Performance of Two-Hop DS-CDMA Systems Using Amplify-and-Forward Protocol over Different Fading Channels

This study analyses the performance of directsequence code division multiple access (DS-CDMA) based on two-hop amplify-and-forward protocol over Weibull symmetric fading channels as well as Rayleigh/Rician, Rician/Rayleigh asymmetric fading phenomenas. We investigate the bit-error rate (BER) of the considered system using multiple relays by considering the effect of Weibull fading parameter and Rician K factor on the system performance. Our simulation results demonstrate the positive impacts of the value of fading parameter, Rician K factor and increasing number of relay nodes on BER performance. It is also confirmed that the Rician K factor is more effective on the system performance over Rician/Rayleigh fading channels in comparison with Rayleigh/Rician fading environment

Design And Performance Analysis Of Enhanced Network Coded Cooperative Communication Systems

Tez (Yüksek Lisans) -- İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, 2017Thesis (M.Sc.) -- İstanbul Technical University, Institute of Science and Technology, 2017Kablosuz haberleşme sistemi birbiriyle haberleşebilen birçok hareketli düğüm noktasından oluşmaktadır. Sönümleme ise kablosuz haberleşme sistemlerinin performansını olumsuz yönde etkileyen önemli faktörlerden biridir. Sönümlemenin mevcut olduğu ortamlarda güvenilir bir haberleşme için kanal kodlama ve çeşitleme teknikleri önerilmiş ve uygulanmıştır. Bunlardan biri, çeşitleme kazancı elde ederek olabildiğince hatasız veri iletimi gerçekleştirmek üzere her bir terminalde çoklu verici ve alıcı düğümleri kullanan çok girişli çok çıkışlı çeşitleme (MIMO) tekniğidir. Fakat işbirlikli çeşitleme tekniği bunu her bir terminalde birden çok verici anten kullanmadan gerçekleştirebilmektedir. Kablosuz yayın ortamı komşu röle düğümlerin işbirliği yapmasına imkan sağlayarak verinin kaynak düğümlerden hedef düğümlere aktarılması sırasındaki sönümleme etikisini azaltmaktadır. Bu sebeple, işbirlikli haberleşme sistemi veri iletimi sırasında röle düğümler ile oluşturulan birden çok haberleşme ağının kullanılmasını ve kendiliğinden oluşan uzaysal kanal çeşitlemesinden faydalanılmasını mümkün kılmaktadır. Doğrudan veri iletimi kullanan klasik tek atlamalı haberleşme sistemlerinde bir alıcı doğrudan gelen işaretin içerisindeki veriyi elde ederek yansıyan işaretleri girişim olarak algılarken, işbirlikli haberleşme sistemleri diğer işaretleri katkı olarak değerlendirmektedir. Böylelikle işbirlikli çeşitlemede veri iki ya da daha çok işaretin birlikte değerlendirilmesiyle elde etmektedir. Başka bir deyişle, işbirlikli çeşitleme kablosuz haberleşme ağlarında bulunan her bir düğümdeki antenin dağıtık olarak kullanıldığı bir anten çeşitleme tekniğidir. Hareketli düğümlerin (mobile nodes) güç, bant genişliği ve boyut gibi kısıtları sebebiyle diğer çeşitleme tekniklerinin kanal sönümlemesine karşı kullanılamadığı kablosuz tasarsız (ad hoc) algılayıcı ağları için işbirlikli çeşitleme özellikle faydalı olmaktadır. Bütün senaryolar için, hareketli kullanıcılar arasında işbirliği olan kablosuz sistemler bu işbirliğinin olmadığı diğer sistemlere göre daha yüksek bir sığa potansiyeline sahiptir. Fakat, işbirlikli haberleşme ile hata performansında elde edilen iyileşme çoğu durumda kablosuz ağdaki iletim hızından feragat ile mümkündür. Bu gibi durumlarda, ağ kodlama tekniği sayesinde röle düğümlere gönderilmiş olan veri paketlerinin akıllı bir şekilde birleştirilmesi ile işbirlikli kablosuz ağlardaki veri hızında ciddi bir iyileştirme sağlanabilmektedir. Ağ kodlama esasen kayıpsız haberleşme sistemlerinde yönlendirme ağlarının verimini artırmak için geliştirilmiştir. Fakat, ağ kodlama ile işbirlikli kablosuz ağların tümleştirilmesi (entegrasyonu) sönümlemenin bulunduğu ortamlarda kaynakların daha