Impact of physical layer impairments on multi-degree CDC ROADM-based optical networks

Nowadays, optical network nodes are usually based on reconfigurable optical add/drop multiplexers (ROADMs). Due to exponential growth of internet data traffic, ROADMs have evolved to become more flexible, with multi-degree and their add/drop structures are now more complex with enhanced features, such as colorless, directionless and contentionless (CDC). In this work, the impact of in-band crosstalk, optical filtering and amplified spontaneous emission noise on the performance of an optical network based on multi-degree CDC ROADMs is studied considering 100-Gb/s polarisation division multiplexing quadrature phase-shift keying signals for the fixed grid. We show that, an optical signal can pass through a cascade of 19 CDC ROADMs, based on a route and select architecture with 16-degree, until an optical signal-to-noise ratio (OSNR) penalty of 1 dB due to in-band crosstalk is reached. We also show that the ASE noise addition, due to the increase of the number of CDC ROADMs, is more harmful in terms of OSNR penalty than in-band crosstalk.info:eu-repo/semantics/acceptedVersio

Physical layer impairments in cascaded multi-degree CDC ROADMs with NRZ and nyquist pulse shaped signals

Nowadays, reconfigurable optical add/drop multiplexers (ROADMs) are mainly based on broadcast and select (B&S) and route and select (R&S) architectures. Moreover, the most used components to implement the colorless, directionless and contentionless (CDC) ROADM add/drop structures are the multicast switches (MCSs) and the wavelength selective switches (WSSs). In-band crosstalk, amplified spontaneous emission (ASE) noise accumulation and optical filtering are physical layer impairments (PLIs) that become more enhanced in a CDC ROADM cascade. In this work, we investigate the impact of these PLIs in a cascade of CDC ROADMs based on both B&S and R&S architectures, with MCSs and WSSs-based add/drop structures and for nonreturn-to-zero (NRZ) and Nyquist pulse shaped signals. We show that the optical filtering impairment is more limiting for a R&S architecture. We also show that the ASE noise accumulation after 32 cascaded ROADMs leads to a 10 dB optical signal-to-noise ratio (OSNR) penalty. Finally, we conclude that the in-band crosstalk introduced in CDC ROADMs based on B&S is more harmful than with a R&S architecture. An OSNR penalty of 1 dB due to in-band crosstalk, is reached after 13 and 24 cascaded 16-degree CDC ROADMs for, respectively, NRZ and Nyquist pulse shaped signals.info:eu-repo/semantics/acceptedVersio

Impact of in-band crosstalk in an optical network based on multi-degree CDC ROADMs

he most common optical networks nodes are known as reconfigurable optical add/drop multiplexers (ROADMs). The architecture and components of these nodes have evolved over the time to become more flexible and dynamic. Particularly, the wavelength add/drop structures of these nodes have become more complex and with new features such as colorless, directionless and contentionless (CDC). One of the main limitations of the optical networks physical layer, the in-band crosstalk, is mainly due to the imperfect isolation of the components inside these nodes. This crosstalk is enhanced, when an optical signal traverses a cascade of ROADM nodes. In this work, the impact of in-band crosstalk, optical filtering and amplified spontaneous emission (ASE) noise on the performance of an optical communication network based on a cascade of CDC ROADMs with coherent detection and the modulation format quadrature phase-shift keying with polarization-division multiplexing (PDM-QPSK) at 100-Gb/s is studied through Monte-Carlo simulation. Two architectures, broadcast and select (B&S) and route and select (R&S), and two possible implementations for the add/drop structures, the multicast switches (MCSs) and the wavelength selective switches (WSSs), were considered. The degradation of the optical communication network performance due to in-band crosstalk is assessed through the optical-signal-to-noise ratio (OSNR) calculation. In particular, an OSNR penalty of 1 dB