6 research outputs found
Advanced high speed data and clock transmission over optical fibre for square kilometre telescope array
Get PDFThere is an ever present need from Internet users for more bandwidth. This is manifested by continuous increase in bandwidth demanding applications such as 5G wireless, new end user consumer links like thunderbolt, video conferencing, high definition video-on-demand transmitted over the Internet and massive data transfers required with and within data centres for backup, storage and data processing in cloud computing. Fibre optic communications technologies are playing a pivotal role in communication, being a major enabling technology in our increasingly Internet-centric society. As network services continue to become more dynamic and diverse, Internet service providers are faced with a challenge of cost reduction in the transmission network, power and spectral efficiency as well as scalability of the optical network infrastructure to support incremental expansions and virtual machines. Intelligent design of terrestrial optical networks to allow for simultaneous signal transmission through shared network infrastructure, and the use of low cost, power efficient, high bandwidth transmitters such as vertical surface emitting lasers (VCSELs) as well as exploitation of spectral efficient in-complex advanced modulation formats is a viable approach to this situation. In this study, techniques for spectral efficiency upgrade and simultaneous transmission of data signal, reference frequency (RF) clock signal and pulse-per-second (PPS) over shared infrastructure have experimentally been optimized in a laboratory environment for adoption in next-generation telescope array networks such as the Square Kilometre Array (SKA), time keeping systems such as banking systems, Coordinated Universal Time(UTC) timing and Global Positioning Systems (GPS), as well as high capacity spectral efficient short reach optical fibre networks such as data centres. This work starts by experimentally optimizing VCSEL technology for simultaneous transmission of 10 Gbps data and 1.712 GHz RF clock signal over a single G. 655 optical fibre of length 24.75 Km at different channel spacing and different propagation direction for implementation in a cost effective next-generation telescope array network. The wavelength tuneability property of VCSEL transmitters allows for wavelength adjustment, a key requirement for simultaneous data and RF clock signal transmission over a single optical fibre. A receiver sensitivity of -19.19 dBm was experimentally achieved at back-to-back analysis. A 24.75 Km of simultaneous data and RF clock signal transmission performed at 0.4 nm channel spacing introduced a transmission penalty of 1.07 dB and 1.63 dB for counter and co-propagation scheme respectively. This work mainly utilized direct modulation and direct detection using a positive intrinsic negative (PIN) due to its simplicity and cost effectiveness. A novel modulation technique for simultaneous data and polarization-based pulse-per-second timing clock signal transmission using a single VCSEL carrier is experimentally demonstrated. Two signal types, a directly modulated 10 Gbps data signal and a polarization-based pulse per second (PPS) clock signal are modulated onto a single mode 10 GHz bandwidth VCSEL carrier at 1310 nm. Spectral efficiency is maximized by exploiting the inherent orthogonal polarization switching of the xiv VCSEL with changing bias in transmission of the PPS signal. A 10 Gbps VCSEL transmission with PPS over 11 Km of G.652 fibre introduced a transmission penalty of 0.52 dB. The contribution of PPS clock signal to this penalty was found to be 0.08 dB. A technique for simultaneous directly modulated data and phase modulated reference clock signal transmission over a signal channel in wavelength division multiplexing (WDM) solutions is experimentally demonstrated. This is to prepare solutions to the ever-increasing demand over gigabit/s, terabit/s and gigahertz capacities in WDM-based terrestrial optical fibre transmission systems such as telescope array networks. a total capacity of 30 Gbps (310 Gbps) data and 12 GHz ( 4 3 GHz) reference clock signal are multiplexed at a channel spacing of 100 GHz and simultaneously transmitted over a single mode G.655 fibre of length 24.73 Km. The recovery of the phase modulated RF clock signal using a differential delay line interferometry technique is experimentally demonstrated. A 625 Gbps (2525 Gbps) DWDM data transmission system is further implemented in simulation by multiplexing 25 channels at 25 Gbps per channel using 50 GHz channel spacing. A four level pulse amplitude modulation (4-PAM) data modulation format employing VCSELs is experimentally demonstrated for adoption in high bitrate networks such as big data science projects and data centre networks. 