verimli bir şekilde kullanılması ve hata performansının iyileştirilmesi yönünde ciddi bir potansiyele sahiptir. Ağ kodlama, 5G standartlarının ötesindeki kablosuz ağlarda sürekli artan kullanıcı ve cihazların taleplerini karşılayabilecek kabiliyete sahiptir. Kablosuz sistemlerin yayın doğası işbirlikli haberleşme ve ağ kodlamanın beraber uygulanmasını ve bu iki tekniğin faydalarından yararlanmayı mümkün kılmaktadır. Bu bağlamda, son yıllarda mevcut literatürde çeşitli ağ kodlama teknikleri değerlendirilmekte fakat her yöntem röle düğümlerdeki veri paketleri işlevlerinin birleştirilmesi ve iletilmesini kapsamaktadır. Bu tezde, rastgele doğrusal ağ kodlama, karmaşık alan ağ kodlama ve XOR ağ kodlama tekniklerinin benzetimleri yapılmış ve çeşitli bakış açıları ile analiz edilmiştir. Tezin ilk bölümünde, Rayleigh ve Rician sönümleme kanalları için varış düğümlerindeki kod çözme hata olasılığı üzerinden rastgele doğrusal ağ kodlama sistemlerinin performansı incelenmektedir. Doğrusal ağ kodlama sistemlerinde, ara düğümlerdeki veri bitleri paket vektörler olarak alınmakta ve ara düğümler belirli bir boyutta ve eşit olasılıklı Galois kümesinden çıkarılan katsayılar ile alınan paketleri doğrusal olarak birleştirerek veriyi çözmektedir. Bu bölümdeki benzetim ortamı birden çok kaynak ile röle ve varış düğümlerinden oluşmakta; kaynak ve varış noktaları arasında ise doğrudan bağlantılar bulunmamaktadır. Belirtilen sistemdeki haberleşme kanalı kesintileri ve dolayısıyla paket kayıpları sönümleme etkisiyle oluşmaktadır. Belirtilen sistem modeli için ortaya çıkan benzetim sonuçları, paket çözümündeki kayıp olasılığının sadece sönümleme ortamı değil röle düğümlerde ağ kodlama için kullanılan katsayılar tarafından da belirlendiğini göstermektedir. Sönümleme kanallarındaki çözümleme kayıp olasılıkları röle düğümlerdeki paketlerin doğrusal olarak birleştirilmesi sırasında kullanılan rastgele katsayıları barındıran Galois kümesinin boyutu artırılarak düşürülebilmektedir. Tezin ikinci kısmında ise, karmaşık alan ağ kodlamasının bit hat oranı performansı frekans seçmeli Rayleigh sönümleme kanalları için dik frekans bölmeli çoğullama (OFDM) kullanılarak analiz edilmiştir. Daha önceki çalışmalarda, bu analiz düz sönümleme kanalları için yapılmıştır. Performans değerlendirmesinde kullanılan sistem modeli birden çok kaynak düğümü, tekli ya da çoklu röle düğümleri ve tek varış düğümü içermektedir. Hem kuvvetlendir ve aktar hem de çöz ve aktar tipi röleler için hata performansı elde edilmekte ve çoklu röle sistemleri için röle seçimi hem kuvventlendir ve aktar hem de çöz ve aktar seçenekleri için ele alınmaktadır. Katlamalı kanal kodları da opsiyonel olarak mevcut sisteme performansı artırmak için eklenebilmekte ve sert kararlı (hard decision) Viterbi Algoritması kaynak bitleri çözmek için kullanılmaktadır. Buna ek olarak, kaynak ve varış noktalarına farklı uzaklıklardaki röle düğümlerinde asimetrik bağlantı ortamları da değerlendirilmiştir. Daha önce bahsedilen senaryo kapsamında hedef ve/veya röle düğümlerde her bir bitin aynı zamanda elde edilmesi için OFDM ile birlikte çoklu kullanıcı belirleme kuralları uygulanmıştır. Benzetim sonuçları, rölelerdeki analog dalga formunun kaydedilmesini gerektirmesi dolayısıyla uygulama açısından pratik olmasa da her durumda kuvvetlendir ve aktar röle düğümlerinin, çöz ve aktar tipi röle düğümlerinden daha iyi performansa sahip olduğunu göstermektedir. Dahası, sistem modelinde hem kuvvetlendir ve aktar hem de çöz ve aktar tipi röleler ile röle seçimi yapıldığında hata performansında hatırı sayılır bir iyileştirme gözlenmektedir. Son olarak, asimetrik ağlarda, daha iyi bir hata performansı röle düğümlerinin kaynak düğümlerine daha yakın yerleştirilmesi ile elde edilebilmektedir. Tezin üçüncü kısmında, ele alınan tekniklerin faydalı yönlerini birleştirecek şekilde, OFDM kullanan kanal