due to in-band crosstalk is observed when the signal passes through a cascade of 19 CDC ROADMs with 16-degree, based on a R&S architecture and with add/drop structures implemented with WSSsOs nós das redes de comunicação ótica mais comuns são os multiplexadores óticos de inserção/extração reconfiguráveis (ROADMs – acrónimo anglo-saxónico de reconfigurable optical add/drop multiplexers). A arquitetura e componentes destes nós têm evoluído ao longo do tempo no sentido de se tornarem mais flexíveis e dinâmicos. Em particular, as estruturas de adição/extração destes nós, tornaram-se mais complexas e detêm novas características que oferecem as funcionalidades CDC (acrónimo anglo- -saxónico de colorless, directionless e contentionless). Uma das principais limitações do nível físico das redes óticas, o crosstalk homódino, deve-se principalmente ao isolamento imperfeito dos componentes presentes dentro destes nós. Este tipo de crosstalk tem um impacto ainda mais significativo quando o sinal ótico atravessa uma cadeia de nós baseados em ROADMs. Nesta dissertação, o impacto do crosstalk homódino, filtragem ótica e ruído ASE (acrónimo anglo-saxónico de amplified spontaneous emission) no desempenho de uma rede de comunicação ótica baseada numa cadeia de CDC ROADMs com deteção coerente e usando o formato de modulação PDM-QPSK (acrónimo anglo-saxónico de polarization-division multiplexing quadrature phase-shift keying) a um ritmo binário de 100-Gb/s é investigado através de simulação Monte-Carlo. Consideraram-se duas arquiteturas, B&S e R&S (acrónimos anglo-saxónicos para broadcast and select e route and select), e duas possíveis implementações para a estruturas de inserção/extração, os MCSs e os WSSs (acrónimos anglo-saxónicos de multicast switches e wavelengh selective switches). A degradação do desempenho da rede ótica devido ao crosstalk homódino foi obtida através do cálculo da relação sinal-ruído ótica. Em particular, obteve-se uma penalidade de 1 dB para esta relação devido ao crosstalk homódino quando o sinal percorre uma cadeia de 19 CDC ROADMs com grau 16, uma arquitetura R&S e estruturas de inserção/extração baseadas em WSSs

Impact of physical layer impairments on large ROADM architectures

Most of today’s optical networks, use reconfigurable optical add/drop multiplexers (ROADMs) as nodes. To become more dynamic and flexible, these nodes architectures evolved over the years. The colorless, directionless and contentionless functionalities are now standard, however, current architectures have poor scalability due to limitations on wavelength selective switches dimensions. Hence, due to constant increase in data traffic, current architectures might become a bottleneck to manufacture future large-scale ROADMs. In this work, the hardware cost and in-band crosstalk generation inside different large-scale ROADM architectures, is compared with conventional architectures. Moreover, an analysis of optical filtering, amplified spontaneous emission (ASE) noise and in-band crosstalk impact in the performance of an optical network, with nodes based on the most promising large-scale architecture, the interconnected A architecture, is performed. This performance is assessed through Monte-Carlo simulation with 16 point quadrature amplitude modulation with polarization-division multiplexing (PDM-16QAM) and PDM- 32QAM signals with 200 Gb/s and 250 Gb/s, respectively. Two architectures are considered for the interconnected A express structure, Broadcast and Select (B&S) and Route and Select (R&S). For the add/drop structure, a bank-based structure is considered. The maximum number of cascaded ROADMs, considering all the studied impairments, is 5 and 7 nodes for a 32 GBaud 16QAM signal, respectively, for B&S and R&S architectures. A 32QAM signal reaches 3 and 4 nodes, respectively, for B&S and R&S architectures. The main penalty in transmission is the ASE noise generated by optical amplifiers throughout the network, having the in-band crosstalk and optical filtering penalties a lower contribution.A maioria das redes óticas são atualmente compostas por multiplexadores óticos de inserção/extração reconfiguráveis (ROADMs, em inglês) nos nós, cuja arquitetura tem evoluído para se tornarem mais dinâmicos e flexíveis. As funcionalidades colorless, directionless e contentionless estão hoje normalizadas, no entanto, as arquiteturas atuais tornam-se pouco escaláveis para ROADMs de elevada dimensão, devido a limitações nos comutadores seletivos no comprimento-de-onda. Neste trabalho, a comparação entre os custos associados e a geração de crosstalk homódino em diferentes arquiteturas propostas para ROADMs de elevada dimensão e as arquitecturas tradicionais é efetuada. É também analisado o impacto da filtragem ótica, ruído de emissão espontânea amplificada (ASE, em inglês) e crosstalk homódino no desempenho de uma rede com nós baseados na arquitetura denominada "Interconnected A". A avaliação é feita através de simulação Monte-Carlo com sinais multiplexados por divisão na polarização e modulação de amplitude em quadratura, PDM-16QAM e PDM-32QAM a 200 Gb/s e 250 Gb/s, respetivamente. Foram consideradas duas configurações para os ROADMs estudados, Broadcast and Select e Route and Select (B&S e R&S, em inglês) e uma estrutura de inserção/extração denominada "bank-based". Quando considerados todos os efeitos, o alcance máximo da rede é de 4 e 7 nós para um sinal 16QAM, respetivamente, para configurações B&S e R&S. Para um sinal 32QAM, é de 3 e 4 nós, respetivamente, para configurações B&S e R&S. A principal penalidade na transmissão deve-se ao ruído ASE gerado nos amplificadores óticos ao longo da rede, tendo a penalidade devido ao crosstalk homódino e a filtragem ótica uma menor contribuição

Programmable DSP-enabled multi-adaptive optical transceivers based on OFDM technology for software defined networks

The dynamic behavior of the traffic demand, due to the advent of technologies such as cloud services or Internet of Things (IoT), is increasing. In fact, heterogeneous connections with different characteristics (bandwidth or bit rate) are expected that coexist in the optical networks. In this respect, an evolution towards Elastic Optical Networks (EONs) has emerged as a cost-effective, flexible and dynamic solution, to face the new claims. The main idea is the efficient utilization of the optical spectrum by combining flexible transceivers, flexi-grid and flexible optical switching. Including the principles of Software Defined Network (SDN) paradigm further flexibility and adaptability can be achieved. The Sliceable Bandwidth Variable Transceiver (S-BVT), as a key element in EONs, provides flexibility and adaptability to the optical networks. It is able to dynamically tune the optical bandwidth or bit rate changing parameters such as the modulation format, bandwidth, among others, to find a trade-off between transmission reach and spectral efficiency, serving multiples destinations. The combination of programmable Digital Signal Processing (DSP) modules with advanced transmission techniques based on Orthogonal Frequency Division Multiplexing (OFDM) technology using Direct Detection (DD) or COherent (CO) detection are proposed to be implemented at the S-BVT making it suitable for elastic optical metro/regional networks. Furthermore, the envisioned migration from fixed-grid to flexi-grid, can benefit from the use of S-BVTs since they are able to generate or receive multiple channels and slicing the aggregated flow into multiples flows with different capacities and destinations. We propose the use of S-BVTs based on multi-band OFDM systems. In particular, we focus on the theoretical model of an advanced transmission technique based on OFDM technology with DD. Then we evaluate the system for a realistic optical metro network. In the context of flexi-grid optical metro/regional networks, as well as the sliceability of the channels, the reduction of channel width for low bit rate connections can be envisioned. It involves that the signal traverses several nodes with the corresponding filtering elements, causing a substantially decrease and distortion of the signal bandwidth. This phenomenon known as filter narrowing effect has been also studied in this thesis, by simulations and experimentally for