Photonic logic-gates: boosting all-optical header processing in future packet-switched networks

Las redes ópticas de paquetes se han convertido en los últimos años en uno de los temas de vanguardia en el campo de las tecnologías de comunicaciones. El procesado de cabeceras es una de las funciones más importantes que se llevan a cabo en nodos intermedios, donde un paquete debe ser encaminado a su destino correspondiente. El uso de tecnología completamente óptica para las funciones de encaminamiento y reconocimiento de cabeceras reduce el retardo de procesado respecto al procesado eléctrico, disminuyendo de ese modo la latencia en el enlace de comunicaciones. Existen diferentes métodos de procesado de datos para implementar el reconocimiento de cabeceras. El objetivo de este trabajo es la propuesta de una nueva arquitectura para el procesado de cabeceras basado en el uso de puertas lógicas completamente ópticas. Estas arquitecturas tienen como elemento clave el interferómetro Mach-Zehnder basado en el amplificador óptico de semiconductor (SOA-MZI), y utilizan el efecto no lineal de modulación cruzada de fase (XPM) en los SOAs para realizar dicha funcionalidad. La estructura SOA-MZI con XPM es una de las alternativas más atractivas debido a las numerosas ventajas que presenta, como por ejemplo los requisitos de baja energía para las señales de entrada, su diseño compacto, una elevada relación de extinción (ER), regeneración de la señal y el bajo nivel de chirp que introducen. Este trabajo se ha centrado en la implementación de la funcionalidad lógica XOR. Mediante esta función se pueden realizar diversas funcionalidades en las redes ópticas. Se proponen dos esquemas para el reconocimiento de cabeceras basados en el uso de la puerta XOR. El primer esquema utiliza puertas en cascada. El segundo esquema presenta una arquitectura muy escalable, y se basa en el uso de un bucle de realimentación implementado a la salida de la puerta. Asimismo, también se presentan algunas aplicaciones del procesado de cabeceras para el encaminamiento de paquetes basadas en el uso dMartínez Canet, JM. (2006). Photonic logic-gates: boosting all-optical header processing in future packet-switched networks [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/1874Palanci

Towards all-optical label switching nodes with multicast

Fiber optics has developed so rapidly during the last decades that it has be- come the backbone of our communication systems. Evolved from initially static single-channel point-to-point links, the current advanced optical backbone net- work consists mostly of wavelength-division multiplexed (WDM) networks with optical add/drop multiplexing nodes and optical cross-connects that can switch data in the optical domain. However, the commercially implemented optical net- work nodes are still performing optical circuit switching using wavelength routing. The dedicated use of wavelength and infrequent recon¯guration result in relatively poor bandwidth utilization. The success of electronic packet switching has inspired researchers to improve the °exibility, e±ciency, granularity and network utiliza- tion of optical networks by introducing optical packet switching using short, local optical labels for forwarding decision making at intermediate optical core network nodes, a technique that is referred to as optical label switching (OLS). Various research demonstrations on OLS systems have been reported with transparent optical packet payload forwarding based on electronic packet label processing, taking advantage of the mature technologies of electronic logical cir- cuitry. This approach requires optic-electronic-optic (OEO) conversion of the op- tical labels, a costly and power consuming procedure particularly for high-speed labels. As optical packet payload bit rate increases from gigabit per second (Gb/s) to terabit per second (Tb/s) or higher, the increased speed of the optical labels will eventually face the electronic bottleneck, so that the OEO conversion and the electronic label processing will be no longer e±cient. OLS with label processing in the optical domain, namely, all-optical label switching (AOLS), will become necessary. Di®erent AOLS techniques have been proposed in the last ¯ve years. In this thesis, AOLS node architectures based on optical time-serial label processing are presented for WDM optical packets. The unicast node architecture, where each optical packet is to be sent to only one output port of the node, has been in- vestigated and partially demonstrated in the EU IST-LASAGNE project. This thesis contributes to the multicast aspects of the AOLS nodes, where the optical packets can be forwarded to multiple or all output ports of a node. Multicast capable AOLS nodes are becoming increasingly interesting due to the exponen- tial growth of the emerging multicast Internet and modern data services such as video streaming, high de¯nition TV, multi-party online games, and enterprise ap- plications such as video conferencing and optical storage area networks. Current electronic routers implement multicast in the Internet protocol (IP) layer, which requires not only the OEO conversion of the optical packets, but also exhaus- tive routing table lookup of the globally unique IP addresses. Despite that, there has been no extensive studies on AOLS multicast nodes, technologies and tra±c performance, apart from a few proof-of-principle experimental demonstrations. In this thesis, three aspects of the multicast capable AOLS nodes are addressed: 1. Logical design of the AOLS multicast node architectures, as well as func- tional subsystems and interconnections, based on state-of-the-art literature research of the ¯eld and the subject. 2. Computer simulations of the tra±c performance of di®erent AOLS unicast and multicast node architectures, using a custom-developed AOLS simulator AOLSim. 3. Experimental demonstrations in laboratory and computer simulations using the commercially available simulator VPItransmissionMakerTM, to evaluate the physical layer performance of the required all-optical multicast technolo- gies. A few selected multi-wavelength conversion (MWC) techniques are particularly looked into. MWC is an essential subsystem of the AOLS node for realizing optical packet multicast by making multiple copies of the optical packet all-optically onto di®er- ent wavelengths channels. In this thesis, theMWC techniques based on cross-phase modulation and four-wave mixing are extensively investigated. The former tech- nique o®ers more wavelength °exibility and good conversion e±ciency, but it is only applicable to intensity modulated signals. The latter technique, on the other hand, o®ers strict transparency in data rate and modulation format, but its work- ing wavelengths are limited by the device or component used, and the conversion e±ciency is considerably lower. The proposals and results presented in this thesis show feasibility of all-optical packet switching and multicasting at line speed without any OEO conversion and electronic processing. The scalability and the costly optical components of the AOLS nodes have been so far two of the major obstacles for commercialization of the AOLS concept. This thesis also introduced a novel, scalable optical labeling concept and a label processing scheme for the AOLS multicast nodes. The pro- posed scheme makes use of the spatial positions of each label bit instead of the total absolute value of all the label bits. Thus for an n-bit label, the complexity of the label processor is determined by n instead of 2n

