Electronic dispersion precompensation of direct-detected NRZ using analog filtering

We demonstrate (in real-time) electrical dispersion compensation in direct detection links using analog transmit side filtering techniques. By this means, we extend the fiber reach using a low complexity solution while avoiding digital preprocessing and digital-to-analog converters (DACs) which are commonly used nowadays. Modulation is done using an IQ MachZehnder modulator (MZM) which allows straightforward compensation of the complex impulse response caused by chromatic dispersion in the fiber. A SiGe BiCMOS 5-tap analog complex finite impulse response (FIR) filter chip and/or a delay between both driving signals of the MZMs is proposed for the filter implementation. Several link experiments are conducted in C-band where transmission up to 60 km of standard single-mode fiber (SSMF) of direct detected 28Gb/s NRZ/OOK is demonstrated. The presented technique can be used in applications where low power consumption is critical

Compensação da não-linearidade do modulador-MZ-IQ baseada em FPGA

Mestrado em Engenharia Electrónica e TelecomunicaçõesNos últimos anos, a crescente necessidade de largura de banda e a evolução das técnicas de processamento digital de sinal renovaram o interesse pelos sistemas de comunicação ópticos coerentes. O modulador IQ assume-se como um componente chave nestes transmissores, sendo responsável pela conversão de informação do domínio eléctrico para o domínio óptico. Os moduladores Mach-Zehnder que constituem este dispositivo recebem sinais de drive com uma excursão controlada, garantindo a utilização de uma região aproximadamente linear das suas funções transferência e a geração de constelações sem distorções de fase. No entanto, existem vantagens em explorar a extensão completa da característica dos moduladores. Neste contexto, torna-se relevante efectuar um estudo acerca das técnicas de pré-distorção electrónica que permitem corrigir os efeitos das não-linearidades associadas a este método de transmissão. Esta dissertação foca-se no estudo da compensação dos impactos que a característica não-linear do modulador Mach-Zehnder tem nos sistemas de transmissão ópticos coerentes. Após a identificação e desenvolvimento de soluções matemáticas para o problema, realizaram-se vários testes utilizando um simulador integrado em ambiente MATLAB. Um sistema de transmissão coerente utilizando formatos de modulação QAM e os respectivos algoritmos de compensação foram posteriormente implementados em FPGA. Desenvolveram-se também co-simulações que permitiram garantir que o hardware concebido produzia os resultados desejados. Para além disso, realizaram-se vários testes utilizando um modulador IQ disponível no “Laboratório de Óptica” do Instituto de Telecomunicações de Aveiro. O objectivo consistiu em operar o sistema em condições laboratoriais e analisar o desempenho dos algoritmos de compensação em ambiente real.In recent years, the ever-increasing bandwidth demand and the evolution of digital signal processing techniques renewed the interest for the optical coherent systems. The IQ-Modulator is a key component in optical coherent transmitters, being responsible for the conversion of information from electrical to optical domain. The Mach-Zehnder modulators that compose this device receive driving signals with a controlled excursion, in order to use an approximately linear region of their transfer function and produce constellations without phase distortions. However, there are advantages in exploit the full range of the modulators’ characteristic. In this context, a study about the electronic predistortion techniques required to overcome the nonlinear effects associated to this transmission method becomes relevant. The subject of this dissertation is the compensation of impairments related to the nonlinear characteristic of the Mach-Zehnder Modulator in coherent optical transmission systems. After the identification and development of mathematical solutions for the problem, several tests were made using a simulator that runs in a MATLAB environment. A QAM coherent transmitter system and the compensation algorithm were then implemented in a FPGA platform. Co-simulations were performed in order to prove that the designed hardware was generating correct results. Furthermore, some tests were conducted using an IQ-Modulator available in the “Optics Laboratory” at Telecommunications Institute of Aveiro. The goal was to operate the system under laboratorial conditions and analyze the performance of the compensation algorithm in a real case scenario

Spectrally Efficient WDM Nyquist Pulse-Shaped 16-QAM Subcarrier Modulation Transmission With Direct Detection

The ability to transmit signals with high information spectral density (ISD) using low-complexity and cost-effective transceivers is essential for short- and medium-haul optical communication systems. Consequently, spectrally efficient direct detection transceiver-based solutions are attractive for such applications. In this paper, we experimentally demonstrate the wavelength-division multiplexed (WDM) transmission of 7×12 GHz-spaced dispersion pre-compensated Nyquist pulse-shaped 16-QAM subcarrier modulated channels operating at a net bit rate of 24 Gb/s per channel, and achieving a net optical ISD of 2.0 b/s/Hz. The direct detection receiver used in our experiment consisted of a single-ended photodiode and a single analog-to-digital converter. The carrier-to-signal power ratio at different values of optical signal-to-noise ratio was optimized to maximize the receiver sensitivity performance. The transmission experiments were carried out using a recirculating fiber loop with uncompensated standard single-mode fiber and EDFA-only amplification. The maximum achieved transmission distances for single channel and WDM signals were 727 and 323 km below the bit-error ratio of 3.8 × 10-3, respectively. To the best of our knowledge, this is the highest achieved ISD for WDM transmission in direct detection links over such distances

Advanced DSP Techniques for High-Capacity and Energy-Efficient Optical Fiber Communications

The rapid proliferation of the Internet has been driving communication networks closer and closer to their limits, while available bandwidth is disappearing due to an ever-increasing network load. Over the past decade, optical fiber communication technology has increased per fiber data rate from 10 Tb/s to exceeding 10 Pb/s. The major explosion came after the maturity of coherent detection and advanced digital signal processing (DSP). DSP has played a critical role in accommodating channel impairments mitigation, enabling advanced modulation formats for spectral efficiency transmission and realizing flexible bandwidth. This book aims to explore novel, advanced DSP techniques to enable multi-Tb/s/channel optical transmission to address pressing bandwidth and power-efficiency demands. It provides state-of-the-art advances and future perspectives of DSP as well

Revisiting Efficient Multi-Step Nonlinearity Compensation with Machine Learning: An Experimental Demonstration

Efficient nonlinearity compensation in fiber-optic communication systems is considered a key element to go beyond the "capacity crunch''. One guiding principle for previous work on the design of practical nonlinearity compensation schemes is that fewer steps lead to better systems. In this paper, we challenge this assumption and show how to carefully design multi-step approaches that provide better performance--complexity trade-offs than their few-step counterparts. We consider the recently proposed learned digital backpropagation (LDBP) approach, where the linear steps in the split-step method are re-interpreted as general linear functions, similar to the weight matrices in a deep neural network. Our main contribution lies in an experimental demonstration of this approach for a 25 Gbaud single-channel optical transmission system. It is shown how LDBP can be integrated into a coherent receiver DSP chain and successfully trained in the presence of various hardware impairments. Our results show that LDBP with limited complexity can achieve better performance than standard DBP by using very short, but jointly optimized, finite-impulse response filters in each step. This paper also provides an overview of recently proposed extensions of LDBP and we comment on potentially interesting avenues for future work.Comment: 10 pages, 5 figures. Author version of a paper published in the Journal of Lightwave Technology. OSA/IEEE copyright may appl

Digital electronic predistortion for optical communications

The distortion of optical signals has long been an issue limiting the performance of communication systems. With the increase of transmission speeds the effects of distortion are becoming more prominent. Because of this, the use of methods known from digital signal processing (DSP) are being introduced to compensate for them. Applying DSP to improve optical signals has been limited by a discrepancy in digital signal processing speeds and optical transmission speeds. However high speed Field Programmable Gate Arrays (FPGA) which are sufficiently fast have now become available making DSP experiments without costly ASIC implementation possible for optical transmission experiments. This thesis focuses on Look Up Table (LUT) based digital Electronic Predistortion (EPD) for optical transmission. Because it is only one out of many possible implementations of EPD, it has to be placed in context with other EPD techniques and other distortion combating techniques in general, especially since it is possible to combine the different techniques. Building an actual transmitter means that compromises and decisions have to be made in the design and implementation of an EPD based system. These are based on balancing the desire to achieve optimal performance with technological and economic limitations. This is partly done using optical simulations to asses the performance. This thesis describes a novel experimental transmitter that has been built as part of this research applying LUT based EPD to an optical signal. The experimental transmitter consists of a digital design (using a hardware description language) for a pair of FPGAs and an analogue optical/electronic setup including two standard DAC integrated circuits. The DSP in the transmitter compensated for both chromatic dispersion and self phase modulation. We achieved transmission of 10.7 Gb/s non-return-to-zero (NRZ) signals with a +4 dBm launch power over 450 km keeping the required optical-signal-to-noise-ratio (OSNR) for a bit-error-rate of 2x10^{-3} below 11 dB. In doing so we showed experimentally, for the first time, that nonlinear effects can be compensated with this approach and that the combination of FPGA-DAC is a viable approach for an experimental setup

Sampling digital coherent receiver for demultiplexing and processing of OTDM signals employing high-order modulation

In this thesis, we present a study of optical communication systems that make use of multilevel modulations and exploits coherent detection with digital signal processing (DSP) and optical time division multiplexing (OTDM). The Matlab modeling of an optical communication system if shown and the different elements of a DSP unit are analyzed. In particular we studied the Chromatic Dispersion (CD) compensation with Time Domain Equalizer (TDE), the Polarization Mode Dispersion (PMD) and polarization rotation compensation with adaptive equalizer, the digital phase estimation with Feed Forward (FF) algorithms and the frequency offset compensation. Next, we present the OTD demultiplexing for optical systems that utilize coherent receivers. A set of numerical simulation has been done for the study of the performance of the model implemented. At last we show the results obtained during a laboratory experiment. A back-to-back transmission of a 4-Channels OTDM QPSK system at 160 Gb/s with coherent detection and digital signal processing has been successfully performed and the results are presented and commente