4-PAM offers a good trade-off between complexity, efficiency, reach, and sensitivity. A software defined digital signal processing (DSP) receiver is designed and implemented in MATLAB to recover the transmitted 4-PAM data signal cost effectively without the necessity of costly receiver hardware. A novel technique for maximizing carrier spectral efficiency through simultaneous 20 Gbps 4-PAM data and phase modulated 2 GHz RF clock signal transmission on a single mode 10 GHz bandwidth VCSEL carrier at 1310 nm is experimentally demonstrated for the first time to the best of our knowledge. Data transmission and clock stability performance of the designed high spectral efficient VCSEL-based link network is evaluated through BER curve plots, phase noise measurements and Allan variance analysis respectively. VCSEL-based Raman amplification is experimentally demonstrated as a viable approach for RF clock signal distribution in extended reach astronomical telescope array networks and other extended reach terrestrial optical fibre network application. This is achieved by adopting two pumping techniques namely forward pumping and backward pumping. A maximum on off gain of 5.7 dB and 1.5 dB was experimentally attained for forward pumping and backward pumping at 24 dBm pump power respectively, while a maximum 100.8 Km fibre transmission achieved experimentally. In summary, this study has successfully demonstrated in-complex, spectral efficient, low cost and power efficient simultaneous data signal, reference frequency (RF) clock signal and pulse-per-second (PPS) transmission techniques over shared network infrastructure. Simultaneous transmission of data, RF clock and PPS timing signal is relevant in nextgeneration telescope array networks such as the Square Kilometre Array (SKA), time keeping systems such as banking systems, Coordinated Universal Time (UTC) timing and Global Positioning Systems (GPS), as well as high capacity spectral efficient short reach optical fibre networks such as data centres
100 Gbps/位 PON downstream O- And C-band alternatives using direct-detection and linear-impairment equalization [Invited]
Get PDFThe future-generation passive optical network (PON) physical layer, targeting 100 Gbps/wavelength, will have to deal with severe optoelectronics bandwidth and chromatic dispersion limitations. In this paper, largely extending our Optical Fiber Communication Conference (OFC) 2020 invited paper, we review 100 Gbps/wavelength PON downstream alternatives over standard single-mode fiber in the O- and C-bands, analyzing three modulation formats (PAM-4, partial-response PAM-4, and PAM-8), two types of direct-detection receivers (APD- and SOA + PIN-based), and three digital reception strategies (unequalized, feed-forward equalized, and decision-feedback equalized). We evaluate by means of simulations the performance of these alternatives under different optoelectronics bandwidth and dispersion scenarios, identifying O-band feasible solutions able to reach 20 km of fiber and an optical path loss of at least 29 dB over a wide wavelength range of operation. Finally, we compare two digitally precompensated modulation schemes that are highly tolerant of chromatic dispersion, showing a possible extension to C-band operation, preserving direct-detection and linear-impairment equalization at the optical network unit side
Next generation technologies for 100 Gb/s PON systems
Get PDFThe worldwide explosion of Internet traffic demand is driving the research for innovative solutions in many aspects of the telecommunication world. In access systems, passive optical networks (PONs) are becoming the preferred solution towards which most providers are migrating thanks to the unrivalled bandwidth they can offer. PON systems with a capacity of 100 Gb/s are envisioned as the solution to the dramatic increase in bandwidth and will be essential to support the future fixed and mobile broadband services. However, many challenging aspects have to be addressed in order to overcome the limitations imposed by the physical layer while meeting the economical requirements for mass deployment. In this thesis a comprehensive approach is taken in order to address the most compelling problems and investigate a series of solutions to the current capacity limitations of PONs. Advanced modulation formats are used to achieve bit-rate enhancement from 10 Gb/s to 25 