Label-controlled optical switching nodes

Optical networks are evolving from initially static optical circuits and subsequently optical circuit switching towards optical packet switching in order to take advan- tage of the high transport capacity made available by WDM systems in a more °exible and e±cient way. Optically labeling of packets and routing the packets's payload optically under control of its label allows the network nodes to route and forward IP data without having to process the payload, thus keeping it in the optical domain; this is a promising solution to avoid electronic bottlenecks in routers. All-optical label switching can therefore be used to route and forward packets independent of their length and payload bitrate. Several optical signal labeling techniques have been proposed in previous re- search reported in literature; orthogonal labeling and time-serial labeling have been studied in this thesis. This thesis studies two orthogonal modulation label- ing techniques: one based on FSK labels with an IM payload, and another one on SCM labeling for a DPSK modulated payload. A time-serial labeling method based on IM labels with IM or DPSK payload is also presented and studied. The ¯rst two techniques assume electronic processing of the labels in the node, and hence assume that labels can be transmitted at a much lower bitrate than the payload data rate. The third technique assumes all-optical signal processing in the nodes, capable of handling a label at the same bitrate or slightly lower than the payload data. Labels at low bitrate in comparison with the payload bitrate are desirable in systems where the label processing will be conducted in the electrical domain, while labels at the same bitrate as the payload can be used in systems where the processing is conducted in the optical domain, exploiting all-optical processing techniques. These three techniques have been chosen because they are compatible with the existing networks, since the modulation format, bitrates, transmission properties, and other features of the signals are similar to the ones used for commercially available applications. Thus, they can be considered important candidates for migration scenarios from optical circuit switching towards optical burst switching networking. Orthogonal labeling based on FSK/IM is a promising scheme for implementing the labeling of optical signals, and it is the technology of choice in the STOLAS project. This technique o®ers advantageous features such as a relaxed timing de- lineation between payload and label, and ease of label erasure and re-writing of new labels. By using wavelength-agile tunable laser sources with FSK modula- tion capability, wavelength converters, and passive wavelength routing elements, a scalable modular label-controlled router featuring high reliability can be built. In this thesis, several aspects of the physical parameters of an FSK/IM labeling scheme within a routing node have been studied and presented. Optical ¯ltering requires special care, since the combined FSK/IM scheme has a broader spectrum than that of pure intensity modulated signals. The requirements on the limited extinction ratio for the IM signal can be relaxed at low bitrates of the label signal or, alternatively, by introducing data encoding. Optical labeling by using FSK/IM represents a simple and attractive way of implementing hybrid optical circuit and burst switching in optical networks. Architecturally, similar advantages can be mentioned for the second orthogo- nal labeling technique studied in this thesis, based on SCM labels and a DPSK payload. In-band subcarriers carrying low bitrate labels located at a frequency equal to half the bitrate of the payload signal can be inserted introducing only low power penalties. Wavelength conversion can be implemented by using passive highly nonlinear ¯bers and exploiting the four-wave mixing e®ect. This thesis also studies the design of two functional blocks of an all-optical core node proposed in the LASAGNE project, namely the all-optical label and payload separator and the wavelength converter unit for a time-serial labeling scheme. The label and payload processor can be realized exploiting nonlinear e®ects in SOAs. An implementation using polarization division multiplexing to transport the external control light for an IM/IM time-serial scheme was demon- strated. Label and payload processors with self-contained control signals were also demonstrated, either using a DPSK signal to simultaneously transport the payload data and the control signal or inserting a CW dummy in between the label and the payload, which were based on IM-RZ format. A study on single- and multi- wavelength conversion based on FWM in a HNLF was presented. This approach allows transparent wavelength conversion (independent of the data format used) at high bitrates (the nonlinear e®ects in a ¯ber are obtained at ultrafast speeds). The labeling techniques explored have indicated a viable way of migration towards optical burst packet switched networks while signi¯cantly improving the throughput of the routing nodes

