Getting routers out of the core: Building an optical wide area network with "multipaths"

We propose an all-optical networking solution for a wide area network (WAN) based on the notion of multipoint-to-multipoint lightpaths that, for short, we call "multipaths". A multipath concentrates the traffic of a group of source nodes on a wavelength channel using an adapted MAC protocol and multicasts this traffic to a group of destination nodes that extract their own data from the confluent stream. The proposed network can be built using existing components and appears less complex and more efficient in terms of energy consumption than alternatives like OPS and OBS. The paper presents the multipath architecture and compares its energy consumption to that of a classical router-based ISP network. A flow-aware dynamic bandwidth allocation algorithm is proposed and shown to have excellent performance in terms of throughput and delay

High capacity photonic integrated switching circuits

As the demand for high-capacity data transfer keeps increasing in high performance computing and in a broader range of system area networking environments; reconfiguring the strained networks at ever faster speeds with larger volumes of traffic has become a huge challenge. Formidable bottlenecks appear at the physical layer of these switched interconnects due to its energy consumption and footprint. The energy consumption of the highly sophisticated but increasingly unwieldy electronic switching systems is growing rapidly with line rate, and their designs are already being constrained by heat and power management issues. The routing of multi-Terabit/second data using optical techniques has been targeted by leading international industrial and academic research labs. So far the work has relied largely on discrete components which are bulky and incurconsiderable networking complexity. The integration of the most promising architectures is required in a way which fully leverages the advantages of photonic technologies. Photonic integration technologies offer the promise of low power consumption and reduced footprint. In particular, photonic integrated semiconductor optical amplifier (SOA) gate-based circuits have received much attention as a potential solution. SOA gates exhibit multi-terahertz bandwidths and can be switched from a high-gain state to a high-loss state within a nanosecond using low-voltage electronics. In addition, in contrast to the electronic switching systems, their energy consumption does not rise with line rate. This dissertation will discuss, through the use of different kind of materials and integration technologies, that photonic integrated SOA-based optoelectronic switches can be scalable in either connectivity or data capacity and are poised to become a key technology for very high-speed applications. In Chapter 2, the optical switching background with the drawbacks of optical switches using electronic cores is discussed. The current optical technologies for switching are reviewed with special attention given to the SOA-based switches. Chapter 3 discusses the first demonstrations using quantum dot (QD) material to develop scalable and compact switching matrices operating in the 1.55µm telecommunication window. In Chapter 4, the capacity limitations of scalable quantum well (QW) SOA-based multistage switches is assessed through experimental studies for the first time. In Chapter 5 theoretical analysis on the dependence of data integrity as ultrahigh line-rate and number of monolithically integrated SOA-stages increases is discussed. Chapter 6 presents some designs for the next generation of large scale photonic integrated interconnects. A 16x16 switch architecture is described from its blocking properties to the new miniaturized elements proposed. Finally, Chapter 7 presents several recommendations for future work, along with some concluding remark

All Optical Signal Processing Technologies in Optical Fiber Communication

Due to continued growth of internet at starling rate and the introduction of new broadband services, such as cloud computing, IPTV and high-definition media streaming, there is a requirement for flexible bandwidth infrastructure that supports mobility of data at peta-scale. Elastic networking based on gridless spectrum technology is evolving as a favorable solution for the flexible optical networking supportive next generation traffic requirements. Recently, research is centered on a more elastic spectrum provision methodology than the traditional ITU-T grid. The main issue is the requirement for a transmission connect, capable of accommodating and handling a variety of signals with distinct modulation format, baud rate and spectral occupancy. Segmented use of the spectrum could lead to the shortage of availableness of sufficiently extensive spectrum spaces for high bitrate channels, resulting in wavelength contention. On-demand space assignment creates not only deviation from the ideal course but also have spectrum fragmentation, which reduces spectrum resource utilization. This chapter reviewed the recent research development of feasible solutions for the efficient transport of heterogeneous traffic by enhancing the flexibility of the optical layer for performing allocation of network resources as well as implementation of optical node by all optical signal processing in optical fiber communication

Metamateriales sub-longitud de onda para microdispositivos fotónicos de altas prestaciones

