Decision point steering in optical fibre communication systems

Sherif, M.

January 1989

No description available.

621.382

Optical transmission systems

Polarisation mode dispersion compensation

Watley, Daniel Andrew

January 2000

No description available.

621.319

Optical transmission

The influence of the dispersionmap on optical OFDM transmissions

Forozesh, Kamyar

January 2010

<p>Fiber-optic networks are an integral part of todays digital communication system. In these networks, distances of typically 400 km to 6000 km are linked together, and information is transfered at extremely high data rates. As the demands for capacity increases, finding new methods for cost effective long-haul transmission systems that can be used to increase the capacity becomes of high interest. In this work Orthogonal Frequency Division Multiplexing (OFDM), which is a standard digital modulation format in many wireless communication systems, for instance the IEEE 802.11n, is adapted to the optical domain and used for data transmission. The advantage of OFDM in the optical domain is that it transforms a high data rate stream into many simultaneously low bit rate streams that are efficiently frequency multiplexed. By doing so high spectral efficiency is achieved and many of the impairments encountered in high data rate transmissions are avoided. The disadvantage is however, that OFDM has inherently a high peak-to-average power ratio. As a result, OFDM suffers from nonlinearities occurring along the transmission line. The low nonlinear tolerance of OFDM in fiber optic applications restricts the feasible transmission distance. The goal of this work is to assess the suitability of OFDM in fiber-optic communications</p>

OFDM

fiber

optic

dispersion

optical transmission

The influence of the dispersionmap on optical OFDM transmissions

Forozesh, Kamyar

January 2010

Fiber-optic networks are an integral part of todays digital communication system. In these networks, distances of typically 400 km to 6000 km are linked together, and information is transfered at extremely high data rates. As the demands for capacity increases, finding new methods for cost effective long-haul transmission systems that can be used to increase the capacity becomes of high interest. In this work Orthogonal Frequency Division Multiplexing (OFDM), which is a standard digital modulation format in many wireless communication systems, for instance the IEEE 802.11n, is adapted to the optical domain and used for data transmission. The advantage of OFDM in the optical domain is that it transforms a high data rate stream into many simultaneously low bit rate streams that are efficiently frequency multiplexed. By doing so high spectral efficiency is achieved and many of the impairments encountered in high data rate transmissions are avoided. The disadvantage is however, that OFDM has inherently a high peak-to-average power ratio. As a result, OFDM suffers from nonlinearities occurring along the transmission line. The low nonlinear tolerance of OFDM in fiber optic applications restricts the feasible transmission distance. The goal of this work is to assess the suitability of OFDM in fiber-optic communications

OFDM

fiber

optic

dispersion

optical transmission

Continuous phase modulation for high speed fiber-optic links

Detwiler, Thomas Frederick

10 November 2011

Fiber-optic networks are continually evolving to accommodate the ever increasing data rates demanded by modern applications and devices. The current state-of-the art systems are being deployed with 100 Gb/s rates per wavelength while maintaining the 50 GHz channel spacing established for 10 Gb/s dense wavelength division multiplexed (DWDM) systems. Phase modulation formats (in particular quadrature phase shift keying - QPSK) are necessary to meet the spectral efficiency (SE) requirements of the application. The main challenge for phase modulated optical systems is fiber nonlinearities, where changes in intensity of the combined optical signal result in changes to the fiber's refractive index. Limiting launch power is the primary means to avoid dramatic intensity fluctuations, a strategy which in turn limits the available signal-to-noise ratio (SNR) within the channel. Continuous phase modulation (CPM) is a format in which data is encoded in the phase, while the amplitude is constant throughout all transmission (even during transitions between symbols). With the goal of reducing the impact of nonlinearities, the purpose of this research was to identify a set of CPM signals best suited for high speed fiber-optic transmission, and quantify their performance against other formats. The secondary goal was to identify techniques appropriate for demodulation of high speed fiber-optic systems and implement them for simulation and experimental research. CPM encompasses a number of variable parameters that combine to form an infinite number of unique schemes, each of which is characterized by its own SE, minimum distance, and implementation complexity. A method for computing minimum distance of DWDM-filtered CPM formats is presented and utilized to narrow down to a range of candidate schemes. A novel transmitter design is presented for CPM signal generation, as well as a number of novel reception techniques to achieve proper demodulation of the CPM signal from the coherent optical receiver. Using these methods, the identified range of candidate schemes was compared in simulation to the conventional QPSK format, showing that some modest gain can be expected from CPM. Through these and other simulations, it is revealed that fiber nonlinearities depend on the aggregate sum of all wavelengths rather than the imposition of each separate carrier on its neighbors. Therefore the constant envelope of CPM does not directly impact the nonlinearities since multiple carriers will photonically interfere and result in intensity fluctuations regardless of modulation format. Additionally, dispersive effects in fiber decompose the underlying channels so that the intensity throughout propagation is nearly Gaussian distributed, regardless of format. The benefits gained from CPM are thus limited to schemes that attain a higher minimum distance than alternative formats (in the given channel passband), and for optically compensated links in which low dispersion is maintained throughout the fiber link.

