Global ETD Search

1	Iterative decoding techniques for block based error correction codes Hirst, Simon January 2002 (has links) No description available. 621.38224 Turbo codes
2	On the design of implementation of turbo-coded Hybrid-ARQ Oteng-Amoako, Kingsley, Electrical Engineering & Telecommunications, Faculty of Engineering, UNSW January 2005 (has links) The problem of the efficient use of Hybrid Automatic-Repeat-reQuest (Hybrid-ARQ) in wireless communication has attracted a considerable amount of research. In this thesis, the use and implementation of turbo codes as the Forward Error Correction (FEC) code for Hybrid-ARQ is investigated. The major accomplishments of the research include both the analysis and implementation of turbo Hybrid-ARQ. The thesis begins by obtaining a tractable bound for the performance of turbo codes with M-ary Quadrature-Amplitude-Modulation (M-ary QAM). The research considers the design problem of turbo coded Hybrid-ARQ optimized for AWGN and fading channels. The design problem of turbo Hybrid-ARQ in wideband channels is considered and an optimization strategy is proposed based on Orthogonal-Frequency-Division- Multiplexing (OFDM). The research also presents a novel rate scalable encoder structure that optimal selects a disparate but optimal pair of component codes given the channel conditions. A second part of the thesis considers the implementation of turbo Hybrid-ARQ in Very Large Scale Integration (VLSI ) systems. A design for a single architecture for Type-I and Type-II turbo Hybrid-ARQ is suggested in addition to approaches for improving performance of the Soft-Output-Viterbi-Algorithm(SOVA) decoder core. The research also proposes a SOVA decoder architecture that exploits reliability information to select between the SOVA and bi-directional SOVA. Turbo Codes Hybrid-ARQ
3	Novel methods in the improvement of turbo codes and their decoding Rogers, Andrew John January 2013 (has links) The performance of turbo codes can often be improved by improving the weight spectra of such codes. Methods of producing the weight spectra of turbo codes have been investigated and many improvements were made to refine the techniques. A much faster method of weight spectrum evaluation has been developed that allows calculation of weight spectra within a few minutes on a typical desktop PC. Simulation results show that new high performance turbo codes are produced by the optimisation methods presented. The two further important areas of concern are the code itself and the decoding. Improvements of the code are accomplished through optimisation of the interleaver and choice of constituent coders. Optimisation of interleaves can also be accomplished automatically using the algorithms described in this work. The addition of a CRC as an outer code proved to offer a vast improvement on the overall code performance. This was achieved without any code rate loss as the turbo code is punctured to make way for the CRC remainder. The results show a gain of 0.4dB compared to the non-CRC (1014,676) turbo code. Another improvement to the decoding performance was achieved through a combination of MAP decoding and Ordered Reliability decoding. The simulations show a performance of just 0.2dB from the Shannon limit. The same code without ordered reliability decoding has a performance curve which is 0.6dB from the Shannon limit. In situations where the MAP decoder fails to converge ordered reliability decoding succeeds in producing a codeword much closer to the received vector, often the correct codeword. The ordered reliability decoding adds to the computational complexity but lends itself to FPGA implementation. 003 Turbo ; Codes ; Decoding ; CRC
4	AN ADVANCED RECONFIGURABLE MULTI-CHANNEL COMMUNICATION TERMINAL FOR TELEMETRY APPLICATIONS BASED ON FLEXICOM 260A Chandran, Henry 10 1900 (has links) International Telemetering Conference Proceedings / October 22-25, 2001 / Riviera Hotel and Convention Center, Las Vegas, Nevada / Traditional communication hardware has focused on modular architectures. Now, with the incoming high speed DSP and FPGAs a shift from traditional modular architecture to reconfigurable architecture has taken place. The nature of this architecture allows to optimize various telemetry applications in a single platform. This paper describes a reconfigurable multi channel communication system. Reconfigurable hardware DSP Turbo Codes OFDM
5	Étude de turbo codes blocs de Reed-Solomon appliqués à la boucle locale filaire haut débit Diatta, Ibrahima Geller, Benoît Lemoine, Jacques January 2004 (has links) (PDF) Thèse de doctorat : Télécommunications : Paris 12 : 2004. / Titre provenant de l'écran-titre.
