Performance Analysis of Cognitive Radio Network over SIMO System / Performance Analysis of Cognitive Radio Network over SIMO System

Haider, Iqbal Hasan, Rabby, MD. Fazla

January 2012

As resources are limited, radio spectrum becomes congested due to the growth of wireless applications. However, measurements address the fact that most of the licensed spectrums experience low utilization even in intensively teeming areas. In the exertion to improve the utilization of the limited spectrum resources, cognitive radio networks have emerged as a powerful technique to resolve this problem. There are two types of user in cognitive radio networks (CRNs) named as primary user (PU) and secondary user (SU). Therein, the CRN enables the SU to utilize the unused licensed frequency of the PU if it possibly finds the vacant spectrum or white space (known as opportunistic spectrum access). Alternatively, SU can transmit simultaneously with the PU provided that transmission power of SU does not cause any harmful interference to the PU (known as spectrum sharing systems). In this thesis work, we study fundamental knowledge of the CRNs and focus on the performance analysis of the single input multiple output (SIMO) system for spectrum sharing approach. We assume that a secondary transmitter (SU-Tx) has full channel state information (CSI). The SU-Tx can adjust its transmit power not to cause harmful interference to the PU and obtain an optimal transmit rate. In particular, we derive the closed-form expressions for the cumulative distribution function (CDF), outage probability and an analytical expression for symbol error probability (SEP). / As resources are limited, radio spectrum becomes congested due to the growth of wireless applications. However, measurements address the fact that most of the licensed spectrums experience low utilization even in intensively teeming areas. In the exertion to improve the utilization of the limited spectrum resources, cognitive radio networks have emerged as a powerful technique to resolve this problem. There are two types of user in cognitive radio networks (CRNs) named as primary user (PU) and secondary user (SU). Therein, the CRN enables the SU to utilize the unused licensed frequency of the PU if it possibly finds the vacant spectrum or white space (known as opportunistic spectrum access). Alternatively, SU can transmit simultaneously with the PU provided that transmission power of SU does not cause any harmful interference to the PU (known as spectrum sharing systems). In this thesis work, we study fundamental knowledge of the CRNs and focus on the performance analysis of the single input multiple output (SIMO) system for spectrum sharing approach. We assume that a secondary transmitter (SU-Tx) has full channel state information (CSI). The SU-Tx can adjust its transmit power not to cause harmful interference to the PU and obtain an optimal transmit rate. In particular, we derive the closed-form expressions for the cumulative distribution function (CDF), outage probability and an analytical expression for symbol error probability (SEP). / Iqbal Hasan Haider, cell: +46704571807 MD. Fazla Rabby, cell: +46734965477

Cognitive Radio

Outage Probability

Symbol Error Probability

Single Input Multiple Output

Selection Combining

Spectrum Sharing System.

Systèmes coopératifs hybride Satellite-Terrestre : analyse de performance et dimensionnement du système / Hybrid Satellite-Terrestrial Cooperative Systems : Performance Analysis and System Dimensioning