CPM

Coherent optical transmission

Telecommunication systems

Fiber optics

Modulation (Electronics)

Extraordinary Optical Transmission in Aligned Carbon Nanotube Devices at Terahertz Frequencies.

Almousa, Shaikhah F.

09 May 2017

No description available.

Physics

Terahertz

Extraordinary optical transmission

Surface plasmon polariton

Carbon nanotube

Geração e propagação de ondas de superfície em fendas metálicas de dimensões menores que o comprimento de onda / Generation and propagation of surface waves in metallic slits of dimensions smaller than the wavelength

Silva, Otavio de Brito

26 October 2012

Neste trabalho apresentamos um estudo sistemático da transmissão da radiação eletromagnética em um conjunto de fendas metálicas individuais depositadas em substratos de vidro BK7 com larguras abaixo do comprimento de onda da luz incidente. As fendas foram obtidas através da evaporação térmica de prata e ouro sobre um substrato dielétrico (vidro BK7). A fabricação das fendas foi feita de forma direta através de um equipamento de feixe de íons de Gálio (FEI Quanta 3D). A transmissão óptica das fendas foi estudada com radiação laser para os comprimentos de onda de 488 nm e 632.8 nm. Observouse uma oscilação de intensidade na transmissão devido ao efeito de interferência dos surface plasmon polariton (SPP) gerados na superfície metálica como função da espessura do filme metálico. Os resultados experimentais obtidos foram confrontados com simulações computacionais, via método de elementos finitos, a partir das quais pode se compreender os mecanismos de propagação da radiação na estrutura em questão, e compará-los com detalhes da fabricação de fendas. Procedimento similar foi realizado ao variar a largura das mesmas. Também foi feita a análise da transmissão óptica em fendas fabricadas em filmes constituídos por camadas alternadas de prata e ouro, a fim de comparar como tal mudança na configuração da estrutura afeta os resultados anteriores. O trabalho serviu para mostrar que as dimensões dos filmes metálicos, assim como das fendas, apresentavam grande influência nas propriedades de transmissão e, além do que foi possível conferir diversos conceitos básicos da teoria eletromagnética num sistema relativamente simples. A compreensão dessas propriedades é fundamental para o desenvolvimento de futuros dispositivos que utilizam efeitos plasmônicos. / This work presents a systematic study of the transmission of electromagnetic radiation on a set of single metallic slits metallic with widths below the wavelength of incident light, deposited on BK7 glass substrates. The slits were obtained by thermal evaporation of silver and gold on a dielectric (BK7 glass). The fabrication of the slits was performed directly through a gallium ion beam equipment (FEI Quanta 3D). The optical transmission of the slits was studied by laser radiation for the wavelengths of 488 nm and 632.8 nm. An oscillation in the transmission intensity was observed due to the interference effect of the surface plasmon polariton (SPP) generated on the metallic surface as a function of the metal film thickness. The experimental results were compared with computational simulations, via finite element method, in order to comprehend the mechanisms of radiation propagation in the structure and compare them with details of slits fabrication. A similar procedure was performed by varying the width of the slits. An analagous analysis of the optical transmission in slits fabricated in films consisting of alternating layers of silver and gold was performed in order to compare how this change in structure configuration affects the previous results. The work served to show that the dimensions of the metal films, as well as of the slits, have a significant influence on the properties of transmission, and, moreover it was possible to confer different basic concepts of electromagnetic theory in a relatively simple system. Understanding these properties is fundamental for the development of future devices that make use of plasmonics effects.

Fenda

Filme metálico

Metallic film

Nanofabricação

Nanofabrication

Optical transmission

Plasmon de superfície

Slit

Surface plasmon

Transmissão óptica

A Novel THz Photoconductive Source and Waveguide Based on One-dimensional Nano-grating

Jafarlou, Saman

January 2013

A terahertz photoconductive source structure with nano-grating electrodes is proposed. The resonance modes of the one-dimensional nano-grating and their affect the optical power absorption are studied. In addition, an approach for optimal design of the grating to maximize the photocurrent for different proposed DC biases, is presented. The dependence of the photocurrent on physical parameters of photomixer are analyzed. A fast analysis method for a new terahertz waveguide for photo-mixing is proposed. The wave-guiding mixer structure is a modified parallel plate waveguide (PPWG) in which the top plate is replaced by a periodic array of sub-wavelength nano-slits. The substrate of the PPWG is made of a fast photoconductive material in which laser photomixing/absorption occurs. The characteristic equation of the modified PPWG when used as a THz waveguide is derived analytically, and its guided modes are studied in details over THz range of frequencies. The accuracy of the analytical results are verified by comparison with full-wave numerical simulations. The criteria for choosing the suitable mode for photomixing application are also discussed. Finally, based on dyadic Green’s function representation, a systematic approach is provided for calculating the amplitude of the guided modes that are excited by an arbitrary photocurrent.

