Resource Allocation Strategies and Linear Precoded OFDM Optimization for Ultra-Wideband Communications Antoine Stephan To cite this version: AntoineStephan. ResourceAllocationStrategiesandLinearPrecodedOFDMOptimizationforUltra- Wideband Communications. Signal and Image processing. INSA de Rennes, 2008. English. NNT: . tel-00376631 HAL Id: tel-00376631 https://theses.hal.science/tel-00376631 Submitted on 18 Apr 2009 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. No d’ordre : D08-29 Thèse présentée devant l’Institut National des Sciences Appliquées de Rennes pour obtenir le titre de Docteur spécialité : Électronique Resource Allocation Strategies and Linear Precoded OFDM Optimization for Ultra-Wideband Communications par Antoine STEPHAN Soutenue le 15 décembre 2008 devant la commission d’Examen Composition du jury Rapporteurs Michel Jézéquel Directeur des Etudes – HDR à TELECOM Bretagne Dirk Slock Professeur à EURECOM Examinateurs Andrea Tonello Professeur à l’Université de Udine, Italie Luc Vandendorpe Professeur à l’Université Catholique de Louvain, Belgique Rodolphe Le Gouable Docteur-Ingénieur à Orange Labs (France Télécom R&D) Jean-Yves Baudais Chargé de Recherches CNRS à l’IETR Jean-François Hélard Professeur à l’INSA de Rennes Institut d’Électronique et de Télécommunications de Rennes Institut National des Sciences Appliquées de Rennes To my Parents Abstract Ultra-wideband (UWB) is a fast technology that has recently attracted considerable interest in the research and standardization communities, due to its ability to provide high data rate at low cost and low power consumption. The objective of this thesis is to propose a new UWB system for high data rate wireless personal area network (WPAN) applications, based on the well-known multiband orthogonal frequency-division multiplexing (MB- OFDM) solution supported by the WiMedia Alliance. In a first step, we analytically investigate the use of a linear precoded OFDM (LP-OFDM) waveform for UWB systems. The resulting scheme reduces in practice to a simple addition of a precoding matrix, or equivalently spreading sequences, to the MB-OFDM transmission chain, which does not increase the system complexity signifi- cantly. The precoding function is then analytically optimized and different resource alloca- tion strategies based on a classical target symbol-error-rate (SER) approach and on a new mean bit-error-rate (BER) approach are investigated. Efficient allocation algorithms maximizing the system range and throughput, and minimizing the system mean BER, are thus proposed for different application scenarios. The numerical results of simulations car- ried out on the different adaptive and non-adaptive schemes show that the LP-OFDM sys- tem outperforms the MB-OFDM system in terms of throughput and range. This is due to the spreading gain provided by the linear precoding component, and to the efficiency of the proposed algorithms. In a second step, a global UWB system approach is carried out. This system study, complementary to the analytical one, points out the advantages of appropriately adding the linear precoding to the MB-OFDM solution. Furthermore, a MIMO component is added to the LP-OFDM system in order to improve the system robustness as well as to provide a data rate of 1 Gb/s. System simulation results show that the joint use of MIMO and LP-OFDM schemes in UWB leads to a significant system improvement compared to the MB-OFDM system. Thus, the proposed MIMO LP-OFDM system can be advantageously exploited for high data rate UWB applications at reasonable additional system complexity. This work was carried out at the Institute of Electronics and Telecommunications of Rennes (IETR) – National Institute of Applied Sciences (INSA). It was sponsored by Or- ange Labs RESA/WIN/CREM (France Télécom R&D) within an external research con- tract. This research was also part of the European Community ICT FP7 OMEGA project OMEGA. v Acknowledgments I owe my gratitude to all the people who have made this thesis possible with their help, support and contributions. First and foremost, I would like to thank my advisor, Prof. Jean-François Hélard, who has given me an invaluable opportunity to do research and work on challenging and ex- tremely interesting subjects over the past three years, and my supervisor, Dr. Jean-Yves Baudais, for his special theoretical ideas and mathematical expertise. They have been great mentors throughout my Ph.D. by helping me establish a direction of research and provid- ing valuable guidance and advice. I will never forget the fun moments and the dialogues we had on various subjects. Many thanks go to Prof. Luc Vandendorpe, the jury president, Prof. Michel Jézéquel, Prof. Dirk Slock, Prof. Andrea Tonello, and Dr. Rodolphe Le Gouable, for coming from the different corners of France, Italy and Belgium to serve on my thesis committee, and for sparing their invaluable time reviewing the manuscript. I want to thank Dr. Matthieu Crussière and Dr. Emeric Guéguen for letting me benefit from their exceptional previous work, which improved my research work significantly. Many thanks also go to all those who collaborated with me, particularly Fahad Syed Mu- hammad and Ayman Khalil. I would like to express my sincere thanks to Orange Labs RESA/WIN/CREM (France Télécom R&D) and to the European ICT FP7 OMEGA project for supporting this work. Special thanks go to Isabelle Siaud for her helpful advice and interesting discussions. All my colleagues at IETR have enriched my graduate life in many ways. I would like to thank my “Bocal” colleagues Minh, Christophe, Yvan, Patrice, Sylvie and Pierre, as well as Irène, Youssef and the rest of the staff. Special thanks go to Prof. Ghais El Zein and Hanna Farhat who have always made themselves available for help and advice. I would like to thank Marielle for her love, support, and unlimited kindness. She has always been by my side, especially during the hardest moments of the Ph.D. Last but not least, I owe my deepest thanks to my wonderful family, my parents, my sister and my brother, who are always there for me even though we are a thousand miles apart. I express my gratitude to my parents for having guided me through life, and sup- ported and encouraged me to move to Sweden and France to pursue my Master’s and Ph.D. studies. vii Contents Abstract v Acknowledgments vii Contents ix Résumé étendu en Français xiii List of Figures xxix List of Tables xxxiii Acronyms xxxv Introduction 1 1. Ultra‐wideband communications 7 1.1 Historical overview................................................................................................7 1.2 UWB principles and characteristics.......................................................................8 1.3 Regulatory bodies.................................................................................................10 1.3.1 UWB regulations in the USA..................................................................10 1.3.2 UWB regulations in Europe....................................................................11 1.4 Standardization.....................................................................................................12 1.4.1 IEEE 802.15.3a.......................................................................................12 1.4.2 IEEE 802.15.4a.......................................................................................13 1.4.3 Other standards........................................................................................13 1.5 Main applications.................................................................................................14 1.6 Modulation techniques.........................................................................................15 1.6.1 Impulse radio...........................................................................................15 1.6.1.1 Data modulation techniques...................................................16 1.6.1.2 Multiple access schemes........................................................17 1.6.2 Multiband OFDM....................................................................................19 1.6.2.1 Multiband technique..............................................................19 ix
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