Gb/s re-using the same optoelectronic devices in order to provide a 2.5x increase in transmission speed without resorting to a newer, more expensive generation of higher speed devices. The management of chromatic dispersion is also addressed in order to extend the reach of the networks beyond the standard 20 km using either electronic or optical based compensation strategies. Transmission of 25 Gb/s traffic over fibre lengths of 40 and 50 km is demonstrated confirming the suitability of the proposed technologies for extended reach networks which could greatly reduce the number of existing nodes and hence the capital and operational costs of PONs. Optical amplification strategies are also discussed as a means to improve the physical reach of the networks, both in terms of distance and number of customers. Raman amplifiers and semiconductor optical amplifiers are investigated in order to extend the reach of a PON upstream channel. The results demonstrate a reach of up to 50 km which is more than double the typical fibre length of 20 km adopted in deployed systems today. A number of customers, up to 512, was also demonstrated in a 20 km network, increased from the typical 32 or 64 users of most commercial networks
Directly Phase Modulated Transmitters and Coherent Recivers for Future Passive Optical Networks (PON)
Get PDFEn los 煤ltimos a帽os, el tr谩fico de dato transmitido en las redes 贸pticas de acceso ha crecido exponencialmente debido a nuevos servicios como pueden ser la computaci贸n en la nube, el video online, la realidad virtual y aumentada, el internet de las cosas (IoT) y la convergencia entre las redes 贸pticas y redes inal谩mbricas en el paradigma del 5G. Estos nuevos servicios endurecen los requerimientos de las redes 贸pticas de acceso, como pueden ser unas tasas de datos m谩s altas, un mayor alcance y un mayor n煤mero de usuarios. Para abordar estos requerimientos, esta tesis ha investigado, desarrollado y analizado nuevas tecnolog铆as para transmisores y receptores orientadas a los dos tipos de redes 贸pticas de acceso que la comunidad cient铆fica ha identificado como posibles candidatas. Estos dos tipos de redes 贸pticas son las redes uDWDM y las redes TWDM como las redes NG-PON2 y sus evoluciones.Las redes uDWDM est谩n basadas en la transmisi贸n de tasas de datos relativamente bajas, por debajo de 2.5 Gbps, que son dedicadas en su totalidad a los usuarios finales. Estas tasas de datos relativamente bajas son multiplexadas en longitud de onda usando intervalos frecuenciales estrechos, del orden de 12.5 GHz o 6.25 GHz. En esta tesis, los transmisores modulados directamente en fase se han propuesto como posibles candidatos para estas redes uDWDM. En concreto, se han propuesto un DFB modulado directamente en fase con una tasa de datos de 1 Gbps; un RSOA bombeado por un VCSEL y modulado directamente en fase con una tasa de datos de 1 Gbps; y un VCSEL modulado directamente en fase con una tasa de datos de 1.25 Gbps y 2.5 Gbps. Estas se帽ales moduladas directamente en fase son recibidas con un receptor heterodino con un 煤nico fotodiodo (PD) para mantener el coste tan bajo como sea posible. La combinaci贸n de estos transmisores modulados directamente en fase con el receptor heterodino con un 煤nico PD ha sido probada como unos candidatos muy prometedores para las redes 贸pticas de acceso basadas en redes uDWDM. Estas combinaciones proveen sensibilidades que var铆an entre -39.5 dBm y -52 dBm, que se traducen en balances de potencia que van desde 38.5 dB a 51 dB y por lo tanto en ratios de divisi贸n o n煤mero de usuarios de entre 128 y 1024 despu茅s de una transmisi贸n de 50 km a trav茅s de fibra monomodo est谩ndar (SSMF).Adem谩s, los links de 1 Gbps formados por la modulaci贸n directa de DFBs o de RSOAs bombeados por VCSELs y el receptor heterodino con un 煤nico PD son usados como enlace de subida en canales bidireccionales. Estos enlaces de subida son combinados con enlaces de bajada basados en Nyquist-DPSK generada con un MZM y recibidos con un receptor heterodino de un 煤nico PD. Como parte de an谩lisis de los canales bidireccionales, se ha analizado el estudio de la viabilidad del uso de LOs de bajo coste, como DFBs o VCSELs, en los receptores heterodinos con un 煤nico PD. Estos canales bidireccionales son tambi茅n unos candidatos prometedores para las futuras redes uDWDM, ya que en esta tesis se ha probado que pueden proveer enlaces full-duplex de 1 Gbps usando intervalos frecuenciales tan peque帽os como 6.25 GHz o 5 GHz. Estos canales bidireccionales tienen balances de potencia que van desde 37 dB a 42 dB y tienen posibles ratios de divisi贸n de 128 o 256 despu茅s de una transmisi贸n de 50 km a trav茅s de SSMF.Esta tesis tambi茅n ha investigado y desarrollado receptores quasicoherentes para redes NG-PON2 y sus evoluciones. Este tipo de redes est谩n basadas en altas tasas de datos, como 10 Gbps para redes NG-PON2 y 25 Gbps para las futuras evoluciones de NG-PON2, en entornos multi longitud de onda donde los usuarios son multiplexados en tiempo y longitud de onda (TWDM). El receptor quasicoherente usa la amplificaci贸n coherente gracias a la recepci贸n heterodina y por tanto la sensibilidad del receptor es mejorada en comparaci贸n con los esquemas de detecci贸n directa. El receptor quasicoherente es independiente a la polarizaci贸n, lo cual es una caracter铆stica importante para los receptores coherentes. Adem谩s, el receptor quasicoherente permite seleccionar el canal de trabajo sin la necesidad de filtros 贸pticos y es un receptor independiente de la longitud de onda debido a que el canal de trabajo se puede elegir ajustando la longitud de onda del LO. El receptor quasicoherente de 10 Gbps muestra una sensibilidad -35.2 dBm y por tanto permite un balance de potencias de 35.64 dB y un ratio de divisi贸n de 128 despu茅s de una transmisi贸n de 40 km a trav茅s de SSMF.La combinaci贸n del receptor quasicoherente con un ecualizador FFE/DFE permite combatir la dispersi贸n crom谩tica de la banda C y conseguir un link de 25 Gbps con un alcance de 20 km a trav茅s de SSMF. El receptor quasicoherente a 25 Gbps con ecualizaci贸n FFE/DFE muestra una mejor sensibilidad de -30.5 dBm con el llamado ecualizador de altas prestaciones, lo que lleva a un balance de potencias de25 dB. Si se utilizada el llamado ecualizador de baja complejidad, la sensibilidad cae a -27 dBm y el balance de potencias cae a 23 dBm. En ambos casos, el receptor quasicoherente a 25 Gbps con ecualizaci贸n FFE/DFE permite un ratio de divisi贸n de 32 despu茅s de una transmisi贸n de 20 km a trav茅s de SSMF.En conclusi贸n, esta tesis ha presentado transmisores (DFB, RSOA y VCSEL) modulados directamente en fase combinados con un receptor heterodino con un 煤nico PD como potenciales candidatos para las redes uDWDM. Esta tesis tambi茅n ha presentados los receptores quasicoherentes como unos candidatos muy prometedores para las redes NG-PON2 y sus futuras evoluciones.<br /
Next generation optical access networks and coexistence with legacy PONs
Get PDFNowadays, Fiber-to-the-Home is one of the most promising solutions to provide broadband services in access networks. However, the fiber is inefficiently used as most of the deployed systems are still based on Time Division Multiplexing Passive Optical Networks (TDM-PONs) providing shared transmission capacities up to 2.5 Gb/s down and 1.25 Gb/s up, among multiple users. Research on high-speed electronics and Wavelength Division Multiplexing (WDM) has allowed the emergence of what is known as the second generation PON (NG-PON2), which specify aggregated capacities up to 40 Gb/s, stacking four channels at symmetric data rates of 10 Gb/s each, for residential scenarios. Nevertheless, the capacity per channel is still shared between multiple users due to the use of TDM. Moreover, the optical spectrum efficiency is low because channels are widely spaced (50 to 100 GHz). In addition, the sensitivity, reach and number of users is limited as consequence of using direct detection (DD) systems. In consequence, and due to the increase in bandwidth demands of new multimedia applications, it is necessary to propose solutions that cope with this tendency and, even more important, that can coexist with legacy systems, being one of the major requirements of network operators to guarantee a smooth and non-disruptive technology migration.
In this thesis, a breakthrough technology such as Ultra-Dense WDM (UDWDM) that allows to allocate a large number of channels spaced only by a few GHz is used. This approach consent to envision the concept of Wavelength-to-the-User, where each costumer can be served with dedicated bandwidth links. The key technologies are based on coherent systems, with inherent wavelength selectivity and improved sensitivity compared to DD systems, thanks to the booster action of a tunable local oscillator (LO) laser.
Because of cost is the main constraint in access networks, especially at the customer premises equipment (Optical Network Unit - ONU), in this thesis, a new class of coherent transceivers, based on low-cost direct modulated lasers and simplified receiver schemes, are proposed and experimentally tested. Moreover, the issue of coexistence is investigated through theoretical studies and real-time implementations, demonstrating full compatibility with legacy systems.
Between the proposed solutions, a simple technique to adjust digitally the direct phase modulation of a distributed feedback (DFB) laser is presented to support flexible transmission rates. Next, several multilevel phase modulation formats for achieving higher transmission rates and better spectral efficiency are experimentally compared. Subsequently, the topic of photonic integration is addressed, demonstrating for the first time an 8-ary hybrid amplitude and phase modulated transmitter (Tx), by using a low-cost, small-footprint and energy efficient dual electro-absorption modulated laser (DEML). Finally, two novel proposals, to reduce the complexity of heterodyne and intradyne detection, are provided to face the typical issue of complexity and high-cost of coherent systems. The former explores the possibility of using only one DFB laser as LO and Tx at the ONU. The later demonstrates for the first time, a novel phase time diversity technique alternating phase modulation at each complex component (in-phase - I and quadrature - Q) achieving a 10 Gb/s' transmission with polarization independence.En la actualidad, la Fibra hasta el Hogar es una de las soluciones m谩s prometedoras para proporcionar servicios de banda ancha en las redes de acceso. Sin embargo, la fibra se usa de manera poco eficiente, ya que la mayor铆a de los sistemas implementados todav铆a est谩n basados en redes 贸pticas pasivas de multiplexaci贸n por divisi贸n en el tiempo (TDM-PON) que brindan capacidades de transmisi贸n compartidas entre m煤ltiples usuarios de hasta 2.5 Gb/s y 1.25 Gb/s. La investigaci贸n en electr贸nica de alta velocidad y la multiplexaci贸n por divisi贸n de longitud de onda (WDM) ha permitido el surgimiento de lo hoy se conoce como PON de segunda generaci贸n (NG-PON2), que especifica capacidades agregadas de hasta 40 Gb/s, apilando cuatro canales a velocidades de datos sim茅tricas de 10 Gb/s cada uno, para escenarios residenciales. Sin embargo, la capacidad por canal todav铆a se comparte entre m煤ltiples usuarios debido al uso de TDM. Adem谩s, la eficiencia en el uso del espectro 贸ptico es baja porque los canales est谩n muy separados (50 a 100 GHz). Asimismo, la sensibilidad, el alcance y el n煤mero de usuarios est谩n limitados debido al uso de sistemas de detecci贸n directa. En consecuencia, y debido al aumento de las demandas de ancho de banda de las nuevas aplicaciones multimedia, es necesario proponer soluciones que respondan a esta tendencia y, lo que es m谩s importante, que puedan coexistir con sistemas heredados, siendo uno de los principales requisitos de los operadores de red para garantizar una migraci贸n de tecnolog铆a fluida y sin interrupciones. En esta tesis, se utiliza una tecnolog铆a de vanguardia, como la multiplexaci贸n por divisi贸n ultra densa de longitud de onda (UDWDM) que permite distribuir un gran n煤mero de canales espaciados solo por unos pocos GHz. Este enfoque permite vislumbrar el concepto de longitud de onda para el usuario, donde cada cliente puede usar enlaces de ancho de banda dedicados. Las tecnolog铆as clave est谩n basadas en los sistemas coherentes, con selectividad de longitud de onda inherente y sensibilidad mejorada en comparaci贸n con los sistemas de detecci贸n directa, gracias al efecto de amplificaci贸n 贸ptica de un l谩ser oscilador local (LO) sintonizable. Debido a que el costo es la principal restricci贸n en las redes de acceso, especialmente del equipo en las instalaciones del cliente (unidad de red 贸ptica - ONU), en 茅sta tesis, una nueva clase de transceptores coherentes, basados en l谩seres de bajo coste modulados directamente y esquemas de recepci贸n simplificados, son propuestos y probados experimentalmente. Adem谩s, el problema de la coexistencia es investigado a trav茅s de estudios te贸ricos