terahertz

photomixer

Plasmonic

Nano-grating

Extraordinary optical transmission

waveguide

Electrical and Computer Engineering

Nanofabrication and its application in plasmonic chemical and bio-sensors

Zhang, Jian

January 2014

This thesis is focused on nanofabrication and its application in plasmonic chemical and bio- sensors. The contribution thus is the development of novel nanofabrication techniques and nano- structures for the sensors based on surface plasmon (SP). Part I (Chapter 1-3) is about novel nanofabrication techniques, especially nanoimprint lithography (NIL) and electron beam lithography (EBL). For NIL, the four major aspects of NIL were discussed, including the resist, mold, imprint process and equipment for NIL. Combined with NIL and soft lithography, hybrid nanoimprint-soft lithography was investigated. To overcome the difficulty of mold fabrication, a more robust solution of mold fabrication through a sacrificial poly(dimethyl glutarimide) (PMGI) master mold was designed in this work. Based on this method, the mold was fabricated without structure distortion, and pattern replication with sub-10 nm resolution was demonstrated. For EBL, several aspects were discussed to improve the performance of EBL, including the resist, development, and exposure condition. The charging effect to the pattern distortion was studied systemically for the electron beam exposure in large area with high current (>nA). Tilted periodic nanostructure was achieved by electron beam scanning on tilted sample with dynamic focus mode. EBL on irregular surface was realized by the exposure on evaporated polystyrene. Part II (Chapter 4-6) is the application in surface plasmonic chemical and bio-sensors. The first type of sensors is surface enhanced Raman scattering (SERS) sensor based on localized SP. Bowtie-shape nano-antenna structures of sub-10 nm gap were fabricated with the breakthrough of EBL resolution to 3 nm by exposing resist on Si3N4 membrane. By controlling the gap size during lithography, the surface plasmon enhancement was tuned accurately. High sensitivity of Au bowties antenna with sub-10 nm gap was achieved at low concentration of the target molecule (10^-7 mM, 1,2-di(4-pyridyl)ethylene in ethanol solution) and high enhancement of 10^7 resulting from the corresponding bowtie structure. The second type of sensors is extraordinary optical transmission (EOT) sensor based on propagating SP. The process of double liftoff was developed for the fabrication of nano-hole arrays on 100 nm-thick Au film utilizing EBL. This technique is versatile for the fabrication of many kinds of high-aspect-ratio noble metal structures. Additionally, annealing method was employed in this work to improve the smoothness of Au film. It was found that the RMS roughness of the deposited film was reduced by 72 % and the sensitivity was increased by 32 nm/RIU as a result of annealing. It was also found that the optical transmission intensity of the annealed NHA of similar hole diameter was increased more than twice which is due to the smaller absorption/scattering of the incident light and surface waves from the Au film surface. Besides the double liftoff process, several techniques were developed for EOT structures, including electroplating, imprint method, and deposition on membrane.

nanofabrication

surface plasmon

sensor

surface enhanced Raman scattering

extraordinary optical transmission

A Novel THz Photoconductive Source and Waveguide Based on One-dimensional Nano-grating

Jafarlou, Saman

January 2013

A terahertz photoconductive source structure with nano-grating electrodes is proposed. The resonance modes of the one-dimensional nano-grating and their affect the optical power absorption are studied. In addition, an approach for optimal design of the grating to maximize the photocurrent for different proposed DC biases, is presented. The dependence of the photocurrent on physical parameters of photomixer are analyzed. A fast analysis method for a new terahertz waveguide for photo-mixing is proposed. The wave-guiding mixer structure is a modified parallel plate waveguide (PPWG) in which the top plate is replaced by a periodic array of sub-wavelength nano-slits. The substrate of the PPWG is made of a fast photoconductive material in which laser photomixing/absorption occurs. The characteristic equation of the modified PPWG when used as a THz waveguide is derived analytically, and its guided modes are studied in details over THz range of frequencies. The accuracy of the analytical results are verified by comparison with full-wave numerical simulations. The criteria for choosing the suitable mode for photomixing application are also discussed. Finally, based on dyadic Green’s function representation, a systematic approach is provided for calculating the amplitude of the guided modes that are excited by an arbitrary photocurrent.

terahertz

photomixer

Plasmonic

Nano-grating

Extraordinary optical transmission

waveguide

Electrical and Computer Engineering