3 research outputs found
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Feedback in multiple antenna wireless communication systems
Multiple-input multiple-output wireless systems promise significant capacity gain
and/or diversity gain over single antenna systems. If channel state information (CSI)
is available at both the transmitter and the receiver, the performance can be further
improved. In this thesis, first, we study binary index feedback problem in beamforming
systems when the feedback channel is not error free. Feedback errors lead to incorrect
beamforming vectors to be applied at the transmitter and thus degrade beamforming
performance. Index-assignment algorithms that minimize the impact of feedback errors
are proposed. Second, in the limited feedback beamforming scheme the receiver has to
determine the best codeword from the beamforming codebook. Exhaustive codeword
search for large-size codebooks becomes a burden when the receiver is a mobile device
with limited computational power. We propose an algorithm to drastically reduce codeword
selection complexity with negligible performance loss. Third, we compare angle
feedback scheme and transmit antenna shuffling feedback scheme for double space-time
transmit diversity systems. We show that the 1-bit angle feedback scheme does not
provide a better performance than the 1-bit antenna shuffling feedback scheme. Fourth,
we consider training power allocation for a closed-loop MIMO system in i.i.d. Rayleigh
flat-fading channels with power constraint. We derive the optimal solution and asymptotic
optimal solution of training power allocation for spatial power control and spatial
and fading power control. Lastly, we analyze the optimal diversity-multiplexing tradeoff
of multiple beamforming systems and compare it with the well known result for MIMO
channels with channel state information at the receiver (CSIR) only and with the optimal
diversity-multiplexing tradeoff of spatial multiplexing system with channel state
information at the transmitter (CSIT), but without coding over space and time
Modélisation et simulation de réseaux locaux et personnels sans fil : intégration des couches PHY et MAC
Dans ce travail nous nous intéressons à la modélisation des couches MAC et PHY dans le cadre des réseaux sans fil à faible, portée. Il présente les techniques de modélisation utilisées pour l'intégration des couches MAC-PHYs (Medium Access Control and Physical layer) de type IR-UWB (Impulse Radio Ultra Wideband) d'une part, et des nouvelles techniques de transmission à 60GHz incluant le beamforming d'autre part, dans le simulateur GloMoSim/QualNet. La modélisation de IR-UWB est basée sur la prise en compte directe des collisions d'impulsions et de l'interférence multi-utilisateur au niveau de la couche PHY par l'introduction du concept de séquences de réception et la notion d'orthogonalité en réception. L'architecture de modélisation proposée est basée sur l'utilisation d'une matrice d'interférence, elle a été développée en deux étapes : une première modélisation basée sur des trains d'impulsions uniformément espacées et une deuxième modélisation plus complète prenant en compte l'utilisation des séquences de sauts aléatoires également appelés séquences de time hopping. L'évaluation de performances de cette partie est basée sur une application typique des réseaux de capteurs dans le cadre d'une application de détection d'intrusion sur une surface protégée. La modélisation à 60 GHz à pour but la prise en compte des nouvelles techniques d'amélioration du débit, notamment l'agrégation et le beamforming. La prise en compte du beamforming est basée sur la définition, des diagrammes de rayonnement des antennes ainsi que de l'interface MAC-PHY/Antenne. La modélisation des deux protocoles de beamforming définis dans le standard 802.15.3c est également effectuée. L'évaluation de performances de cette partie est basée sur un système de distribution de contenu multimédia.In this work, we focus on physical and medium access control layer modeling and simulation for short range wireless communication. In particular, the modeling of the Impulse Radio Ultra Wide Band technique for wireless sensor networks and the high data rate communication modeling which uses millimeter wave and beamforming.
The first part deals with the modeling of Impulse Radio Ultra Wide Band. The proposed model takes into account the pulse collision induced by multiple concurrent transmissions at the physical layer which is also called multi user interference. This aspect is accurately introduced thanks to the concept of reception time hopping sequences of concurrent reception and their orthogonality. The simulation architecture is built using two models: the first model is based on a uniformly distributed pulse train and the second model, more complete, takes into account variable time hopping sequences. The performance evaluation of this part is based on a typical wireless sensor networks application, in which sensor nodes are scattered on a particular area to detect and report intrusion events to a base station.
The second part deals with the modeling of high data rate communication using millimeter wave. The targeted goal of millimeter wave transmission is to increase the data rate using some novel techniques: beamforming and data aggregation. Beamforming is modeled on the so-called codebook beamforming defined as the new beamforming technique for high data rate wireless communication standards. A methodology is developed to take into account the radiation pattern defined by the codebook indexes. For each index the gain of the directional antenna is computed for each direction. This is used in the simulation model physical layer to determine the directional antenna gain in a particular direction during the propagation stage. The defined protocols for sector level and beam level training defined in the 802.15.3c draft are also modeled. The performance evaluation of this part is based on a multimedia distribution system