kodlamalı karmaşık alan ağ kodlama tekniği önerilmekte ve bit hata oranı üzerinden performans değerlendirmesi yapılmaktadır. Buradaki çalışma OFDM kullanan katlamalı kanal kodlamalı karmaşık alan ağ kodlama ve ikinci bölümde bahsedilen sert kararlı (hard decision) Viterbi Algoritmasının genişletilmesidir. Sistem modeli ikinci kısımdaki ile aynı olmakla birlikte yavaş ve frekans seçimli Rayleigh sönümleme kanalı içermektedir. Yine hem kuvvetlendir ve aktar hem de çöz ve aktar türü röleler bu bağlamda değerlendirilmiş ve birden çok röle içeren senaryolarda röle seçimi uygulanmıştır. Fakat, bu bölümde kodlanmış kaynak bitlerinin elde edilmesi için yumuşak kararlı (soft decision) Viterbi Algoritması ve Max-Log-MAP kod çözme teknikleri kullanılmakta ve böylelikle çok kullanıcı belirleme kuralları kodlanmış kaynak bitleri için log likelihood oranlarını sağlamaktadır. Dahası, kafeste farklı kod oranlarına ve durum sayılarına sahip katlamalı kodlar ve asimetrik bağlantı ortamları için performans analizi verilmektedir. Benzetim sonuçlarına göre, hem yumuşak kararlı Viterbi hem de Max- Log-MAP kanal çözümleme tekniklerinin belirtilen sistem modelinde aynı bit hatası performansına sahip olduğu görülmektedir. Kuvventlendir ve aktar yöntemi çöz ve aktar yöntemine göre her durumda daha iyi sonuç vermekte ve röle seçim teknikleri fark edilir bir performans iyileştirmesine sebep olmaktadır. Daha düşük kod oranlı ve daha çok kafes durumuna (trellis state) sahip katlamalı kodlar sistem performansını ciddi bir şekilde artırmakta ve asimetrik bağlantılarda aynı şekilde performansın iyileştirilmesi amacına katkı yapmaktadır. Tezin son bölümü OFDM ile birleştirilmiş iki yönlü röle ağları için XOR ağ kodlama tekniğinin geliştirilmiş versiyonu ile ilgilidir. İki yönlü röle ağları için geliştirilen geleneksel stratejiler ile karşılaştırıldığında, bu stratejide Galois küme eklemesi veya kaynaklarda çoklu veri paketlerinin bit XOR kodlaması uygulanmaktadır. XOR kodlamalı paket, iki yönlü röle ağının hata performansını artırmak için verici çeşitleme kazancı elde etmek üzere artıklık barındıran veri paketleri ile birlikte röle düğümlerine iletilmektedir. Sistem modeli, iki kaynak ve istenen hata performansının elde edilmesi için farklı sayıda ve katlamalı kanal kodlamalı röle düğümleri içermektedir. Sistemde birden çok röle olduğu durumda röle seçimi de yapılmakta ve bu sayede sadece hata performansı artırılmamakta aynı zamanda verimlilik de artmaktadır. Sonuçlar, iki yönlü röle ağının iletim ucunda sağlanan artıklık ile sistemde bit hatası performansının artırıldığını göstermektedir.A wireless communication system consists of multiple wireless nodes that can move around and communicate with each other. Fading is one of major degrading factors that can limit the performance of wireless communication systems. In order to achieve reliable communication in fading environments, channel coding and diversity techniques were proposed and implemented. Multiple input multiple output (MIMO) is one of the diversity techniques which uses multiple transmission and reception nodes per terminal to obtain diversity gains for reduced errors in the transmission of data. But cooperative diversity techniques can realize this purpose without installing multiple transmission antennas per terminal. The broadcasting nature of wireless medium allows neighbouring relay nodes to cooperate in communication by forwarding information from source nodes to destination nodes for fading mitigation. Therefore, cooperative communication system utilizes multiple communication routes created by relay nodes and exploits the inherent spatial diversity of the channel for information transmission. While classical single hop communication systems use direct transmission in which a receiver recovers the information using the direct signal only and regarding the reflected signal as interference, the cooperative communication systems consider the other signal as contribution. Therefore, cooperative diversity retrieves information from the combination of two or more signals. In other words, cooperative diversity is a virtual antenna diversity technique that uses distributed antennas belonging to each node in a wireless network for communication. Cooperative diversity is particularly considered useful in wireless ad hoc and sensor networks, where power/bandwidth/size restrictions of the mobile nodes may prevent the use of other diversity techniques to combat channel fading. In all scenarios, cooperation among mobile users of a wireless system has the potential to provide an increased capacity in comparison with the systems without using cooperation. However, in most cases, cooperative communication attains this improvement in error performance by sacrificing the throughput of wireless network. In such cases, network coding technique can substantially improve the data rate of cooperative wireless networks by intelligently combining the forwarded packets of information at the relay nodes. Network coding was originally proposed for lossless communication systems to increase the throughput of routing networks. But the integration of network coding with cooperative wireless networks has the potential to ensure more efficient usage of resources with improved error performance in fading environments. Network coding can ensure the capability to address the ever increasing number of users and devices in wireless networks, in beyond 5G standards. The broadcast nature of wireless systems allows the joint implementation of cooperative communication and network coding, exploiting the benefits of both techniques. In this context, several types of network coding have been discussed in literature in the recent years but each type involves the concept of combining and transmitting the functions of information packets at the relay nodes. In this thesis, random linear network coding, complex field network coding and exclusive-OR (XOR) network coding are simulated and analyzed in different perspectives. In the first part of this thesis, the performance of random linear network coding systems is investigated for Rayleigh and Rician fading channels in terms of decoding failure probabilities at destination nodes. In random linear network coding systems, the information bits at the intermediate nodes are received as packet vectors and the intermediate nodes encode the information data by linearly combining the received packets, with coefficients randomly extracted from the Galois field of a particular size, with equal probability. The setup considered in this section consists of multiple source, relay and destination nodes, with no direct links between sources and destinations. The communication channel outage and hence the packet loss in the given system occurs due to fading. The simulation results for the supposed system model show that the packet decoding failure probabilities are not only determined by the fading environment but also by the coefficients used in the network coding at the relay nodes. In fading channels, decoding failure probabilities can be reduced by increasing the size of the Galois field that contains random coefficients for linear combination of packets at relay nodes. In the second part of this thesis, the bit error rate performance of complex field network coding is analyzed with orthogonal frequency division multiplexing (OFDM) for frequency selective Rayleigh fading channels. In previous literatures, this analysis is performed for flat fading channels. The system model used in the performance evaluation contains multiple source nodes, single or multiple relay nodes and a single destination node. Both amplify and forward as well as decode and forward types of relays