an adaptive cost-effective OFDM system using DD and for a standard OOK system. Apart from adaptive, flexible and programmable transceivers, metro optical networks have to be equipped with flexible optical switching systems at the node level. In this respect, we propose the adoption of adaptive S-BVTs based on advanced transmission techniques using DD with Discrete MultiTone (DMT) modulation and adaptive capabilities in combination with Semiconductor Optical Amplier (SOA)-based switching nodes. SOAs can be conveniently used for optical switching in metro networks because of their low cost or low power consumption, among others relevant characteristics. The system has been experimentally analyzed with and without considering filtering elements. Thanks to the combination of adaptive DMT modulation and SOA-based switching nodes, impairments due to the fiber links and the filtering elements can be compensated. Finally, to enhance the tranmission distance and data rate, we propose the combination of multidimensional constellations implemented at the DSP modules of the S-BVT with CO detection and OFDM technology. Thus, the deployed infrastructure is more efficiently exploited since the quadrature and the polarization dimensions are used to transmit the signal. In particular, we focus on CO-OFDM systems using Dual Polarization Quadrature Phase Shift Keying (DPQPSK) constellation transmitting the signal over the time and the polarization dimensions in the optical domain.El comportamiento dinámico de la demanda de tráfico, debido a la llegada de tecnologías como los servicios en la nube o el Internet of Things (IoT), está aumentando. De hecho, se espera que coexistan en las redes ópticas conexiones heterogéneas con características diferentes, tales como ancho de banda o tasa de bits. Para hacer frente a estas demandas es crucial una evolución de las redes ópticas. En este sentido, las Elastic Optical Networks (EONs) emergen como una solución rentable, flexible y dinámica. La idea principal se basa en la utilización eficiente del espectro óptico mediante la combinación de transceptores flexibles, redes flexibles y conmutación óptica flexible. Una mayor flexibilidad y adaptabilidad se puede conseguir incluyendo los principios del paradigma conocido como Software Defined Network (SDN). La adopción de la arquitectura SDN implica la separación del plano de control y de datos, permitiendo la programabilidad dinámica de la red. Un elemento clave en las EONs es el Sliceable Bandwidth Variable Transceiver (SBVT), ya que provee de flexibilidad y adaptabilidad a las redes ópticas. El S-BVT es capaz de cambiar el ancho de banda o la tasa de bits medicando parámetros como el formato de modulación, el ancho de banda o la codificación de Forward Error Correction (FEC), entre otros, para encontrar un equilibrio entre el alcance de la transmisión y la eficiencia espectral, sirviendo múltiples destinos. La combinación de módulos programables de Digital Signal Processing (DSP) con técnicas de transmisión avanzadas, basadas en la tecnología Orthogonal Frequency Division Multiplexing (OFDM) con detección directa o detección coherente, se han propuesto para ser implementadas en el S-BVT, haciéndolo adecuado para su uso en redes ópticas elásticas metropolitanas y regionales. Además, la migración prevista de las redes fijas a las redes flexibles, con el fin de explotar la granularidad de 12:5 GHz, puede beneficiarse del uso de S-BVTs ya que son capaces de generar y recibir múltiples canales y dividir el flujo agregado en múltiples flujos con diferentes capacidades y destinos. A este respecto, proponemos el uso de S-BVTs basados en señales OFDM multi banda combinadas en el dominio eléctrico con el fin de limitar los recursos optoelectrónicas y relajar los requerimientos de los convertidores digitales analógicos y analógicos digitales. En particular, nos centramos en el modelo teórico de una técnica de transmisión avanzada basada en la tecnología OFDM con detección directa. A continuación, evaluamos el sistema para una red metropolitana óptica realista. En el contexto de redes metropolitanas y regionales flexibles, además