Design of Energy-Efficient Uniquely Factorable Constellations for MIMO and Relay Systems

Leung, Eleanor

06 1900

This thesis focuses on the concept of uniquely factorable constellations (UFCs) in the design of space-time block codes (STBCs) for wireless communication systems using three different approaches. Based on intelligent constellation collaboration, UFCs can provide the systematic design of a full diversity code with improved coding gain. Firstly, motivated by the energy-efficient hexagonal lattice carved from the Eisenstein integer domain, hexagonal UFCs and hexagonal uniquely factorable constellation pairs (UFCPs), of various sizes, are constructed for a noncoherent single-input multiple-output (SIMO) system. It is proved that these designs assure the blind unique identification of channel coefficients and transmitted signals in a noise-free case and full diversity for the noncoherent maximum likelihood (ML) receiver in a noisy case. In addition, an optimal energy scale is found to maximize the coding gain. Secondly, using a matrix similar to the Alamouti matrix and the UFCP concept based on the quadrature amplitude modulation (QAM) constellation, a novel energy-efficient unitary STBC is designed for a noncoherent multiple-input single-output (MISO) system with two transmitter antennas and one receiver antenna by using the QR decomposition. It is shown that the proposed UFCP-STBC design also allows for the blind unique identification of both the transmitted signals and channel coefficients as well as full diversity. In addition, an optimal unitary UFCP-STBC is devised to maximize the coding gain subject to a transmission bit rate constraint. The last approach is to demonstrate how the UFCP concept is applied to the systematic design of a coherent relay network coding system. A class of uniquely factorable Alamouti matrix pairs is proposed for the design of a novel amplify-forward relay network coding scheme, which allows the relay node to transmit its own information. By carefully making use of the Alamouti coding structure and strategically encoding the signals from the two antennas at the relay node, the resulting coding scheme enables the optimal full diversity gain and better coding gain for the ML detector. Comprehensive computer simulations show that the three uniquely factorable designs presented in this thesis have the best error performance compared to the current designs in literature. / Thesis / Candidate in Philosophy

MIMO Systems

Relay Systems

Noncoherent Communication

Uniquely factorable constellation

Signal Constellation Design

Advanced Coded Modulation for High Speed Optical Transmission

Liu, Tao

January 2016

In the recent years, the exponential Internet traffic growth projections place enormous transmission rate demand on the underlying information infrastructure at every level, from the long haul submarine transmission to optical metro networks. In recent years, optical transmission at 100 Gb/s Ethernet date rate has been standardized by ITU-T and IEEE forums and 400Gb/s and 1Tb/s rates per DWDM channel systems has been under intensive investigation which are expected to be standardized within next couple of years.To facilitate the implementation of 400GbE and 1TbE technologies, the new advanced modulation scheme combined with advanced forward error correction code should be proposed. Instead of using traditional QAM, we prefer to use some other modulation techniques, which are more suitable for current coherent optical transmission systems and can also deal with the channel impairments. In this dissertation, we target at improving the channel capacity by designing the new modulation formats. For the first part of the dissertation, we first describe the optimal signal constellation design algorithm (OSCD), which is designed by placing constellation points onto a two dimensional space. Then, we expand the OSCD onto multidimensional space and design its corresponding mapping rule. At last, we also develop the OSCD algorithm for different channel scenario in order to make the constellation more tolerant to different channel impairments. We propose the LLR-OSCD for linear phase noise dominated channel and NL-OSCD for nonlinear phase noise dominated channel including both self-phase modulation (SPM) and cross-phase modulation (XPM) cases. For the second part of the dissertation, we target at probability shaping of the constellation sets (non-uniform signaling). In the conventional data transmission schemes, the probability of each point in a given constellation is transmitted equally likely and the number of constellation sets is set to 2!. If the points with low energy are transmitted with larger probability then the others with large energy, the non- uniform scheme can achieve higher energy efficiency. Meanwhile, this scheme may be more suitable for optical communication because the transmitted points with large probabilities, which have small energy, suffer less nonlinearity. Both the Monte Carlo simulations and experiment demonstration of both OSCD and non-uniform signaling schemes indicate that our proposed signal constellation significantly outperforms QAM, IPQ, and sphere-packing based signal constellations.

Coherent Optics

Low Density Parity Check Code

Optical Communication System

Probability Shaping

Signal Constellation Design

Electrical & Computer Engineering

Coded Modulation

Modula??o quantizada para sistemas com codifica??o wavelet sujeitos ao desvanecimento rayleigh

Ferreira, Talles Rodrigues

12 March 2009

Made available in DSpace on 2014-12-17T14:55:42Z (GMT). No. of bitstreams: 1 TallesRF_DISSERT.pdf: 1140964 bytes, checksum: 341e86481dc2ae47c2cea90b012c9fc6 (MD5) Previous issue date: 2009-03-12 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior / Wavelet coding is an efficient technique to overcome the multipath fading effects, which are characterized by fluctuations in the intensity of the transmitted signals over wireless channels. Since the wavelet symbols are non-equiprobable, modulation schemes play a significant role in the overall performance of wavelet systems. Thus the development of an efficient design method is crucial to obtain modulation schemes suitable for wavelet systems, principally when these systems employ wavelet encoding matrixes of great dimensions. In this work, it is proposed a design methodology to obtain sub-optimum modulation schemes for wavelet systems over Rayleigh fading channels. In this context, novels signal constellations and quantization schemes are obtained via genetic algorithm and mathematical tools. Numerical results obtained from simulations show that the wavelet-coded systems derived here have very good performance characteristics over fading channels / A codifica??o por matrizes wavelets tem se mostrado um m?todo eficiente para combater o desvanecimento, fen?meno que causa flutua??es na intensidade do sinal transmitido em um canal de comunica??o sem fio, devido ? propaga??o por m?ltiplos percursos. Mas como os s?mbolos codificados pelo sistema wavelet s?o n?o-equiprov?veis, os esquemas de modula??o influenciam de maneira fundamental o desempenho desse sistema. Por isso se torna essencial um m?todo eficaz para a obten??o desses esquemas de modula??o de forma a otimizar o desempenho do sistema wavelet, principalmente quando se emprega matrizes wavelets de grandes dimens?es. Esse trabalho aborda o projeto de esquemas de modula??o para um sistema de transmiss?o sem fio baseado na codifica??o por matrizes wavelets em canais com desvanecimento Rayleigh plano. Para o projeto desses esquemas de modula??o s?o criados novas constela??es e esquemas de quantiza??o. O projeto desses esquemas de modula??o ? guiado por um algoritmo gen?tico. Os resultados obtidos atrav?s de simula??es computacionais mostram que os sistemas wavelets empregando esses esquemas obtiveram um bom desempenho em canais caracterizados pelo desvanecimento Rayleigh

Modula??o

Codifica??o wavelet

Projeto de constela??es de sinais

Algoritmos gen?ticos

Modulation

Wavelet coding

Signal constellation design

Genetic algorithm

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA