Route diversity analyses for free-space optical wireless links within turbulent scenarios

Free-Space Optical (FSO) communications link performance is highly affected when propagating through the time-spatially variable turbulent environment. In order to improve signal reception, several mitigation techniques have been proposed and analytically investigated. This paper presents experimental results for the route diversity technique evaluations for a specific case when several diversity links intersects a common turbulent area and concurrently each passing regions with different turbulence flows

Adaptive parallel interference cancellation receivers with diversity combining for multicarrier DS CDMA systems

Master'sMASTER OF ENGINEERIN

Physical and Link Layer Implications in Vehicle Ad Hoc Networks

Vehicle Ad hoc Networks (V ANET) have been proposed to provide safety on the road and deliver road traffic information and route guidance to drivers along with commercial applications. However the challenges facing V ANET are numerous. Nodes move at high speeds, road side units and basestations are scarce, the topology is constrained by the road geometry and changes rapidly, and the number of nodes peaks suddenly in traffic jams. In this thesis we investigate the physical and link layers of V ANET and propose methods to achieve high data rates and high throughput. For the physical layer, we examine the use of Vertical BLAST (VB LAST) systems as they provide higher capacities than single antenna systems in rich fading environments. To study the applicability of VB LAST to VANET, a channel model was developed and verified using measurement data available in the literature. For no to medium line of sight, VBLAST systems provide high data rates. However the performance drops as the line of sight strength increases due to the correlation between the antennas. Moreover, the performance of VBLAST with training based channel estimation drops as the speed increases since the channel response changes rapidly. To update the channel state information matrix at the receiver, a channel tracking algorithm for flat fading channels was developed. The algorithm updates the channel matrix thus reducing the mean square error of the estimation and improving the bit error rate (BER). The analysis of VBLAST-OFDM systems showed they experience an error floor due to inter-carrier interference (lCI) which increases with speed, number of antennas transmitting and number of subcarriers used. The update algorithm was extended to VBLAST -OFDM systems and it showed improvements in BER performance but still experienced an error floor. An algorithm to equalise the ICI contribution of adjacent subcarriers was then developed and evaluated. The ICI equalisation algorithm reduces the error floor in BER as more subcarriers are equalised at the expense of more hardware complexity. The connectivity of V ANET was investigated and it was found that for single lane roads, car densities of 7 cars per communication range are sufficient to achieve high connectivity within the city whereas 12 cars per communication range are required for highways. Multilane roads require higher densities since cars tend to cluster in groups. Junctions and turns have lower connectivity than straight roads due to disconnections at the turns. Although higher densities improve the connectivity and, hence, the performance of the network layer, it leads to poor performance at the link layer. The IEEE 802.11 p MAC layer standard under development for V ANET uses a variant of Carrier Sense Multiple Access (CSMA). 802.11 protocols were analysed mathematically and via simulations and the results prove the saturation throughput of the basic access method drops as the number of nodes increases thus yielding very low throughput in congested areas. RTS/CTS access provides higher throughput but it applies only to unicast transmissions. To overcome the limitations of 802.11 protocols, we designed a protocol known as SOFT MAC which combines Space, Orthogonal Frequency and Time multiple access techniques. In SOFT MAC the road is divided into cells and each cell is allocated a unique group of subcarriers. Within a cell, nodes share the available subcarriers using a combination of TDMA and CSMA. The throughput analysis of SOFT MAC showed it has superior throughput compared to the basic access and similar to the RTS/CTS access of 802.11