y experimentos en tiempo real, demostrando compatibilidad total con los sistemas heredados. Entre las soluciones propuestas, se presenta una t茅cnica simple para ajustar digitalmente la modulaci贸n de fase directa de un l谩ser de retroalimentaci贸n distribuida (DFB), y admitir velocidades de transmisi贸n flexibles. Acto seguido, se comparan experimentalmente varios formatos multinivel de modulaci贸n de fase, para lograr tasas de transmisi贸n m谩s altas y una mejor eficiencia espectral. Posteriormente, se aborda el tema de la integraci贸n fot贸nica, demostrando por primera vez un transmisor (Tx) con modulaci贸n h铆brida de fase y amplitud de ocho puntos, mediante el uso de un dispositivo peque帽o, de bajo coste y eficiente energ茅ticamente, como lo es el l谩ser dual de electro-absorci贸n modulada (DEML). Finalmente, se presentan dos propuestas novedosas para reducir la complejidad de la detecci贸n heterodina e intradina, afrontando el problema t铆pico de la complejidad y alto coste de los sistemas coherentes. La primera explora la posibilidad de usar solo un l谩ser DFB en la ONU, como LO y Tx. La segunda, demuestra por primera vez, una nueva t茅cnica de diversidad fase en el tiempo, que alterna la modulaci贸n de fase en cada componente del plano complejo (fase-I y cuadratura-Q) logrando una transmisi贸n de 10 Gb / s / 位 con independencia de polarizaci贸
Next generation optical access networks and coexistence with legacy PONs
Get PDFNowadays, Fiber-to-the-Home is one of the most promising solutions to provide broadband services in access networks. However, the fiber is inefficiently used as most of the deployed systems are still based on Time Division Multiplexing Passive Optical Networks (TDM-PONs) providing shared transmission capacities up to 2.5 Gb/s down and 1.25 Gb/s up, among multiple users. Research on high-speed electronics and Wavelength Division Multiplexing (WDM) has allowed the emergence of what is known as the second generation PON (NG-PON2), which specify aggregated capacities up to 40 Gb/s, stacking four channels at symmetric data rates of 10 Gb/s each, for residential scenarios. Nevertheless, the capacity per channel is still shared between multiple users due to the use of TDM. Moreover, the optical spectrum efficiency is low because channels are widely spaced (50 to 100 GHz). In addition, the sensitivity, reach and number of users is limited as consequence of using direct detection (DD) systems. In consequence, and due to the increase in bandwidth demands of new multimedia applications, it is necessary to propose solutions that cope with this tendency and, even more important, that can coexist with legacy systems, being one of the major requirements of network operators to guarantee a smooth and non-disruptive technology migration.
In this thesis, a breakthrough technology such as Ultra-Dense WDM (UDWDM) that allows to allocate a large number of channels spaced only by a few GHz is used. This approach consent to envision the concept of Wavelength-to-the-User, where each costumer can be served with dedicated bandwidth links. The key technologies are based on coherent systems, with inherent wavelength selectivity and improved sensitivity compared to DD systems, thanks to the booster action of a tunable local oscillator (LO) laser.
Because of cost is the main constraint in access networks, especially at the customer premises equipment (Optical Network Unit - ONU), in this thesis, a new class of coherent transceivers, based on low-cost direct modulated lasers and simplified receiver schemes, are proposed and experimentally tested. Moreover, the issue of coexistence is investigated through theoretical studies and real-time implementations, demonstrating full compatibility with legacy systems.