Tesis inédita de la Universidad Complutense de Madrid, Facultad de Ciencias Físicas, leída el 28-04-2020Photonics has become of paramount importance in many areas of our everyday life owing to its inherent potential to develop not only telecom and datacom solutions, but also many other applications such as metrology [DeMiguel’18], energy generation and saving [Polman’12, Miller’17], spectrometry [Velasco’13a], sensing [Rodríguez-Barrios’10], medicine [Morgner’00] and industrial manufacturing [Malinauskas’16], to name a few. Particularly, integrated optics has attracted increasing industrial attention and scientific efforts to implement photonic integrated circuits (PICs) capable of tackling all abovementioned tasks in compact and efficient systems.Among all the available materials, silicon photonics leverages the maturity of the fabrication techniques reached by the microelectronics industry, enabling cost-effective mass production [Chen’18]. Different material platforms with a high refractive index contrast have been proposed for silicon photonics to achieve higher integration levels and perform more complex functions in a single chip, such as silicon-on-insulator (SOI) and silicon nitride (Si3N4, commonly simplified to SiN). The increased integration capacity of silicon photonics has enabled to tackle one of our greatest technological challenges: global data traffic inside data centers. Besides short-range optical interconnects for telecom and datacom applications, the progress in silicon photonics also encompasses many other untapped applications that are being explored by academia and industry: absorption spectroscopy and bio-sensing [Herrero-Bermello’17, Wangüemert-Pérez’19], light detection and ranging (LIDAR) [Poulton’17a], quantum computing [Harris’16], microwave and terahertz photonics [Marpaung’19, Harter’18], nonlinear optics [Leuthold’10], and many others...La fotónica ha adquirido una importancia fundamental en muchos ámbitos de nuestra vida cotidiana debido a su potencial intrínseco para desarrollar soluciones no sólo en el campo de las telecomunicaciones y las interconexiones de corto alcance, sino también en otras muchas áreas como la metrología [DeMiguel’18], la generación de energía [Polman’12, Miller’17], la espectrometría [Velasco’13a], la detección [Rodríguez-Barrios’10], la medicina [Morgner’00] y la fabricación industrial [Malinauskas’16]. En particular, la óptica integrada ha atraído tanto la atención de la industria como los esfuerzos científicos para implementar circuitos fotónicos integrados (PICs, Photonic Integrated Circuits) capaces de abordar todas las tareas mencionadas anteriormente en sistemas compactos y eficientes. Entre todos los materiales disponibles, la fotónica de silicio aprovecha la madurez de las técnicas de fabricación alcanzadas por la industria de la microelectrónica, permitiendo una producción en masa rentable [Chen’18]. Para maximizar su densidad de integración y poder realizar funciones más complejas en un único chip, diferentes plataformas materiales con un alto contraste de índice de refracción se han propuesto, como por ejemplo las plataformas de silicio sobre aislante (SOI, Silicon-On-Insulator) y de nitruro de silicio (Si3N4, comúnmente simplificada a SiN, Silicon Nitride). Esta mayor densidad de integración ha permitido abordar uno de nuestros mayores desafíos tecnológicos hasta la fecha: el tráfico de datos global dentro de los centros de datos. Además de las interconexiones ópticas de corto alcance, el progreso de la fotónica de silicio también comprende muchas otras aplicaciones inexploradas que están siendo estudiadas en el ámbito académico e industrial como, por ejemplo, la espectroscopía de absorción y biodetección [Herrero-Bermello’17, Wangüemert-Pérez’19], LIDAR (Light Detection And Ranging) [Poulton’17a], computación cuántica [Harris’16], fotónica de microondas y terahercios [Marpaung’19, Harter’18], óptica no lineal [Leuthold’10], y muchas otras...Fac. de Ciencias FísicasTRUEunpu

Silicon Photonics for All-Optical Processing and High-Bandwidth-Density Interconnects