Sreng, Sokchenda

11 December 2012

Les systèmes de communications par satellite sont utilisés dans le contexte de la radiodiffusion, de la navigation, du sauvetage et du secours aux sinistrés, car ils permettent de fournir des services sur une large zone de couverture. Cependant, cette zone de couverture est limitée par l'effet de masquage provoqué par des obstacles qui bloquent la liaison directe entre le satellite et un utilisateur terrestre. L'effet de masquage devient plus sévère en cas de satellites à faibles angles d'élévation ou lorsque l'utilisateur est à l'intérieur. Pour résoudre ce problème, les Systèmes Coopératifs Hybride Satellite-Terrestre (HSTCS) ont été proposés. Dans un système HSTCS, l'utilisateur mobile peut profiter de la diversité spatiale en recevant des signaux à la fois du satellite et des relais terrestres. Les gap-fillers fixes ou mobiles sont utilisés pour relayer le signal satellite. La plupart des systèmes de diffusion par satellite utilisent les gap-fillers fixes alors que les gap-fillers mobiles sont nécessaires en cas de communications d'urgence lorsque l'infrastructure fixe n'est pas disponible. Dans les scénarios d'urgence (incendie, tremblement de terre, inondations, explosion) l'infrastructure terrestre existante est endommagée, donc les HSTCSs sont appropriés pour mettre à jour des informations qui permettent aux sauveteurs d'intervenir efficacement et en toute sécurité. En particulier, une mise en œuvre rapide et souple est nécessaire, ce qui pourrait être fourni par le déploiement de gap-fillers mobiles (véhicule ou portable). Plusieurs scénarios coopératifs et techniques de transmission ont déjà été proposés et étudiés. Cependant, la plupart des méthodes proposées ne fournissent qu'une analyse de performance fondée sur la simulation alors que les expressions analytiques de la probabilité de coupure et de la Probabilité d'Erreur Symbole (SEP) n'ont pas encore été établies. Cette thèse se focalise sur l'analyse de performances des systèmes HSTCS. La probabilité de coupure et SEP du système utilisant le schéma de transmission Selective Decode-and-Forward (SDF), avec ou sans sélection de relais, est évaluée dans le cas des modulations MPSK et MQAM. Cette expression analytique permet de concevoir le système HSTCS. Ces résultats sont applicables aux cas des relais fixes ou mobiles. La seconde partie de cette thèse est consacrée à des problèmes de synchronisation (décalage en temps et en fréquence ainsi que l'étalement Doppler). La mobilité des utilisateurs crée l'étalement Doppler qui détruit l'orthogonalité des sous-porteuses dans les signaux de type Orthogonal Frequency Division Multiplexing (OFDM). Cette perte d'orthogonalité engendre de l'interférence entre sous-porteuses (ICI) et donc une dégradation des performances du système en termes de SEP. Dans ce cas, on présente les conditions dans lesquelles cette dégradation peut être compensée par une augmentation du Rapport Signal sur Bruit (SNR) du côté de l'émetteur. Le résultat dépend du schéma de modulation et aussi de la vitesse des utilisateurs. / Satellite communication systems are used in the context of broadcasting, navigation, rescue, and disaster relief since they allow the provision of services over a wide coverage area. However, this coverage area is limited by the masking effect caused by obstacles that block the Line-Of-Sight (LOS) link between the satellite and a terrestrial user. The masking effect becomes more severe in case of low satellite elevation angles or when the user is indoor. To address this issue, Hybrid Satellite-Terrestrial Cooperative Systems (HSTCSs) have been proposed. In an HSTCS, the mobile user can exploit the diversity advantages by receiving signals from both satellite and terrestrial components. Fixed or mobile gap-fillers are used to relay the satellite signal. Most of satellites broadcasting systems have been implemented using fixed gap-fillers while mobile gap-fillers are needed in emergency cases when the fixed infrastructure is not available. In emergency scenarios (e.g., fire, earthquake, flood and explosion), the existing terrestrial infrastructure has been destroyed. So, an HSTCS is appropriate for transmitting the information between the rescuers and the central office. This allows the rescuers to operate efficiently. In particular, a fast and flexible implementation is needed and this could be provided by deploying mobile gap fillers (vehicle or mobile handheld). Recently, the topic of HSTCSs has gain interest in the research community. Several cooperative scenarios and transmission techniques have been proposed and studied. However, most of existing approaches only provide a performance analysis based on simulation results and the analytical expression of the exact Symbol Error Probability (SEP) is generally not provided. This dissertation focuses on the performance analysis of HSTCSs. The exact closed-form outage probability and SEP of Selective Decode-and-Forward (SDF) transmission scheme with and without relay selection are derived for both M-ary phase shift keying (MPSK) and M-ary quadrature amplitude modulation (MQAM) schemes. This analytical SEP helps in designing and dimensioning HSTCSs. Our results are applicable to both fixed and mobile relaying techniques. Another part of the dissertation is dedicated to synchronization issues (time, frequency shifting/spreading). The mobility of users induces a Doppler spread in the Orthogonal Frequency Division Multiplexing (OFDM) signal that destroys the orthogonality of subcarriers. The loss of orthogonality produces Inter-subCarrier Interference (ICI) and hence a degradation of the system performance in terms of SEP. In this case, we present the conditions in which this degradation can be compensated for by an increase in the Signal to Noise Ratio (SNR) at the transmitter side. The result depends on both the modulation scheme and the speed of the mobile users.

Probabilité d'erreur symbole

Probabilité de coupure

Modèle de canal LMS

Symbol error probability

Outage probability

LMS channel models.

Modelos matematicos para estimação do desempenho de sistemas de multiplexação por divisão em frequencias ortogonais / Mathematical models for performance estimation of orthogonal frequency division multiplexing systems