Between the proposed solutions, a simple technique to adjust digitally the direct phase modulation of a distributed feedback (DFB) laser is presented to support flexible transmission rates. Next, several multilevel phase modulation formats for achieving higher transmission rates and better spectral efficiency are experimentally compared. Subsequently, the topic of photonic integration is addressed, demonstrating for the first time an 8-ary hybrid amplitude and phase modulated transmitter (Tx), by using a low-cost, small-footprint and energy efficient dual electro-absorption modulated laser (DEML). Finally, two novel proposals, to reduce the complexity of heterodyne and intradyne detection, are provided to face the typical issue of complexity and high-cost of coherent systems. The former explores the possibility of using only one DFB laser as LO and Tx at the ONU. The later demonstrates for the first time, a novel phase time diversity technique alternating phase modulation at each complex component (in-phase - I and quadrature - Q) achieving a 10 Gb/s' transmission with polarization independence.En la actualidad, la Fibra hasta el Hogar es una de las soluciones m谩s prometedoras para proporcionar servicios de banda ancha en las redes de acceso. Sin embargo, la fibra se usa de manera poco eficiente, ya que la mayor铆a de los sistemas implementados todav铆a est谩n basados en redes 贸pticas pasivas de multiplexaci贸n por divisi贸n en el tiempo (TDM-PON) que brindan capacidades de transmisi贸n compartidas entre m煤ltiples usuarios de hasta 2.5 Gb/s y 1.25 Gb/s. La investigaci贸n en electr贸nica de alta velocidad y la multiplexaci贸n por divisi贸n de longitud de onda (WDM) ha permitido el surgimiento de lo hoy se conoce como PON de segunda generaci贸n (NG-PON2), que especifica capacidades agregadas de hasta 40 Gb/s, apilando cuatro canales a velocidades de datos sim茅tricas de 10 Gb/s cada uno, para escenarios residenciales. Sin embargo, la capacidad por canal todav铆a se comparte entre m煤ltiples usuarios debido al uso de TDM. Adem谩s, la eficiencia en el uso del espectro 贸ptico es baja porque los canales est谩n muy separados (50 a 100 GHz). Asimismo, la sensibilidad, el alcance y el n煤mero de usuarios est谩n limitados debido al uso de sistemas de detecci贸n directa. En consecuencia, y debido al aumento de las demandas de ancho de banda de las nuevas aplicaciones multimedia, es necesario proponer soluciones que respondan a esta tendencia y, lo que es m谩s importante, que puedan coexistir con sistemas heredados, siendo uno de los principales requisitos de los operadores de red para garantizar una migraci贸n de tecnolog铆a fluida y sin interrupciones. En esta tesis, se utiliza una tecnolog铆a de vanguardia, como la multiplexaci贸n por divisi贸n ultra densa de longitud de onda (UDWDM) que permite distribuir un gran n煤mero de canales espaciados solo por unos pocos GHz. Este enfoque permite vislumbrar el concepto de longitud de onda para el usuario, donde cada cliente puede usar enlaces de ancho de banda dedicados. Las tecnolog铆as clave est谩n basadas en los sistemas coherentes, con selectividad de longitud de onda inherente y sensibilidad mejorada en comparaci贸n con los sistemas de detecci贸n directa, gracias al efecto de amplificaci贸n 贸ptica de un l谩ser oscilador local (LO) sintonizable. Debido a que el costo es la principal restricci贸n en las redes de acceso, especialmente del equipo en las instalaciones del cliente (unidad de red 贸ptica - ONU), en 茅sta tesis, una nueva clase de transceptores coherentes, basados en l谩seres de bajo coste modulados directamente y esquemas de recepci贸n simplificados, son propuestos y probados experimentalmente. Adem谩s, el problema de la coexistencia es investigado a trav茅s de estudios te贸ricos y experimentos en tiempo real, demostrando compatibilidad total con los sistemas heredados. Entre las soluciones propuestas, se presenta una t茅cnica simple para ajustar digitalmente la modulaci贸n de fase directa de un l谩ser de retroalimentaci贸n distribuida (DFB), y admitir velocidades de transmisi贸n flexibles. Acto seguido, se comparan experimentalmente varios formatos multinivel de modulaci贸n de fase, para lograr tasas de transmisi贸n m谩s altas y una mejor eficiencia espectral. Posteriormente, se aborda el tema de la integraci贸n fot贸nica, demostrando por primera vez un transmisor (Tx) con modulaci贸n h铆brida de fase y amplitud de ocho puntos, mediante el uso de un dispositivo peque帽o, de bajo coste y eficiente energ茅ticamente, como lo es el l谩ser dual de electro-absorci贸n modulada (DEML). Finalmente, se presentan dos propuestas novedosas para reducir la complejidad de la detecci贸n heterodina e intradina, afrontando el problema t铆pico de la complejidad y alto coste de los sistemas coherentes. La primera explora la posibilidad de usar solo un l谩ser DFB en la ONU, como LO y Tx. La segunda, demuestra por primera vez, una nueva t茅cnica de diversidad fase en el tiempo, que alterna la modulaci贸n de fase en cada componente del plano complejo (fase-I y cuadratura-Q) logrando una transmisi贸n de 10 Gb / s / 位 con independencia de polarizaci贸nPostprint (published version