Silicon photonics has emerged in recent years as one of the leading technologies poised to enable penetration of optical communications deeper and more intimately into computing systems than ever before. The integration potential of power efficient WDM links at the first level package or even deeper has been a strong driver for the rapid development this field has seen in recent years. The integration of photonic communication modules with very high bandwidth densities and virtually no bandwidth-distance limitations at the short reach regime of high performance computers and data centers has the potential to alleviate many of the bandwidth bottlenecks currently faced by board, rack, and facility levels. While networks on chip for chip multiprocessors (CMP) were initially deemed the target application of silicon photonic components, it has become evident in recent years that the initial lower hanging fruit is the CMP's I/O links to memory as well as other CMPs. The first chapter of the thesis provides more detailed motivation for the integration of silicon photonic modules into compute systems and surveys some of the recent developments in the field. The second chapter then proceeds to detail a technical case study of silicon photonic microring-based WDM links' scalability and power efficiency for these chip I/O applications which could be developed in the intermediate future. The analysis, initiated originally for a workshop on optical and electrical board and rack level interconnects, looks into a detailed model of the optical power budget for such a link capturing both single-channel aspects as well as WDM-operation-related considerations which are unique for a microring physical characteristics. The holistic analysis for the full link captures the wavelength-channel-spacing dependent characteristics, provides some methodologies for device design in the WDM-operation context, and provides performance predictions based on current best-of-class silicon photonic devices. The key results of the analysis are the determination of upper bounds on the aggregate achievable communication bandwidth per link, identifying design trade-offs for bandwidth versus power efficiency, and highlighting the need for continued technological improvements in both laser as well as photodetector technologies to allow acceptable power efficiency operation of such systems.The third chapter, while continuing on the theme silicon photonic high bandwidth density links, proceeds to detail the first experimental demonstration and characterization of an on-chip spatial division multiplexing (SDM) scheme based on microrings for the multiplexing and demultiplexing functionalities. In the context of more forward looking optical network-on-chip environments, SDM-enabled WDM photonic interconnects can potentially achieve superior bandwidth densities per waveguide compared to WDM-only photonic interconnects. The microring-based implementation allows dynamic tuning of the multiplexing and demultiplexing characteristic of the system which allows operation on WDM grid as well device tuning to combat intra-channel crosstalk. The characterization focuses on the first reported power penalty measurements for on-chip silicon photonic SDM link showing minimal penalties achievable with 3 spatial modes concurrently operating on a single waveguide with 10-Gb/s data carried by each mode. The chapter also details the first demonstration of WDM combined with SDM operation with six separate wavelength-and-spatial 10-Gb/s channels with error free operation and low power penalties. The fourth, fifth, and sixth chapters shift in topic from the application of silicon photonics to communication links to the evolving use of silicon waveguides for nonlinear all-optical processing. The unique tight mode confinement in sub-micron cross-sections combined with the high response of silicon have motivated the development of four-wave mixing (FWM)-based processing silicon devices. The key feature of the silicon platform for these nonlinear processing platforms is the ability to finely and uniformly control the dispersive properties of the optical structures in a way that enables completely offsetting the material dispersion and achieve dispersion profiles required for effective parametric interaction of waves in the optical structures. Chapter four primarily introduces and motivates nonlinear processing in communication applications and focuses on recent achievements in non-silicon and silicon FWM platforms. Chapter five describes some of the author's contributions on parametric processing of high speed data in silicon nonlinear devices, with first of a kind demonstrations of wavelength conversion of 160-Gb/s optically time division multiplexed (OTDM) data as well as the wavelength-multicasting of a 320-Gb/s OTDM stream. The chapter then details a methodical characterization and demonstration of several record wavelength conversion experiments of data in silicon with 40-Gb/s data wavelength-converted across more than 100 nm with only 1.4-dB of power penalties as well as the wavelength and format conversion of 10-Gb/s data across up to 168 nm with sensitivity gains stemming from the format conversion of about 2 dB and a residual conversion penalty of only 0.1 dB, achieved by implementing an improved experimental setup. Both experiments highlight the performance uniformity of the conversion process for a wide range of probe-idler detuning settings, showcasing the silicon platform's unique broadband phase matching properties. The sixth chapter presents a slight shift in motivation for parametric processing from traditional telecom-wavelength applications to functionalities developed targeting mid-IR operation. Parametric-processing in the silicon platform at long wavelengths holds large potential for performance improvements due to the elimination of two-photon absorption in silicon at long wavelengths as well as silicon's dispersion engineering capabilities which uniquely position the silicon platform for effective phase matching of significantly wavelength detuned waves. Four-wave mixing signal generation and reception at mid-IR wavelengths are attractive candidates for tunable flexible operation with modulation and detection speeds which are currently only available at telecom wavelengths. With this vision in mind, several contributions detailing extension of FWM functionalities in silicon to operate at wavelengths close to 2 μm with performance equivalent to much smaller detuning setting measurements. The contributions detail the experimental demonstration of the first silicon optical processing functionalities achieved at such long wavelengths including the wavelength conversion and unicast of 10-Gb/s signals with up to 700 nm of probe-idler detuning, the combined two-stage 10-Gb/s FWM-link in which both data generation and detection at 1900 nm is facilitated by parametric processing in silicon with only 2.1-dB overall penalty, the first ever 40-Gb/s receiver at 1900 nm based on a FWM stage for simultaneous temporal demultiplexing and wavelength conversion, and lastly, the demonstration of a 40-Gb/s FWM-link operation with only 3.6 dB of penalty. The chapter concludes with a short discussion on possible extensions to enable silicon parametric processing at even longer wavelengths targeting the mid-IR spectral transmission window of 3-5 μm