are assumed to obtain error performance results and for multi-relay system, relay selection is also taken into account for both amplify and forward and decode and forward relay types. Convolutional channel codes are also optionally integrated in the given system to boost the system performance and hard decision Viterbi decoding is used to decode source bits. In addition to this, asymmetric link environments, with relay nodes at different distances from sources and destination, are also considered. Multiuser detection rules with OFDM are employed at destination node and/or relay nodes to retrieve each source bits at the same time, for the above mentioned scenarios. The simulation results indicate that amplify and forward relay nodes outperform decode and forward relay nodes in all cases but are not very suitable from the implementation perspective since they require the storage of analog waveform at relays. Moreover, a considerable improvement is error performance can be observed when relay selection is provided in the system model with both amplify and forward and decode and forward types of relays. Finally, in asymmetric network, better error performance can be achieved by placing relay nodes closer to the source nodes. The third part of this thesis proposes the channel coded complex field network coding with OFDM, combining the mutual benefits of all the techniques involved and the performance evaluation is made in terms of bit error rate. This work is the extension of the Convolutional channel coded complex field network coding with OFDM and hard decision Viterbi decoding, presented in the second part. The system model is same as the second part with slow and frequency selective Rayleigh fading channel. Again, both amplify and forward and decode and forward types of relays are considered in this context and relay selection is employed in scenarios with multiple relays. However, this part uses soft decision Viterbi and Max-Log-MAP decoding techniques for obtaining coded source bits and therefore, in this case, the multiuser detection rules provide log likelihood ratios for coded source bits. Moreover, the performance analysis is provided for Convolutional codes with different code rates and number of states in the trellis as well as for asymmetric link environments. From simulation results, it is seen that both soft decision Viterbi and Max-Log-MAP channel decoding techniques provide almost same bit error performance in the given system model. Amplify and forward performs better than decode and forward in all cases and relay selection techniques results in a noticeable performance gain. Convolutional codes with lower code rate and more number of trellis states can enhance the system performance considerably and asymmetric links also serve the similar purpose of performance improvement. The final part of thesis is related to an enhanced version of XOR network coding scheme for two-way relay networks, combined with OFDM. Compared to other conventional strategies for two-way relay networks, this strategy performs Galois field addition or bit-wise XOR coding of multiple information packets at sources. The XOR coded packet is transmitted to the relay nodes along with the information packets which facilitates redundancy to acquire transmit diversity gain for improving error performance of the two-way relay network. The system model consists of two source and different number of relay nodes with Convolutional channel encoding in the system to obtain desired error performance. Relay selection is also provided when there are multiple relays in the system and this provision not only improves the error performance but also gives better throughput. The results show that the redundancy provided at the transmission end of two-way relay network enhances bit error performance of the system.Yüksek LisansM.Sc