de la capacidad de división de los canales, se puede prever una posible reducción del ancho de canal para las conexiones de baja tasa de bits. Esto implica que la señal atraviese varios nodos con los correspondientes elementos filtrantes causando un substancial decremento y distorsión del ancho de banda de la señal. Este fenómeno conocido como el efecto de estrechamiento de filtrado ha sido también estudiado en esta tesis, mediante simulaciones y de manera experimental para un sistema OFDM rentable y adaptativo usando detección directa y un sistema estándar On-Off Keying (OOK). El sistema OFDM de detección directa ha resultado ser un buen candidato para aumentar la flexibilidad y la robustez frente a las deficiencias de transmisión sin necesidad de compensar la dispersión. Aparte de los transceptores adaptables, flexibles y programables, las redes ópticas metropolitanas deben estar equipadas con sistemas de conmutación óptica flexible a nivel de nodo. En este sentido, proponemos la adopción de S-BVTs adaptativos basados en técnicas de transmisión avanzadas usando detección directa con modulación Discrete MultiTone (DMT) y capacidades adaptativas, adoptando nodos de conmutación basados en Semiconductor Optical Amplifier (SOA). Los SOAs pueden ser utilizados para la conmutación óptica en redes metropolitanas debido a su bajo coste o bajo consumo de energía, entre otras características relevantes. El sistema ha sido analizado experimentalmente considerando y sin considerar la presencia de elementos filtrantes. Gracias a la combinación de la modulación DMT adaptativa y los nodos de conmutación basados en SOA, las degradaciones debidas a los enlaces de fibra y a los elementos filtrantes se pueden compensar. Finalmente, para mejorar la distancia de transmisión y la tasa de datos, proponemos la combinación de constelaciones multidimensionales implementadas en los módulos DSP del S-BVT utilizando detectaron coherente y la tecnología OFDM. De hecho, los sistemas OFDM coherentes tienen un espacio de señal 4D (dos cuadraturas y dos polarizaciones), que puede ser utilizado con constelaciones multidimensionales, pudiendo éstas ser más eficientes que las convencionales Binary Phase-Shift Keying (BPSK) o Quadrature Phase-Shift Keying (QPSK). De este modo, la infraestructura desplegada se explota de manera más eficiente, ya que tanto la dimensión de cuadratura como de polarización se utilizan para transmitir la señal. Además, los sistemas OFDM coherentes pueden recuperar la amplitud y la fase de la señal en el receptor, mitigando los efectos de la fibra aumentando, de esta forma, la distancia de transmisión. El sistema OFDM coherente que utiliza el formato de constelación Dual Polarization Quadrature Phase Shift Keying (DPQPSK) y que transmite la señal a lo largo del tiempo ha demostrado ser una solución prometedora.El comportament dinàmic de la demanda de transit, a causa de l'arribada de tecnologies, com poden ser els serveis al núvol o l'Internet of Things (IoT), està creixent. De fet, s'espera que coexisteixin a les xarxes òptiques connexions heterogènies amb característiques diferents, tal com l'ample de banda o la taxa de bits. Per a fer front a aquestes demandes és crucial una revolució de les xarxes òptiques. En aquest sentit, les Elastic Optical Networks (EONs) emergeixen com una solució rendible, flexible i dinàmica. La idea principal es basa en la utilització eficient de l'espectre òptic mitjançant la combinació de transceptors flexibles, xarxes flexibles i commutació òptica flexible. Una major flexibilitat i adaptabilitat es pot aconseguir incloent els principis del paradigma conegut com a Software Defined Networks (SDN). L’adopció de l'arquitectura SDN implica la separació del plànol de control i de dades permetent la programabilitat de la xarxa d'una forma dinàmica. Un element clau en les EONs és l'Sliceable Bandwith Variable Transceiver (S-BVT), ja que aporta flexibilitat i adaptabilitat a les xarxes òptiques. L' S-BVT és capaç de canviar l'ample de banda o la taxa de bits modificant paràmetres com el format de modulació, l'ample de banda o la codificació del Forward Error Correction (FEC), entre altres, per a trobar un equilibri entre l’assistència assolida i l’eficiència espectral, servint múltiples destinacions. La combinació de mòduls de Digital Signal Processing (DSP) amb tècniques de transmissió avançades basades en la tecnologia Orthogonal Frequency Division Multiplexing (OFDM) i detecció directa o detecció coherent s'han proposat per a ser implementades en l'S-BVT, fent-lo adient per a les xarxes òptiques elàstiques metropolitanes i regionals. A més, la migració prevista des de les xarxes fixes a les xarxes flexibles, amb el fi d'explotar la granuralitat de 12:5GHz, pot beneficiar-se de l’ús d'S-BVTs ja que són capaços de generar i rebre múltiples canals i dividir el flux agregat en múltiples fluxos amb diferents capacitats i destinacions. Per aquest motiu, proposem l’ús d'S-BVTs basats en senyals OFDM multi banda combinats en el domini elèctric amb el fi de limitar els recursos optoelectrònics i relaxar els requeriments dels convertidors digitals analògics i analògics digitals. Particularment, ens centrem en el model teòric d'una tècnica de transmissió avançada basada en la tecnologia OFDM amb detecció directa. A continuació, avaluem el sistema per a una xarxa metropolitana òptica realista. En el context de xarxes metropolitanes i regionals flexibles, a més de la propietat de divisió dels canals, es pot preveure una possible reducció de l'ample de canal per a les connexions de baixa taxa de bits. Això implica que el senyal travessi diversos nodes amb els corresponents elements filtrants causant un substancial decrement i distorsió de l'ample de banda del senyal. Aquest fenomen conegut com l'efecte d'estretament de filtrat ha sigut també estudiat en aquesta tesi, mitjançant simulacions i de manera experimental en el cas d'un sistema OFDM rendible i adaptatiu utilitzant detecció directa i un sistema estàndard On-Off Keying (OOK). El sistema OFDM de detecció directa ha resultat ser un bon candidat per augmentar la flexibilitat i la robustesa front a les deficiències de transmissió sense necessitat de compensar la dispersió. A part dels transceptors adaptables, flexibles i programables, les xarxes òptiques metropolitanes han d'estar equipades amb sistemes de commutació òptica flexible a nivell de node. En aquest sentit, proposem l’adopció d'un S-BVT adaptatiu basat en tècniques de transmissió avançades i utilitzant detecció directa amb modulació Discrete MultiTone (DMT) i capacitats adaptatives, adoptant nodes de comunicació basats en Semi-conductor Optical Amplifier (SOA). Els SOAs poden ser utilitzats per la commutació _òptica en xarxes metropolitanes degut al seu baix cost o baix consum d'energia, entre altres característiques rellevants. El sistema ha sigut analitzat experimentalment considerant i sense considerar la presència d'elements filtrants. Gràcies a la combinació de la modulació DMT adaptativa i dels nodes de commutació basats en SOA, les degradacions degudes als enllaços de fibra i als elements filtrants es poden compensar. Finalment, per a millorar la distància de transmissió i la taxa de dades, proposem la combinació de constel·lacions multidimensionals implementades als mòduls DSP de l'SBVT utilitzant detecció coherent i la tecnologia OFDM. De fet, els sistemes coherents OFDM tenen un espai de senyal 4D (dues quadratures i dues polaritzacions), que pot ser utilitzat amb constel·lacions multidimensionals, arribant a ser més eficients que les modulacions convencionals Binary Phase-Shift Keying (BPSK) o Quadrature Phase-Shift Keying (QPSK). D'aquesta manera, la infraestructura desplegada s'explota de forma més eficient, ja que tant la dimensió de quadratura com de polarització s'utilitzen per transmetre el senyal. A més, els sistemes coherents basats en OFDM poden recuperar l'amplitud i la fase del senyal en el receptor, mitigant els efectes de la fibra i d'aquesta forma augmentant la distància de transmissió. El sistema OFDM coherent que utilitza el format de constel·lació Dual Polarization Quadrature Phase Shift Keying (DPQPSK) i que transmet el senyal al llarg del temps ha demostrat ser una solució prometedora.Postprint (published version