Photonic Integrated Semiconductor Optical Amplifier Switch Circuits

No abstract

Subsystems for High bit-rate Optical Networks

Questa tesi contiene parte del lavoro svolto negli ultimi tre anni presso i laboratori congiunti del CNIT e della la Scuola Superiore Sant'Anna di Pisa, dove ho lavorato nel gruppo di Sistemi Ottici sotto la supervisione del prof. Ernesto Ciaramella, ed in parte presso il Dipartimento di Fisica dell'Università di Pisa, sotto la supervisione del prof. Niccolò Beverini. Durante questi anni ho avuto l'opportunità di lavorare su vari filoni di ricerca (studio di sorgenti laser impulsate, esperimenti di processamento dei segnali tutto ottico, sistemi di protezione dei guasti di rete,...) inquadrati in differenti progetti di ricerca, ed anche in Università straniere (Massachussetts Intitute of Technology MIT di Boston, USA). In questa tesi verrà comunque descritta solo una parte dei risultati sviluppati. In particolare, verrà discussa la ricerca svolta mirata alla realizzazione di sotto-sistemi che possono essere impiegati nei sistemi di comunicazione ottica (o, più in generale nelle Reti Ottiche) basate su trassmissioni di dati alla frequenza di cifra di 40 Gb/s. Ogni sottos-sistema sarà presentato seguendo un ordine che riproduce quello in cui questi sotto-sistemi sono impegati effettivamente: inizierò descrivendo una sorgente di impulsi ottici ad altissimo bit-rate da impiegare nei sistemi ottici multiplati a divisione di tempo (OTDM); si passerà poi alla descrizione di vari convertitori di lunghezza d'onda che sono utilizzati nei nodi di rete; per concludere, verrà discussa una unità tutta ottica per i recupero del sincronisimo, che è tipicamente impiegata alla fine di un sistema di trasmissione ed è usata per affiancare i ricevitori veri e propri. Tutte queste funzionalità sfruttano le proprietà ottiche non lineari di dispositivi tra i più comunemente usati nei sistemi di comunicazione ottici: le fibre ottiche e gli amplificatori ottici a semiconduttore. Oltre che dalla natura "tutto-ottica", tutti questi dispositivi (o funzionalità) sono accumunati dalla ricerca di semplicità sia realizzativa che progettuale: come verrà mostrato caso per caso, ogni sotto-sistema è stato realizzato cercando di ricorrere al minor numero possibile di dispositivi per ridurre la complessità globale. Questo è un punto fondamentale per dimostrare che le tecnologie "tutto-ottiche" possono rappresentare un'alternativa all'elettronica. Ogni "sotto-sistema" verrà trattato separatamente in un capitolo. Ogni capitolo contiene una breve discussione sulle novità introdotte, rispetto a soluzioni simili presentate in letteratura o in commercio. Benchè il lavoro riportato in questa tesi è essenzialmente di carattere sperimentale, per migliorarne la comprensione e la completezza ogni capitolo contiene dei paragrafi in cui l'argomento viene illustrato dal punto di vista teorico. La tesi è divisa in 4 capitoli secondo lo schema seguente: Una panoramica sui sistemi di comunicazione basati su fibra ottica: un capitolo introduttivo per spiegare l'evoluzione e la struttura e possibili scenari delle Reti Ottiche ed introdurre i motivi fondanti della ricerca riportata nella tesi. Una sorgente solitonica, nel capitolo 2. Questo capitolo contiene una discussione sulla progettazione e la realizzazione di una sorgente laser da impiegare in sistemi OTDM. La sorgente è progetatta per produrre impulsi di durata inferiore al picosecondo ad una frequenza di ripetizione di 40 GHz repetition rate. La sorgente è studiata per essere utilizzata direttamente nei sistemi di comunicazione, senza la necessità di dover ricorrere a stadi di processamento successivi (come la risagomatura degli impulsi, la loro compressione o la rimozione di piedistallo). Gli impulsi sono generati tramite un fenomeno di propagazione in regime non-lineare controllato in una fibra ottica particolare. Benchè la sorgente sia stata progettata per essere impiegata in sistemi OTDM, dato il suo spettro ottico largo e periodico potrebbe essere utilizzata anche in altri ambiti, come verrà discusso più volte nel corso della tesi. Esperimenti di conversione di lunghezza d'onda (includendo anche espeimenti di conversione di lunghezza d'onda multipla), nel capitolo 3. In questo capitolo, la conversione di lunghezza d'onda (ovvero il trasferimento della modulazione contenuta su un segnale ottico ad uno su una portante a lughezza d'onda differente) è dimostrata attraverso diverse tecniche, principalmente ricorrendo alle dinamiche veloci non-lineari deli amplificatori a semiconduttore. In tutti questi esperimenti, verrà trattata in dettaglio anche la realizzazione della conversione di lunghezza d'onda simultaneamente su più canali: in particolare questa funzionalità è ritenuta molto importante per le reti di accesso di prossima generazione.. Uno circuito tutto ottico per l'estrazione del segnale di sincronia da un segnale modulato nel capitolo 4. Lo schema presentato in questo capitolo per i recupero del sincronismo rappresenta un notevole passo in avanti rispetto ai circuiti presentati precedentemente in letteratura, sia in termini di efficienza che di compattezza. Il dispositivo è basato sull'implementazione tutta-ottico del Tank-Circuit (largamente utilizzato in elettronica). Questo circuito si è dimostrato molto versatile: in particolare è stato dimostrato il suo impiego con diversi formati di modulazione, sia con traffico continuo che a pacchetti. Il circuito inoltre è adatto per un'integrazione fotonica ibrida