Ultra Reliable UAV Communication Using Altitude and Cooperation Diversity

The use of unmanned aerial vehicles (UAVs) that serve as aerial base stations is expected to become predominant in the next decade. However, in order for this technology to unfold its full potential it is necessary to develop a fundamental understanding of the distinctive features of air-to-ground (A2G) links. As a contribution in this direction, this paper proposes a generic framework for the analysis and optimization of the A2G systems. In contrast to the existing literature, this framework incorporates both height-dependent path loss exponent and small-scale fading, and unifies a widely used ground-to-ground channel model with that of A2G for analysis of large-scale wireless networks. We derive analytical expressions for the optimal UAV height that minimizes the outage probability of a given A2G link. Moreover, our framework allows us to derive a height-dependent closed-form expression and a tight lower bound for the outage probability of an \textit{A2G cooperative communication} network. Our results suggest that the optimal location of the UAVs with respect to the ground nodes does not change by the inclusion of ground relays. This enables interesting insights in the deployment of future A2G networks, as the system reliability could be adjusted dynamically by adding relaying nodes without requiring changes in the position of the corresponding UAVs

Energy harvesting over Rician fading channel: A performance analysis for half-duplex bidirectional sensor networks under hardware impairments

In this paper, a rigorous analysis of the performance of time-switching energy harvesting strategy that is applied for a half-duplex bidirectional wireless sensor network with intermediate relay over a Rician fading channel is presented to provide the exact-form expressions of the outage probability, achievable throughput and the symbol-error-rate (SER) of the system under the hardware impairment condition. Using the proposed probabilistic models for wireless channels between mobile nodes as well as for the hardware noises, we derive the outage probability of the system, and then the throughput and SER can be obtained as a result. Both exact analysis and asymptotic analysis at high signal-power-to-noise-ratio regime are provided. Monte Carlo simulation is also conducted to verify the analysis. This work confirms the effectiveness of energy harvesting applied in wireless sensor networks over a Rician fading channel, and can provide an insightful understanding about the effect of various parameters on the system performance.Web of Science186art. no. 1781

Finite Random Matrix Theory Analysis of Multiple Antenna Communication Systems

Multiple-antenna systems are capable of providing substantial improvement to wireless communication networks, in terms of data rate and reliability. Without utilizing extra spectrum or power resources, multiple-antenna technology has already been supported in several wireless communication standards, such as LTE, WiFi and WiMax. The surging popularity and enormous prospect of multiple-antenna technology require a better understanding to its fundamental performance over practical environments. Motivated by this, this thesis provides analytical characterizations of several seminal performance measures in advanced multiple-antenna systems. The analytical derivations are mainly based on finite dimension random matrix theory and a collection of novel random matrix theory results are derived. The closed-form probability density function of the output of multiple-input multiple-output (MIMO) block-fading channels is studied. In contrast to the existing results, the proposed expressions are very general, applying for arbitrary number of antennas, arbitrary signal-to-noise ratio and multiple classical fading models. Results are presented assuming two input structures in the system: the independent identical distributed (i.i.d.) Gaussian input and a product form input. When the channel is fed by the i.i.d. Gaussian input, analysis is focused on the channel matrices whose Gramian is unitarily invariant. When the channel is fed by a product form input, analysis is conducted with respect to two capacity-achieving input structures that are dependent upon the relationship between the coherence length and the number of antennas. The mutual information of the systems can be computed numerically from the pdf expression of the output. The computation is relatively easy to handle, avoiding the need of the straight Monte-Carlo computation which is not feasible in large-dimensional networks. The analytical characterization of the output pdf of a single-user MIMO block-fading channels with imperfect channel state information at the receiver is provided. The analysis is carried out under the assumption of a product structure for the input. The model can be thought of as a perturbation of the case where the statistics of the channel are perfectly known. Specifically, the average singular values of the channel are given, while the channel singular vectors are assumed to be isotropically distributed on the unitary groups of dimensions given by the number of transmit and receive antennas. The channel estimate is affected by a Gaussian distributed error, which is modeled as a matrix with i.i.d. Gaussian entries of known covariance. The ergodic capacity of an amplify-and-forward (AF) MIMO relay network over asymmetric channels is investigated. In particular, the source-relay and relay-destination channels undergo Rayleigh and Rician fading, respectively. Considering arbitrary-rank means for the relay-destination channel, the marginal distribution of an unordered eigenvalue of the cascaded AF channel is presented, thus the analytical expression of the ergodic capacity of the system is obtained. The results indicate the impact of the signal-to-noise ratio and of the Line-of-Sight component on such asymmetric relay network

Cooperative diversity techniques for high-throughput wireless relay networks

Relay communications has attracted a growing interest in wireless communications with application to various enhanced technologies. This thesis considers a number of issues related to data throughput in various wireless relay network models. Particularly, new implementations of network coding (NC) and space-time coding (STC) techniques are investigated to offer various means of achieving high-throughput relay communications. Firstly, this thesis investigates different practical automatic repeat request (ARQ) retransmission protocols based on NC for two-way wireless relay networks to improve throughput efficiency. Two improved NC-based ARQ schemes are designed based on go-back-N and selective-repeat (SR) protocols. Addressing ARQ issues in multisource multidestination relay networks, a new NC-based ARQ protocol is proposed and two packet-combination algorithms are developed for retransmissions at relay and sources to significantly improve the throughput. In relation to the concept of channel quality indicator (CQI) reporting in two-way relay networks, two new efficient CQI reporting schemes are designed based on NC to improve the system throughput by allowing two terminals to simultaneously estimate the CQI of the distant terminal-relay link without incurring additional overhead. The transmission time for CQI feedback at the relays is reduced by half while the increase in complexity and the loss of performance are shown to be negligible. Furthermore, a low-complexity relay selection scheme is suggested to reduce the relay searching complexity. For the acknowledgment (ACK) process, this thesis proposes a new block ACK scheme based on NC to significantly reduce the ACK overheads and therefore produce an enhanced throughput. The proposed scheme is also shown to improve the reliability of block ACK transmission and reduce the number of data retransmissions for a higher system throughput. Additionally, this thesis presents a new cooperative retransmission scheme based on relay cooperation and NC to considerably reduce the number of retransmission packets and im- prove the reliability of retransmissions for a more power efficient and higher throughput system with non-overlapped retransmissions. Moreover, two relay selection schemes are recommended to determine the optimised number of relays for the retransmission. Finally, with respect to cognitive wireless relay networks (CWRNs), this thesis proposes a new cooperative spectrum sensing (CSS) scheme to improve the spectrum sensing performance and design a new CSS scheme based on NC for three-hop CWRNs to improve system throughput. Furthermore, a new distributed space-time-frequency block code (DSTFBC) is designed for a two- hop nonregenerative CWRN over frequency-selective fading channels. The proposed DSTFBC design achieves higher data rate, spatial diversity gain, and decoupling detection of data blocks at all destination nodes with a low-complexity receiver structure

Capacity and performance analysis of advanced multiple antenna communication systems

Multiple-input multiple-output (MIMO) antenna systems have been shown to be able to substantially increase date rate and improve reliability without extra spectrum and power resources. The increasing popularity and enormous prospect of MIMO technology calls for a better understanding of the performance of MIMO systems operating over practical environments. Motivated by this, this thesis provides an analytical characterization of the capacity and performance of advanced MIMO antenna systems. First, the ergodic capacity of MIMO Nakagami-m fading channels is investigated. A unified way of deriving ergodic capacity bounds is developed under the majorization theory framework. The key idea is to study the ergodic capacity through the distribution of the diagonal elements of the quadratic channel HHy which is relatively easy to handle, avoiding the need of the eigenvalue distribution of the channel matrix which is extremely difficult to obtain. The proposed method is first applied on the conventional point-to-point MIMO systems under Nakagami-m fading, and later extended to the more general distributed MIMO systems. Second, the ergodic capacity of MIMO multi-keyhole and MIMO amplify-and-forward (AF) dual-hop systems is studied. A set of new statistical properties involving product of random complex Gaussian matrix, i.e., probability density function (p.d.f.) of an unordered eigenvalue, p.d.f. of the maximum eigenvalue, expected determinant and log-determinant, is derived. Based on these, analytical closedform expressions for the ergodic capacity of the systems are obtained and the connection between the product channels and conventional point-to-point MIMO channels is also revealed. Finally, the effect of co-channel interference is investigated. First, the performance of optimum combining (OC) systems operating in Rayleigh-product channels is analyzed based on novel closed-form expression of the cumulative distribution function (c.d.f.) of the maximum eigenvalue of the resultant channel matrix. Then, for MIMO Rician channels and MIMO Rayleigh-product channels, the ergodic capacity at low signal-to-noise ratio (SNR) regime is studied, and the impact of various system parameters, such as transmit and receive antenna number, Rician factor, channel mean matrix and interference-tonoise- ratio, is examined