Global ETD Search

11	Lattice-Based Precoding And Decoding in MIMO Fading Systems Taherzadeh, Mahmoud January 2008 (has links) In this thesis, different aspects of lattice-based precoding and decoding for the transmission of digital and analog data over MIMO fading channels are investigated: 1) Lattice-based precoding in MIMO broadcast systems: A new viewpoint for adopting the lattice reduction in communication over MIMO broadcast channels is introduced. Lattice basis reduction helps us to reduce the average transmitted energy by modifying the region which includes the constellation points. The new viewpoint helps us to generalize the idea of lattice-reduction-aided precoding for the case of unequal-rate transmission, and obtain analytic results for the asymptotic behavior of the symbol-error-rate for the lattice-reduction-aided precoding and the perturbation technique. Also, the outage probability for both cases of fixed-rate users and fixed sum-rate is analyzed. It is shown that the lattice-reduction-aided method, using LLL algorithm, achieves the optimum asymptotic slope of symbol-error-rate (called the precoding diversity). 2) Lattice-based decoding in MIMO multiaccess systems and MIMO point-to-point systems: Diversity order and diversity-multiplexing tradeoff are two important measures for the performance of communication systems over MIMO fading channels. For the case of MIMO multiaccess systems (with single-antenna transmitters) or MIMO point-to-point systems with V-BLAST transmission scheme, it is proved that lattice-reduction-aided decoding achieves the maximum receive diversity (which is equal to the number of receive antennas). Also, it is proved that the naive lattice decoding (which discards the out-of-region decoded points) achieves the maximum diversity in V-BLAST systems. On the other hand, the inherent drawbacks of the naive lattice decoding for general MIMO fading systems is investigated. It is shown that using the naive lattice decoding for MIMO systems has considerable deficiencies in terms of the diversity-multiplexing tradeoff. Unlike the case of maximum-likelihood decoding, in this case, even the perfect lattice space-time codes which have the non-vanishing determinant property can not achieve the optimal diversity-multiplexing tradeoff. 3) Lattice-based analog transmission over MIMO fading channels: The problem of finding a delay-limited schemes for sending an analog source over MIMO fading channels is investigated in this part. First, the problem of robust joint source-channel coding over an additive white Gaussian noise channel is investigated. A new scheme is proposed which achieves the optimal slope for the signal-to-distortion-ratio (SDR) curve (unlike the previous known coding schemes). Then, this idea is extended to MIMO channels to construct lattice-based codes for joint source-channel coding over MIMO channels. Also, similar to the diversity-multiplexing tradeoff, the asymptotic performance of MIMO joint source-channel coding schemes is characterized, and a concept called diversity-fidelity tradeoff is introduced in this thesis. Lattice decoding Precoding MIMO communications Fading channels Joint source-channel coding Lattice-basis reduction LLL algorithm Diversity-multiplexing trade-off Diversity-fidelity trade-off Electrical and Computer Engineering
12	Lattice-Based Precoding And Decoding in MIMO Fading Systems Taherzadeh, Mahmoud January 2008 (has links) In this thesis, different aspects of lattice-based precoding and decoding for the transmission of digital and analog data over MIMO fading channels are investigated: 1) Lattice-based precoding in MIMO broadcast systems: A new viewpoint for adopting the lattice reduction in communication over MIMO broadcast channels is introduced. Lattice basis reduction helps us to reduce the average transmitted energy by modifying the region which includes the constellation points. The new viewpoint helps us to generalize the idea of lattice-reduction-aided precoding for the case of unequal-rate transmission, and obtain analytic results for the asymptotic behavior of the symbol-error-rate for the lattice-reduction-aided precoding and the perturbation technique. Also, the outage probability for both cases of fixed-rate users and fixed sum-rate is analyzed. It is shown that the lattice-reduction-aided method, using LLL algorithm, achieves the optimum asymptotic slope of symbol-error-rate (called the precoding diversity). 2) Lattice-based decoding in MIMO multiaccess systems and MIMO point-to-point systems: Diversity order and diversity-multiplexing tradeoff are two important measures for the performance of communication systems over MIMO fading channels. For the case of MIMO multiaccess systems (with single-antenna transmitters) or MIMO point-to-point systems with V-BLAST transmission scheme, it is proved that lattice-reduction-aided decoding achieves the maximum receive diversity (which is equal to the number of receive antennas). Also, it is proved that the naive lattice decoding (which discards the out-of-region decoded points) achieves the maximum diversity in V-BLAST systems. On the other hand, the inherent drawbacks of the naive lattice decoding for general MIMO fading systems is investigated. It is shown that using the naive lattice decoding for MIMO systems has considerable deficiencies in terms of the diversity-multiplexing tradeoff. Unlike the case of maximum-likelihood decoding, in this case, even the perfect lattice space-time codes which have the non-vanishing determinant property can not achieve the optimal diversity-multiplexing tradeoff. 3) Lattice-based analog transmission over MIMO fading channels: The problem of finding a delay-limited schemes for sending an analog source over MIMO fading channels is investigated in this part. First, the problem of robust joint source-channel coding over an additive white Gaussian noise channel is investigated. A new scheme is proposed which achieves the optimal slope for the signal-to-distortion-ratio (SDR) curve (unlike the previous known coding schemes). Then, this idea is extended to MIMO channels to construct lattice-based codes for joint source-channel coding over MIMO channels. Also, similar to the diversity-multiplexing tradeoff, the asymptotic performance of MIMO joint source-channel coding schemes is characterized, and a concept called diversity-fidelity tradeoff is introduced in this thesis. Lattice decoding Precoding MIMO communications Fading channels Joint source-channel coding Lattice-basis reduction LLL algorithm Diversity-multiplexing trade-off Diversity-fidelity trade-off Electrical and Computer Engineering
13	Réseaux Euclidiens : Algorithmes et Cryptographie Stehlé, Damien 14 October 2011 (has links) (PDF) Les réseaux Euclidiens sont un riche objet algébrique qui apparaît dans des contextes variés en mathématiques et en informatique. Cette thèse considère plusieurs aspects algorithmiques des réseaux. Le concept de réduction d'une base d'un réseau est étudié minutieusement : nous couvrons en particulier le spectre complet des compromis qualité-temps des algorithmes de réduction. D'une part, nous présentons et analysons des algorithmes rapides pour trouver une base assez courte (base LLL-réduite) d'un réseau donné arbitraire. D'autre part, nous proposons de nouvelles analyses pour des algorithmes (plus lents) permettant de calculer des bases très courtes (bases HKZ et BKZ-réduites). Cette étude des algorithmes de résolution efﬁcace de problèmes portant sur les réseaux est complétée par une application constructive exploitant leur difﬁculté apparente. Nous proposons et analysons des schémas cryptographiques, dont la fonction de chiffrement NTRU, et les prouvons au moins aussi difﬁciles à casser que de résoudre des problèmes pires-cas bien spéciﬁés portant sur les réseaux. Réseaux Euclidiens réductions LLL/HKZ/BKZ analyse d'algorithmes
14	Applications of Lattices over Wireless Channels Najafi, Hossein January 2012 (has links) In wireless networks, reliable communication is a challenging issue due to many attenuation factors such as receiver noise, channel fading, interference and asynchronous delays. Lattice coding and decoding provide efficient solutions to many problems in wireless communications and multiuser information theory. The capability in achieving the fundamental limits, together with simple and efficient transmitter and receiver structures, make the lattice strategy a promising approach. This work deals with problems of lattice detection over fading channels and time asynchronism over the lattice-based compute-and-forward protocol. In multiple-input multiple-output (MIMO) systems, the use of lattice reduction significantly improves the performance of approximate detection techniques. In the first part of this thesis, by taking advantage of the temporal correlation of a Rayleigh fading channel, low complexity lattice reduction methods are investigated. We show that updating the reduced lattice basis adaptively with a careful use of previous channel realizations yields a significant saving in complexity with a minimal degradation in performance. Considering high data rate MIMO systems, we then investigate soft-output detection methods. Using the list sphere decoder (LSD) algorithm, an adaptive method is proposed to reduce the complexity of generating the list for evaluating the log-likelihood ratio (LLR) values. In the second part, by applying the lattice coding and decoding schemes over asynchronous networks, we study the impact of asynchronism on the compute-and-forward strategy. While the key idea in compute-and-forward is to decode a linear synchronous combination of transmitted codewords, the distributed relays receive random asynchronous versions of the combinations. Assuming different asynchronous models, we design the receiver structure prior to the decoder of compute-and-forward so that the achievable rates are maximized at any signal-to-noise-ratio (SNR). Finally, we consider symbol-asynchronous X networks with single antenna nodes over time-invariant channels. We exploit the asynchronism among the received signals in order to design the interference alignment scheme. It is shown that the asynchronism provides correlated channel variations which are proved to be sufficient to implement the vector interference alignment over the constant X network. Wireless Lattice Fading MIMO decoding Interference Alignment Compute-and-Forward Soft-output Lattice Decoding X network Degrees of Freedom Lattice Reduction Asynchronous Networks Asynchronous Communications Matched Filter Maximum Likelihood LLL DILLL X channel Adaptive Decoding Closest Point Search Electrical and Computer Engineering