On architecture and scalability of optical multi-protocol label switching networks using optical-orthogonal-code label.

Wen Yonggang.Thesis (M.Phil.)--Chinese University of Hong Kong, 2001.Includes bibliographical references.Abstracts in English and Chinese.Chapter 1 --- IntroductionChapter 1.1 --- Multi-Protocol Label Switching (MPLS) Technology --- p.1Chapter 1.2 --- Objective of this Thesis --- p.4Chapter 1.3 --- Reference --- p.5Chapter 2 --- Optical MPLS Network and Optical Label SchemesChapter 2.1 --- Optical MPLS Network --- p.7Chapter 2.2 --- Optical Label Schemes --- p.10Chapter 2.2.1 --- Time-division OMPLS scheme --- p.12Chapter 2.2.2 --- Wavelength-division OMPLS scheme --- p.16Chapter 2.2.3 --- Frequency-division OMPLS scheme --- p.22Chapter 2.2.3.1 --- UCSB Testbed --- p.23Chapter 2.2.3.2 --- UC-Davis Testbed --- p.26Chapter 2.2.3.3 --- NCTU-Telecordia Testbed --- p.28Chapter 2.2.4 --- Code-division OMPLS scheme --- p.30Chapter 2.2.4.1 --- Coherent Code-Division Label Scheme --- p.30Chapter 2.2.4.2 --- Noncoherent Code-Division Label Scheme --- p.32Chapter 2.3 --- Reference --- p.35Chapter 3 --- Architecture of OOC-based OMPLS networkChapter 3.1 --- Infrastructure of OOC-label switch router (code converter) --- p.37Chapter 3.1.1 --- Architecture of the Proposed Code Converter --- p.38Chapter 3.1.2 --- Enhancement of the Code Converter --- p.41Chapter 3.2 --- Implementation of the OOC code converter --- p.43Chapter 3.2.1 --- Encoders/Decoders --- p.43Chapter 3.2.1.1 --- All-parallel encoders/decoders --- p.43Chapter 3.2.1.2 --- All-serial encoders/decoders --- p.45Chapter 3.2.1.3 --- Serial-to-parallel encoder/decoders --- p.47Chapter 3.2.1.4 --- Comparison of the three kinds of encoders/decoders --- p.49Chapter 3.2.2 --- Time-Gate-Intensity-Threshold (TGIT) Device --- p.50Chapter 3.2.3 --- Optical Space Switch Array --- p.54Chapter 3.2.3.1 --- All-optical Space Switch --- p.54Chapter 3.2.3.2 --- Optical switching technologies --- p.56Chapter 3.2.3.2.1 --- Scalability --- p.56Chapter 3.2.3.2.2 --- Switching Speed --- p.57Chapter 3.2.3.2.3 --- Reliability --- p.57Chapter 3.2.3.2.4 --- Losses --- p.58Chapter 3.2.3.2.5 --- Port-to-Port repeatability --- p.58Chapter 3.2.3.2.6 --- Cost --- p.59Chapter 3.2.3.2.7 --- Power Consumption --- p.60Chapter 3.3 --- Reference --- p.61Chapter 4 --- Scalability of OOC-based MPLS networkChapter 4.1 --- Limitation on Label Switching Capacity --- p.63Chapter 4.1.1 --- Upper Bound --- p.65Chapter 4.1.2 --- Lower Bound --- p.66Chapter 4.2 --- Limitation on Switching Cascadability --- p.70Chapter 4.2.1. --- Limit Induced by the Inter-channel Crosstalk --- p.70Chapter 4.2.2 --- Limits Induced by the Residue Intensity of Sidelobes --- p.74Chapter 4.3 --- Appendix --- p.78Chapter 4.3.1 --- Derivation of Chip Intensity --- p.78Chapter 4.3.2 --- The 5% residue power criterion --- p.81Chapter 4.4 --- Reference --- p.83Chapter 5 --- ConclusionChapter 5.1 --- Summary of the Thesis --- p.85Chapter 5.2 --- Future work --- p.8

Characterisation and optimisation of the semiconductor optical amplifier for ultra-high speed performance

This research is in the area of high speed telecommunication systems where all- optical technologies are being introduced to meet the ever increasing demand for bandwidth by replacing the costly electro-optical conversion modules. In such systems, all-optical routers are the key technologies capable of supporting networks with high capacity/bandwidth as well as offering lower power consumption. One of the fundamental building blocks in all-optical routers/networks is the semiconductor optical amplifier (SOA), which is used in for clock extraction, wavelength conversion, all-optical gates and optical processing. The SOAs are perfect for optical amplification and optical switching at a very high speed. This is due to their small size, a low switching energy, non-linear characteristics and the seamless integration with other optical devices. Therefore, characterisation of the SOA operational functionalities and optimisation of its performance for amplification and switching are essential and challenging. Existing models on SOA gain dynamics do not address the impact of optical propagating wavelength, the combined input parameters and their adaptation for optimised amplification and switching operations. The SOA operation is limited at high data rates > 2.5 Gb/s to a greater extent by the gain recovery time. A number of schemes have been proposed to overcome this limitation; however no work has been reported on the SOA for improving the gain uniformity. This research aims to characterise the boundaries conditions and optimise the SOA performance for amplification and switching. The research also proposes alternative techniques to maximise the SOA gain uniformity at ultra-high speed data rates theoretically and practically. An SOA model is been developed and used throughout the research for theoretical simulations. Results show that the optimum conditions required to achieve the maximum output gain for best amplification performance depends on the SOA peak gain wavelength. It is also shown that the optimum phase shift of 180º for switching can be induced at lower input power level when the SOA biasing current is at its maximum limit. A gain standard deviation equation is introduced to measure the SOA gain uniformity. New wavelength diversity technique is proposed to achieve an average improvement of 7.82 dB in the SOA gain standard deviation at rates from 10 to 160 Gb/s. Other novel techniques that improved the gain uniformity employing triangular and sawtooth bias currents, as replacements for the uniform biasing, have been proposed. However, these current patterns were not able to improve the SOA gain uniformity at data rates beyond 40 Gb/s. For that reason, an optimised biasing for SOA (OBS) pattern is introduced to maximise the gain uniformity at any input data rates. This OBS pattern was practically generated and compared to the uniform biased SOA at different data rates and with different input bit sequences. All executed experiments showed better output uniformities employing the proposed OBS pattern with an average improvement of 19%

Applications of optical orthogonal modulation schemes in optical networks.