Transmitter based techniques for ISI and MAI mitigation in CDMA-TDD downlink

The third-generation (3G) of mobile communications systems aim to provide enhanced voice, text and data services to the user. These demands give rise to the complexity and power consumption of the user equipment (UE) while the objective is smaller, lighter and power efficient mobiles. This thesis aims to examine ways of reducing the UE receiver’s computational cost while maintaining a good performance. One prominent multiple access scheme selected for 3G is code division multiple access. Receiver based multiuser detection techniques that utilise the knowledge of the downlink channel by the mobile have been extensively studied in the literature, in order to deal with multiple access and intersymbol interference. However, these techniques result in high mobile receiver complexity. Recently, work has been done on algorithms that transfer the complexity from the UE to the base station by exploiting the fact that in time division duplex mode the downlink channel can be known to the transmitter. By linear precoding of the transmitted signal the user equipment can be simplified to a filter matched to the user’s spreading code. In this thesis the problem of generic linear precoding is analysed theoretically and a method for analytical calculation of BER is developed. The most representative of the developed precoding techniques are described under a common framework, compared and classified as bitwise or blockwise. Bitwise demonstrate particular advantages in terms of complexity and implementation but lack in performance. Two novel bitwise algorithms are presented and analysed. They outperform significantly the existing ones, while maintain a reduced computational cost and realisation simplicity. The first, named inverse filters, is the Wiener solution of the problem after applying a minimum mean squared error criterion with power constraints. The second recruits multichannel adaptive algorithms to achieve the same goal. The base station emulates the actual system in a cell to converge iteratively to the pre-filters that precode the transmitted signals before transmission. The advantages and the performance of the proposed techniques, along with a variety of characteristics are demonstrated by means of Monte Carlo simulations

Performance Evaluation and Analysis of Mimo Schemes in LTE Networks Environment

RÉSUMÉ Dans cette thèse, nous proposons d'évaluer et d’analyser les performances des configurations radio à antennes multiples à l'émission et/ou la réception (MIMO) dans l’environnement des réseaux LTE (Long Term Evolution). Plus spécifiquement, on s’intéresse à la couche physique de l'interface radio OFDM-MIMO de ces réseaux. Après une introduction rapide aux réseaux LTE et aux techniques MIMO, on présente dans une première étape, une analyse théorique du taux d'erreur binaire en fonction du rapport signal sur bruit des deux principaux codes spatio-temporels de la norme LTE, à savoir le codage SFBC 21 (Space Frequency Block Coding) et le codage FSTD 42 (Frequency Switch Transmit Diversity). On développe les équations analytiques du taux d'erreur binaire de ces codes dans un canal à évanouissement de Rayleigh sans corrélation spatiale qui sont par la suite comparées à des valeurs obtenues par simulations Monte-Carlo. Dans une deuxième étape, on considère l’évaluation de la capacité du canal résultant de l’utilisation de ces mêmes codes dans un canal à évanouissement de Rayleigh. Pour fin de comparaison, on propose par la suite d’évaluer par simulation leur débit effectif. Les résultats montrent que la capacité peut effectivement être presque atteinte en pratique. Le deuxième volet de cette thèse considère les performances des systèmes MIMO utilisant la sélection d’antennes. Nous utilisons la théorie d'ordre statistique pour développer des équations analytiques relatives au taux d’erreur binaire des systèmes avec sélection d'antennes du coté récepteur dans un canal d'évanouissement de Rayleigh sans corrélation spatiale. Afin de valider numériquement les résultats de notre analyse, un algorithme à sélection d’antenne au récepteur a été développé et utilisé en simulation. Dans un dernier temps, on évalue l'effet de la corrélation spatiale entre les antennes. L’étude est faite à partir de simulations et d’un modèle de corrélation spatiale basé sur le produit Kronecker de deux matrices de corrélation relatives respectivement à l'émission et à la réception.----------ABSTRACT This thesis considers both an analysis and a numerical evaluation of the performance of MIMO radio systems in the LTE network environment. More specifically we consider the physical layer of the OFDM-MIMO based radio interface. As a first step we present a theoretical analysis of the bit error rate of the two space-time codes adopted by the LTE norm, namely the SFBC 21 and FSTD 42 codes, as a function of the signal upon noise ratio. Analytical expressions are given for transmission over a Rayleigh channel without spatial correlation which are then compared with Monte-Carlo simulations. As a second step, we consider the capacity of the channel obtained by using these codes on a Rayleigh fading channel. Results show that simulated throughput almost reaches the capacity limit. As a different topic, this thesis considers also MIMO systems based on antenna selection. By using order statistics we develop analytical expressions for the error rate on a Rayleigh channel without antenna correlation. In order to validate our numerical results, an algorithm implementing antenna selection at the receiver has been developed and used in the simulations. As a last step the effect of antenna correlation is investigated through the use of simulations and a model of spatial antenna correlation based on the Kronecker product of two correlation matrices related to the transmitting and receiving elements of the MIMO scheme