15	Algorithmique de la réduction de réseaux et <br />application à la recherche de pires cas pour l'arrondi de<br />fonctions mathématiques Stehlé, Damien 02 December 2005 (has links) (PDF) Les réseaux euclidiens sont un outil particulièrement puissant dans<br />plusieurs domaines de l'algorithmique, en cryptographie et en théorie<br />algorithmique des nombres par exemple. L'objet du présent mémoire est dual : nous améliorons les algorithmes de réduction des réseaux,<br />et nous développons une nouvelle application dans le domaine<br />de l'arithmétique des ordinateurs. En ce qui concerne l'aspect algorithmique, nous nous intéressons aux cas des petites dimensions (en dimension un, où il s'agit du calcul de pgcd, et aussi en dimensions 2 à 4), ainsi qu'à la description d'une nouvelle variante de l'algorithme LLL, en dimension quelconque. Du point de vue de l'application, nous utilisons la méthode<br />de Coppersmith permettant de trouver les petites racines de polynômes modulaires multivariés, pour calculer les pires cas pour l'arrondi des fonctions mathématiques, quand la fonction, le mode d'arrondi, et la précision sont donnés. Nous adaptons aussi notre technique aux mauvais cas simultanés pour deux fonctions. Ces deux méthodes sont des pré-calculs coûteux, qui une fois <br />effectués permettent d'accélérer les implantations des fonctions mathématiques élémentaires en précision fixée, par exemple en double précision.<br /><br />La plupart des algorithmes décrits dans ce mémoire ont été validés<br />expérimentalement par des implantations, qui sont<br />disponibles à l'url http://www.loria.fr/~stehle. Réseaux euclidiens algorithme LLL calcul de pgcd <br />arithmétique flottante dilemme du fabricant de tables <br />méthode de Coppersmith analyse de complexité
16	Applications of Lattices over Wireless Channels Najafi, Hossein January 2012 (has links) In wireless networks, reliable communication is a challenging issue due to many attenuation factors such as receiver noise, channel fading, interference and asynchronous delays. Lattice coding and decoding provide efficient solutions to many problems in wireless communications and multiuser information theory. The capability in achieving the fundamental limits, together with simple and efficient transmitter and receiver structures, make the lattice strategy a promising approach. This work deals with problems of lattice detection over fading channels and time asynchronism over the lattice-based compute-and-forward protocol. In multiple-input multiple-output (MIMO) systems, the use of lattice reduction significantly improves the performance of approximate detection techniques. In the first part of this thesis, by taking advantage of the temporal correlation of a Rayleigh fading channel, low complexity lattice reduction methods are investigated. We show that updating the reduced lattice basis adaptively with a careful use of previous channel realizations yields a significant saving in complexity with a minimal degradation in performance. Considering high data rate MIMO systems, we then investigate soft-output detection methods. Using the list sphere decoder (LSD) algorithm, an adaptive method is proposed to reduce the complexity of generating the list for evaluating the log-likelihood ratio (LLR) values. In the second part, by applying the lattice coding and decoding schemes over asynchronous networks, we study the impact of asynchronism on the compute-and-forward strategy. While the key idea in compute-and-forward is to decode a linear synchronous combination of transmitted codewords, the distributed relays receive random asynchronous versions of the combinations. Assuming different asynchronous models, we design the receiver structure prior to the decoder of compute-and-forward so that the achievable rates are maximized at any signal-to-noise-ratio (SNR). Finally, we consider symbol-asynchronous X networks with single antenna nodes over time-invariant channels. We exploit the asynchronism among the received signals in order to design the interference alignment scheme. It is shown that the asynchronism provides correlated channel variations which are proved to be sufficient to implement the vector interference alignment over the constant X network. Wireless Lattice Fading MIMO decoding Interference Alignment Compute-and-Forward Soft-output Lattice Decoding X network Degrees of Freedom Lattice Reduction Asynchronous Networks Asynchronous Communications Matched Filter Maximum Likelihood LLL DILLL X channel Adaptive Decoding Closest Point Search Electrical and Computer Engineering

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