6	Étude du codage de sources distribuées pour de nouveaux concepts en compression vidéo Lajnef, Khaled Guillemot, Christine January 2006 (has links) (PDF) Thèse doctorat : Traitement du signal et télécommunications : Rennes 1 : 2006. / Bibliogr. p. 197-204.
7	Iterative decoding of concatenated codes Fagervik, Kjetil January 1998 (has links) No description available. 621.3822
8	Contribution à l’amélioration des performances de décodage des turbo codes : algorithmes et architecture / Contribution to the improvement of the decoding performance of turbo codes : algorithms and architecture Tonnellier, Thibaud 05 July 2017 (has links) Les turbo codes sont une classe de codes correcteurs d’erreurs approchant la limite théorique de capacité formulée par Claude Shannon. Conjointement à leurs excellentes performances de décodage, la complexité calculatoire modérée des turbo décodeurs a permis leur inclusion dans de nombreux standards de communications numériques. Une des métriques permettant la caractérisation de codes correcteurs d’erreurs est l’évolution du taux d’erreurs binaires en fonction du rapport signal sur bruit. Dans le cadre des turbo codes, une courbe de performance de décodage comprend deux zones principales.Dans la première zone, une faible amélioration de la qualité du canal de transmission entraîne de grandes améliorations au niveau des performances de décodage. En revanche dans la seconde, une amélioration de cette qualité ne résulte qu’en une amélioration marginale des performances de décodage. Cette seconde région est nommée zone du plancher d’erreurs. Elle peut empêcher l’utilisation de turbo codes dans des contextes nécessitant de très faibles taux d’erreurs. C’est pourquoi la communauté scientifique a proposé différentes optimisations favorisant la construction de turbo codes atténuant ce plancher d’erreurs. Cependant, ces approches ne peuvent être considérées pour des turbocodes déjà standardisés. Dans ce contexte, cette thèse adresse le problème de la réduction du plancher d’erreurs en s’interdisant de modifier la chaîne de communications numériques du côté de l’émetteur.Pour ce faire, un état de l’art de méthodes de post-traitement de décodage est dressé pour les turbo codes. Il apparaît que les solutions efficaces sont coûteuses à mettre en oeuvre car elles nécessitent une multiplication des ressources calculatoires ou impactent fortement la latence globale de décodage.Dans un premier temps, deux algorithmes basés sur une supervision de l’évolution de métriques internes aux décodeurs, sont proposés. L’un deux permet d’augmenter la convergence du turbo décodeur. L’autre ne permet qu’une réduction marginale du plancher d’erreurs. Dans un second temps, il est observé que dans la zone du plancher d’erreurs, les trames décodées par le turbo décodeur sont très proches du mot de code originellement transmis. Ceci est démontré par une proposition de prédiction analytique de la distribution du nombre d’erreurs binaires par trame erronée. Cette dernière est réalisée grâce au spectre de distance du turbo code. Puisque ces erreurs binaires responsables du plancher d’erreurs sont peu nombreuses, une métrique permettant de les identifier est mise en oeuvre. Ceci mène alors à l’établissement d’un algorithme de décodage permettant de corriger des erreurs résiduelles. Cet algorithme, appelé algorithme Flip-and-Check se base sur un principe de création de mots candidats et de vérifications successives parun code détecteur d’erreurs. Grâce à cet algorithme de décodage, un abaissement du plancher d’erreurs d’un ordre de grandeur est obtenu pour les turbo codes de différents standards (LTE, CCSDS, DVB-RCS et DVB-RCS2), ce, tout en conservant une complexité calculatoire raisonnable.Finalement, une architecture matérielle de décodage implémentant l’algorithme Flipand-Check est présentée. Une étude préalable de l’impact des différents paramètres de l’algorithme est menée. Elle aboutit à la définition de valeurs optimales pour certains de ces paramètres. D’autres sont à adapter en fonction des gains visés en terme de performances de décodage. Cette architecture démontre alors la possible intégration de cet algorithme aux turbo décodeurs existants ; permettant alors d’abaisser le plancher d’erreurs des différents turbo codes présents dans les différents standards de télécommunication. / Since their introduction in the 90’s, turbo