Dynamic bandwidth allocation for all-optical wide-area networks

International audienceNous proposons une architecture pour un réseau WAN tout-optique basée sur la notion de connexions optiques multipoint à multipoint, que nous appelons multipaths. L'ensemble des noeuds d'accès est partitionné en groupements pour l'émission et la réception. Une (ou plusieurs) longueur d'onde est allouée à chaque paire groupement-source groupement-destination. Les noeuds d'un même groupement-source se partagent la capacité de cette longuer d'onde selon un protocole MAC adapté. Les données transmises sur une longueur d'onde sont diffusées à tous les noeuds du groupement-destination, et chaque récepteur extrait alors les données qui lui sont destinées à partir du flux reçu. Le réseau que nous proposons ne nécessite que des composants existants et se compare favorablement en termes de complexité et d'efficacité énergétique à des solutions alternatives comme la commutation optique par paquet (Optical Packet Switching - OPS) ou la commutation optique par rafale (Optical Burst Switching - OBS). Nous présentons d'abord l'architecture multipath et comparons sa consommation d'énergie celle d'un réseau classique à base de routeurs. Nous proposons ensuite un algorithme d'allocation dynamique de la bande passante. Nous évaluons la performance de l'algorithme proposé à l'aide de simulations et nous montrons que notre solution permet d'atteindre d'excellentes performances en terme de délai et temps de réponse

An investigation into an all-optical 1x2 self-routed optical switch using parallel optical processing

Dissertation (MEng (Electronic Engineering))--University of Pretoria, 2007.A unique all-optical 1x2 self-routed switch is introduced. This switch routes an optical packet from one input to one of two possible outputs. The header and payload are transmitted separately in the system, and the header bits are processed in parallel thus increasing the switching speed as well as reducing the amount of buffering required for the payload. A 1x2 switching operation is analysed and a switching ratio of up to 14dB is obtained. The objective of the research was to investigate a unique all-optical switch. The switch works by processing the optical bits in a header packet which contains the destination address for a payload packet. After the destination address is processed the optical payload packet gets switched to one of two outputs depending on the result of the optical header processing. All-optical packet switching in the optical time domain was accomplished by making use of all-optical parallel processing of an optical packet header. This was demonstrated in experiments in which a three bit parallel processing all-optical switching node was designed, simulated and used to successfully demonstrate the concept. The measure of success that was used in the simulated experiments was the output switching ratio, which is the ratio between the peak optical power of a high bit at the first output and the peak optical power of a high bit at the second output. In all experimental results the worst case scenario was looked at, which means that if there was any discrepancy in the peak value of the output power then the measurement’s minimum/maximum value was used that resulted in a minimum value for the switching ratio. The research resulted in an optical processing technique which took an optical bit sequence and delivered a single output result which was then used to switch an optical payload packet. The packet switch node had two optical fibre inputs and two optical fibre outputs. The one input fibre carried the header packet and the other input fibre carried the payload packet. The aim was to switch the payload packet to one of the two output fibres depending on the bit sequence within the header packet. Also only one unique address (header bit sequence) caused the payload packet to exit via one of the outputs and all the other possible addresses caused the payload packet to exit via the other output. The physical configuration of the all-optical switches in the parallel processing structure of the switching node determined for which unique address the payload packet would exit via a different output than when the address was any of the other possible combinations of sequences. Only three Gaussian shaped bits were used in the header packet at a data rate of 10 Gbps and three Gaussian shaped bits in the payload packet at a data rate of 40 Gbps, but in theory more bits can be used in the payload packet at a decreased bit length to increase throughput. More bits can also be used in the header packet to increase the number of addresses that can be reached. In the simulated experiments it was found that the payload packet would under most circumstances exit both outputs, and at one output it would be much larger than at the other output (where it was normally found to be suppressed when compared to the other output’s optical power). The biggest advantage of this method of packet-switching is that it occurs all-optically, meaning that there is no optical to electronic back to optical conversions taking place in order to do header processing. All of the header processing is done optically. One of the disadvantages is that the current proposed structure of the all-optical switching node uses a Cross-Gain Modulator (XGM) switch which is rather expensive because of the Semiconductor Optical Amplifier (SOA). In this method of packet-switching the length of the payload packet cannot exceed the length of one bit of the header packet. This is because the header processing output is only one header bit length long and this output is used to switch the payload packet. Thus any section of the payload packet that is outside this header processing output window will not be switched correctlyElectrical, Electronic and Computer Engineeringunrestricte

Novel linear and nonlinear optical signal processing for ultra-high bandwidth communications

The thesis is articulated around the theme of ultra-wide bandwidth single channel signals. It focuses on the two main topics of transmission and processing of information by techniques compatible with high baudrates. The processing schemes introduced combine new linear and nonlinear optical platforms such as Fourier-domain programmable optical processors and chalcogenide chip waveguides, as well as the concept of neural network. Transmission of data is considered in the context of medium distance links of Optical Time Division Multiplexed (OTDM) data subject to environmental fluctuations. We experimentally demonstrate simultaneous compensation of differential group delay and multiple orders of dispersion at symbol rates of 640 Gbaud and 1.28 Tbaud. Signal processing at high bandwidth is envisaged both in the case of elementary post-transmission analog error mitigation and in the broader field of optical computing for high level operations (“optical processor”). A key innovation is the introduction of a novel four-wave mixing scheme implementing a dot-product operation between wavelength multiplexed channels. In particular, it is demonstrated for low-latency hash-key based all-optical error detection in links encoded with advanced modulation formats. Finally, the work presents groundbreaking concepts for compact implementation of an optical neural network as a programmable multi-purpose processor. The experimental architecture can implement neural networks with several nodes on a single optical nonlinear transfer function implementing functions such as analog-to-digital conversion. The particularity of the thesis is the new approaches to optical signal processing that potentially enable high level operations using simple optical hardware and limited cascading of components