to its ultra-narrow pulse widths. The presence of dispersion, timing jitter, polarization mode dispersion, and nonlinear effects, can sufficiently degrade the quality of the received data. This thesis gives a clear guideline to the tolerance an OTDM system exhibits to each of the aforementioned sources of system penalty. The theory behind each impairment is thoroughly discussed and simulated using MatLab. From the simulated results, a finite degree of sensitivity to each source of system penalty is realized. These contributions are of particular importance when attempting to implement an OTDM system in either the laboratory, or the field. / Thesis (Master, Electrical & Computer Engineering) -- Queen's University, 2010-05-17 22:51:56.471

OTDM

electro-absorption modulators

system tolerances

optical time division multiplexing

160 Gbit/s

Components and Techniques for High-Speed Optical Communications

YANEZ, MAURICIO

05 July 2011

Electroabsorption modulators (EAMs) are fundamental components in optical communication systems. Their response is governed by a set of parameters inherent to their internal structure and by the external electrical components used to drive them. The first part of this thesis discusses a new method for the extraction of values for these parameters. The use of EAMs as both optical modulators and photodetectors is exploited for the purpose of parameter extraction. The proposed method allows the estimation of the parameters which govern the internal frequency response of EAMs without any knowledge of the characteristics of the electrical interconnect used to drive them. The procedure also removes the need for an accurately calibrated optical transmitter and receiver pair normally used during the characterization of optoelectronic components. Analytic description and experimental verification are presented. In the second part of this thesis, direct demultiplexing of a 10 Gbit/s channel from a 160 Gbit/s optical time division multiplexing (OTDM) signal using a single lumped, electrically driven EAM is experimentally presented for the first time. Direct demultiplexing is made possible by using an electrical driving signal for the EAM consisting of a sum of in-phase harmonics of the base channel rate. The use of a single EAM as an optical gate is quasi-analytically compared with the common approach of cascading two EAMs when performing 160 Gbit/s to 10 Gbit/s demultiplexing. The analysis reveals that the use of a single EAM is beneficial in terms of lower penalty with respect to degradations in the extinction ratio and width of the pulses used in the OTDM signal. The last part of this thesis introduces an electrical distributed oscillator which works in a regime of oscillation similar to that of mode locked laser (MLL) systems. The oscillator offers the flexibility of producing other waveforms not found in MLLs and has the potential to generate the required electrical driving signal for a single EAM OTDM demultiplexer. Other possible applications of the oscillator include the generation of short pulses for use in radar systems and wireless personal area networks. / Thesis (Ph.D, Electrical & Computer Engineering) -- Queen's University, 2011-06-30 14:41:42.625

Electroabsorption

Modulator

Optical Communications

Distributed Electronic Oscillator

OTDM Demultiplexing

High-Speed

Investigation of High-Nonlinearity Glass Fibers for Potential Applications in Ultrafast Nonlinear Fiber Devices

Kim, Jong-Kook

23 August 2005

Nonlinear fiber devices have been attracting considerable attention in recent years, due to their inherent ultrafast response time and potential applications in optical communication systems. They usually require long fibers to generate sufficient nonlinear phase shifts, since nonlinearities of conventional silica-core silica-clad fibers are too low. These long devices, however, cause the serious problems of pulse walk-off, pulse broadening, and polarization fluctuation which are major limiting factors for response time, switching bandwidth, and maximum transmittable bit-rate. Therefore, short device length is indispensable for achieving ultrafast switching and higher bit-rate data transmission. To shorten the required device length, fiber nonlinearities should be increased. In this dissertation, as a way of increasing fiber nonlinearities, high-nonlinearity materials of Litharge, Bismite, Tellurite, and Chalcogenide glasses have been considered. Although they have high nonlinearities, they also have high group-velocity dispersion and high losses deteriorating the performance of nonlinear fiber devices seriously. The aim of this work is to investigate how these high-nonlinearity glasses affect the performance of nonlinear fiber devices, taking into consideration both the advantages and disadvantages. To achieve it, the critical properties of various nonlinear fiber devices constructed with the different types of high-nonlinearity glasses and different types of fibers have been evaluated. It turned out that the required device lengths of nonlinear fiber devices constructed with the high-nonlinearity glasses were significantly reduced and high group-velocity dispersions and losses could not be major problems due to the extremely short device length. As a result, it would be possible to suppress the problems of pulse walk-off, pulse broadening, and polarization fluctuation in nonlinear fiber devices by introducing high-nonlinearity glasses, thus enabling ultrafast switching and higher bit-rate data transmission. Furthermore, in this dissertation, a new scheme of wavelength-division demultiplexing based on the optical Kerr effect has been proposed for the first time. The new scheme can turn the disadvantage of the extremely high group-velocity dispersion of high-nonlinearity glasses into an advantage of wavelength-division demultiplexing. Finally, it now would be possible to greatly increase maximum transmittable bit-rate in optical communication systems by simultaneously demultiplexing optical time-division-multiplexed signals and wavelength-division-multiplexed signals with an optical Kerr effect-based demultiplexer. / Ph. D.

Demultiplexer

Nonlinear Fiber Device

Fiber Nonlinearity

Optical Communication System

OTDM/WDM

High-Nonlinearity Glass