codes are considered as one of the most powerful error-correcting code. Thanks to their excellent trade-off between computational complexity and decoding performance, they were chosen in many communication standards. One way to characterize error-correcting codes is the evolution of the bit error rate as a function of signal-to-noise ratio (SNR). The turbo code error rate performance is divided in two different regions : the waterfall region and the error floor region. In the waterfall region, a slight increase in SNR results in a significant drop in error rate. In the error floor region, the error rate performance is only slightly improved as the SNR grows. This error floor can prevent turbo codes from being used in applications with low error rates requirements. Therefore various constructions optimizations that lower the error floor of turbo codes has been proposed in recent years by scientific community. However, these approaches can not be considered for already standardized turbo codes.This thesis addresses the problem of lowering the error floor of turbo codes without allowing any modification of the digital communication chain at the transmitter side. For this purpose, the state-of-the-art post-processing decoding method for turbo codes is detailed. It appears that efficient solutions are expensive to implement due to the required multiplication of computational resources or can strongly impact the overall decoding latency. Firstly, two decoding algorithms based on the monitoring of decoder’s internal metrics are proposed. The waterfall region is enhanced by the first algorithm. However, the second one marginally lowers the error floor. Then, the study shows that in the error floor region, frames decoded by the turbo decoder are really close to the word originally transmitted. This is demonstrated by a proposition of an analytical prediction of the distribution of the number of bits in errors per erroneous frame. This prediction rests on the distance spectrum of turbo codes. Since the appearance of error floor region is due to only few bits in errors, an identification metric is proposed. This lead to the proposal of an algorithm that can correct residual errors. This algorithm, called Flip-and-Check, rests on the generation of candidate words, followed by verification according to an error-detecting code. Thanks to this decoding algorithm, the error floor of turbo codes encountered in different standards (LTE, CCSDS, DVB-RCS and DVB-RCS2) is lowered by one order of magnitude. This performance improvement is obtained without considering an important computational complexity overhead. Finally, a hardware decoding architecture implementing the Flip-and-Check algorithm is presented. A preliminary study of the impact of the different parameters of this algorithm is carried out. It leads to the definition of optimal values for some of these parameters. Others has to be adapted according to the gains targeted in terms of decoding performance. The possible integration of this algorithm along with existing turbo decoders is demonstrated thanks to this hardware architecture. This therefore enables the lowering of the error floors of standardized turbo codes. Turbo-codes Erreurs résiduelles Post-traitement Implémentation matérielle Turbo codes Residual Errors Post-processing Hardware architecture
9	Performance of a Low Rate Duo - Binary Turbo Decoder With Genetic Optimization Chowdhari, Vikram 05 August 2009 (has links) No description available. Electrical Engineering turbo codes genetic algorithm duo binary turbo codes error correction codes
10	TURBO-CODED APSK FOR TELEMETRY Shaw, Christopher, Rice, Michael 10 1900 (has links) ITC/USA 2007 Conference Proceedings / The Forty-Third Annual International Telemetering Conference and Technical Exhibition / October 22-25, 2007 / Riviera Hotel & Convention Center, Las Vegas, Nevada / This paper considers the use of Amplitude-Phase Shift Keying (APSK) for a telemetry system. Variable rate turbo codes are used to improve the power efficiency of 16- and 32-APSK. We discuss compensation techniques for power amplifier nonlinearities. Simulation results show the improved spectral efficiency of this modulation scheme over those currently defined in telemetry standards. Turbo codes amplitude-phase shift keying spectral efficiency

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