Yang Yi.Thesis (M.Phil.)--Chinese University of Hong Kong, 2004.Includes bibliographical references (leaves 51-55).Abstracts in English and Chinese.ACKNOWLEDGEMENTS --- p.IIABSTRACT --- p.III摘要 --- p.IVCONTENTS --- p.VChapter CHAPTER 1: --- INTRODUCTION --- p.1Chapter 1.1. --- Modulation Formats in Optical Communication SYSTEMS --- p.2Chapter 1.1.1 --- Optical ASK Format --- p.3Chapter 1.1.2 --- Optical FSK Format --- p.4Chapter 1.1.3 --- Optical PSK Format --- p.5Chapter 1.1.4 --- Optical Orthogonal Modulation --- p.7Chapter 1.2. --- All-Optical Packet Switching --- p.8Chapter 1.2.1 --- AOLS Using Subcarrier Labels --- p.9Chapter 1.2.2 --- Serial Labels --- p.10Chapter 1.2.3 --- Orthogonal Modulated Labels --- p.12Chapter 1.3. --- Optical Supervisory Control --- p.13Chapter 1.3.1 --- OXC Supervisory Schemes --- p.13Chapter 1.3.2 --- Optical A mplifier Supervisory Schemes --- p.14Chapter 1.3.3 --- Optical Supervisory Schemes for Transmission Networks --- p.15Chapter 1.4. --- Thesis Organization --- p.16Chapter CHAPTER 2: --- PREVIOUS STUDIES ON OPTICAL ORTHOGONAL MODULATION….… --- p.17Chapter 2.1. --- Orthogonal Modulation Used in STARNET --- p.17Chapter 2.2. --- AOLS in IP-over-WDM Networks Employing Orthogonal Modulation --- p.18Chapter 2.2.1 --- DPSK Labels on ASK Payload --- p.18Chapter 2.2.2 --- FSK Labels on ASK Payload --- p.20Chapter 2.2.3 --- Experimental Result of ASK/DPSK Label Swapping --- p.21Chapter 2.3. --- Quaternary Optical ASK-DPSK Modulation --- p.22Chapter 2.4. --- Conclusion --- p.23Chapter CHAPTER 3: --- OPTICAL DPSK/ASK ORTHOGONAL MODULATION SCHEME --- p.24Chapter 3.1. --- motivation --- p.24Chapter 3.2. --- Proposed Optical DPSK/ASK Orthogonal Modulation Scheme --- p.25Chapter 3.3. --- DPSK/ASK orthogonal modulation modules --- p.26Chapter 3.4. --- Numerical Simulations --- p.27Chapter 3.4.1 --- Mathematical Model of DPSK/ASK Signal --- p.28Chapter 3.4.2 --- Simulation Model --- p.31Chapter 3.4.3 --- Simulation Results --- p.32Chapter 3.5. --- Experimental Demonstration --- p.34Chapter 3.5.1 --- Experimental Setup --- p.34Chapter 3.5.2 --- Experimental Results --- p.36Chapter 3.6. --- transmission experiment --- p.38Chapter 3.7. --- Supervisory Information Dissemination Using DPSK/ASK Orthogonal Modulation --- p.41Chapter 3.8. --- Label Swapping Experiment and Results --- p.42Chapter 3.8.1 --- Experiment Setup --- p.42Chapter 3.8.2 --- Experiment Results --- p.45Chapter CHAPTER 4: --- CONCLUSION --- p.48Chapter 4.1. --- Thesis Summary --- p.48Chapter 4.2. --- Future Work --- p.49LIST OF PUBLICATIONS --- p.50REFERENCES --- p.5

Optical performance monitoring in optical packet-switched networks

Para poder satisfacer la demanda de mayores anchos de banda y los requisitos de los nuevos servicios, se espera que se produzca una evolución de las redes ópticas hacia arquitecturas reconfigurables dinámicamente. Esta evolución subraya la importancia de ofrecer soluciones en la que la escalabilidad y la flexibilidad sean las principales directrices. De acuerdo a estas características, las redes ópticas de conmutación de paquetes (OPS) proporcionan altas capacidades de transmisión, eficiencia en ancho de banda y excelente flexibilidad, además de permitir el procesado de los paquetes directamente en la capa óptica. En este escenario, la solución all-optical label switching (AOLS) resuelve el cuello de botella impuesto por los nodos que realizan el procesado en el dominio eléctrico. A pesar de los progresos en el campo del networking óptico, las redes totalmente ópticas todavía se consideran una solución lejana . Por tanto, es importante desarrollar un escenario de migración factible y gradual desde las actuales redes ópticas basadas en la conmutación de circuitos (OCS). Uno de los objetivos de esta tesis se centra en la propuesta de escenarios de migración basados en redes híbridas que combinan diferentes tecnologías de conmutación. Además, se analiza la arquitectura de una red OPS compuesta de nodos que incorporan nuevas funcionalidades relacionadas con labores de monitorización y esquemas de recuperación. Las redes ópticas permiten mejorar la transparencia de la red, pero a costa de aumentar la complejidad de las tareas de gesión. En este escenario, la monitorización óptica de prestaciones (OPM) surge como una tecnología capaz de facilitar la administración de las redes OPS, en las que cada paquete sigue su propia ruta en la red y sufre un diferente nivel de degradación al llegar a su destino. Aquí reside la importancia de OPM para garantizar los requisitos de calidad de cada paquete.Vilar Mateo, R. (2010). Optical performance monitoring in optical packet-switched networks [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/8926Palanci