Mendes, Luciano Leonel

26 July 2007

Orientadores: Renato Baldini Filho / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Eletrica e de Computação / Made available in DSpace on 2018-08-09T08:49:59Z (GMT). No. of bitstreams: 1 Mendes_LucianoLeonel_D.pdf: 19765188 bytes, checksum: 2fb7017335865378997ffcdbbf6a3b93 (MD5) Previous issue date: 2007 / Resumo: O objetivo deste trabalho é apresentar uma análise detalhada do desempenho de sistemas OFDM, considerando a ação do ruído, seletividade na resposta em freqüência do canal, mobilidade do receptor, uso de esquemas de diversidade e ceifamento do sinal por parte do amplificador de potência. O procedimento de realização desta análise consiste em determinar expressões analíticas para estimar a probabilidade de erro de símbolo, comparando as expressões teóricas com resultados obtidos por simulações computacionais. O efeito do erro de estimação de canal no desempenho do sistema, considerando os diferentes cenários mencionados, também foi considerado, uma vez que empregou-se diversos algoritmos de estimação de canal nas simulações implementadas. Existe na literatura diversas expressões para estimar a probabilidade de erro de símbolo nas diferentes situações analisadas neste trabalho. No entanto, essas expressões são válidas para as modulações M QAM quadradas. Neste trabalho, expressões válidas para as modulações não quadradas são apresentadas para todos os cenários analisados. Além disso, algumas considerações utilizadas no desenvolvimento da expressão para estimar a probabilidade de erro de símbolo devido ao ceifamento são revistas, o que resulta em uma expressão mais realista. Este trabalho também apresenta uma breve descrição sobre as principais técnicas de controle de potência de pico para sinais OFDM, descrevendo detalhadamente o uso da transformada de Walsh-Hadamard para este fim. A integração desta transformada com todos os esquemas empregados ao longo do trabalho também é apresentada e o desempenho dos esquemas resultantes é comparado com o desempenho dos esquemas convencionais / Abstract: The aim of this work is to present a detailed analysis about the performance of OFDM systems considering noise, frequency selective fading, moving receiver, diversity and signal c1ipping by the high power amplifier. The approach used in the development of this analysis consists on determining analytical equations to estimate the symbol error probability and compare the theoretical results with the ones obtained by computational simulation. The effect of the channel estimation error is also considered in this analysis, once different channel estimation algorithms is employed to estimate the channel frequency response in the developed simulations. In the literature there are several expressions to estimate the symbol error probability in the different situations 'mentioned above. However, these expressions have been developed for square M QAM constellations. This work presents expressions that are also valid for nonsquare M QAM constellations. Also, the expression to estimate the symbol error probability due the c1ipping is rewritten, resulting in a new expression that is more accurate than the original one. This work also presents a short description of the main techniques used to control the peak to average power ratio in OFDM signals. The Walsh-Hadamard Transform technique is detailed described and its integration with all the schemes used in this work is presented. The performance of the resulting integration is compared with the performance of the conventional systems / Doutorado / Telecomunicações e Telemática / Doutor em Engenharia Elétrica

Sistemas de comunicação sem fio

Sistemas de transmissão de dados

Multiplexação

Análise de erros (Matemática)

Sistemas não-lineares

Digital communications

OFDM

Symbol error probability

Diversity

Clipping

Signal design for multi-way relay channels

Sharifian, Shaham

20 December 2016

Today’s communication systems are in need of spectrally efficient and high throughput techniques more than ever because of high data rate applications and the scarcity and expense of bandwidth. To cope with increased data rate demands, more base stations are needed which is not cost and energy efficient in cellular networks. It has been shown that wireless relay networks can provide higher network throughput and increase power efficiency with low complexity and cost. Furthermore, network resources can be utilized more efficiently by using network coding in relay networks. A wireless relay network in which multiple nodes exchange information with the help of relay node(s) is called a multi-way relay channel (MWRC). MWRCs are expected to be an integral part of next generation wireless standards. The main focus of this dissertation is the investigation of transmission schemes in an MWRC to improve the throughput and error performance. An MWRC with full data exchange is assumed in which a half-duplex relay station (RS) is the enabler of communication. One of the challenges with signal demodulation in MWRCs is the existence of ambiguous points in the received constellation. The first part of this dissertation investigates a transmission scheme for full data exchange in MWRC that benefits from these points and improves its throughput by 33% compared to traditional relaying. Then an MWRC is considered where a RS assists multiple nodes to exchange messages. A different approach is taken to avoid ambiguous points in the superposition of user symbols at the relay. This can be achieved by employing complex field network coding (CFNC) which results in full data exchange in two communication phases. CFNC may lead to small Euclidean distances between constellation points, resulting in poor error performance. To improve this performance, the optimal user precoding values are derived such that the power efficiency of the relay constellation is highest when channel state information is available at the users. The error performance of each user is then analyzed and compared with other relaying schemes. Finally, focusing on the uplink of multi-way relay systems, the performance of an MWRC is studied in which users can employ arbitrary modulation schemes and the links between the users and the relay have different gains, e.g. Rayleigh fading. Analytical expressions for the exact average pairwise error probability of these MWRCs are derived. The probability density function (PDF) and the mean of the minimum Euclidean distance of the relay constellation are closely approximated, and a tight upper bound on the symbol error probability is developed. / Graduate

Multi-way Relay

Network Coding

Multiple Access

Broadcast

One-Way Relay Channel

Pulse Amplitude Modulation

Pairwise Error Probability

Plain Routing

Quadrature Amplitude Modulation

Random Variable

Symbol Error Probability

Signal to Noise Ratio

Galois Field

Complex field

Finite Field Network Coding

Infinite Field Network Coding