On the Performance of Full-duplex Two-way Relay Channels with Spatial Modulation

In this paper, the spatial modulation (SM) technique is employed at the source and relay nodes in a full-duplex twoway relay channel (FD-TWRC) to support spectral-efficient bidirectional communications while guaranteeing a low cost implementation. Maximum likelihood (ML) detectors are employed at each node that is subject to an intrinsic self-loop interference (SI). We first propose a tight upper bound on the average bit error probability (ABEP). Then based on the ABEP upper bound, an asymptotic ABEP expression is derived in the high SNR regime. Exploiting the asymptotic ABEP, an exact SNR threshold for the selection between FD-TWRC-SM and half-duplex (HD)-TWRCSM is derived in a closed form, which sheds light on when it is beneficial to select the FD (or HD) mode. In addition, the power allocation (PA) among sources and relay is investigated, through which an optimal PA factor in terms of ABEP is obtained. All analytical results derived in this paper are verified by Monte Carlo simulations, from which some new insights are obtained on the performance of FD-TWRC-SM

Radio Communications

In the last decades the restless evolution of information and communication technologies (ICT) brought to a deep transformation of our habits. The growth of the Internet and the advances in hardware and software implementations modified our way to communicate and to share information. In this book, an overview of the major issues faced today by researchers in the field of radio communications is given through 35 high quality chapters written by specialists working in universities and research centers all over the world. Various aspects will be deeply discussed: channel modeling, beamforming, multiple antennas, cooperative networks, opportunistic scheduling, advanced admission control, handover management, systems performance assessment, routing issues in mobility conditions, localization, web security. Advanced techniques for the radio resource management will be discussed both in single and multiple radio technologies; either in infrastructure, mesh or ad hoc networks

Full duplex-transceivers : architectures and performance analysis

PhD ThesisThe revolution of the 5G communication systems will result in 10,000 times increase in the total mobile broadband traffic in the 2020s, which will increase the demand on the limited wireless spectrum. This has highlighted the need for an efficient frequency-reuse technique that can meet the ever-increasing demand on the available frequency resources. In-band full-duplex (FD) wireless technology that enables the transceiver nodes to transmit and receive simultaneously over the same frequency band, has gained tremendous attention as a promising technology to double the spectral efficiency of the traditional half-duplex (HD) systems. However, this technology faces a formidable challenge, that is the large power difference between the self-interference (SI) signal and the signal of interest from a remote transceiver node. In this thesis, we focus on the architecture of the FD transceivers and investigate their ability to approximately double the throughput and the spectral efficiency of the conventional HD systems. Moreover, this thesis is concerned with the design of efficient self-interference cancellation schemes that can be combined with the architecture of the FD transceiver nodes in order to effectively suppress the SI signal and enable the FD mode. In particular, an orthogonal frequency-division multiplexing (OFDM) based amplify-and-forward (AF) FD physical-layer network coding (PLNC) system is proposed. To enable the FD mode in the proposed system, a hybrid SIC scheme that is a combination of passive SIC mechanism and active SIC technique is exploited at each transceiver node of that system. Next, we propose an adaptive SIC scheme, which utilizes the normalized least-mean-square (NLMS) algorithm to effectively suppress the SI signal to the level of the noise floor. The proposed adaptive SIC is then utilized in a denoise-and-forward (DNF) FD-PLNC system to enable the FD mode. Finally, we introduce a novel overthe- air SIC scheme that can effectively mitigate the SI signal before it arrives the local analog-to-digital converter (ADC) of the FD transceiver nodes. Furthermore, the impact of the hardware impairments on the performance of the introduced SIC scheme is examined and characterized.Iraq, and the Ministry of Higher Education and Scientific Research (MOHSR

Collaborative Distributed Beamforming for Spectrum-Sharing Systems

The scarcity of bandwidth has always been the main obstacle for providing reliable high date-rate wireless links, which are in great demand to accommodate nowadays and immediate future wireless applications. In addition, recent reports have showed inefficient usage and under-utilization of the available bandwidth. Cognitive radio (CR) has recently emerged as a promising solution to enhance the spectrum utilization, where it offers the ability for unlicensed users to access the licensed spectrum opportunistically. On one hand, by allowing opportunistic spectrum access, the overall spectrum utilization can be improved. On the other hand, transmission from cognitive nodes can cause severe interference to the licensed users of the spectrum. This requires cognitive radio networks (CRNs) to consider two essential design targets, namely, maximizing the spectrum utilization and minimizing the interference caused to the primary users (PUs). Such interference can be reduced through proper resource allocation, power control or other degrees of freedom techniques such as beamforming. In this thesis, we aim to use joint distributed beamforming and cooperative relaying in spectrum-sharing systems in an effort to enhance the spectrum efficiency and improve the performance of the secondary system. We investigate a one-way cooperative spectrum-sharing system in the presence of one PU and multiple PUs. We study two relaying schemes, namely, decode-and-forward (DF) and amplify-and-forward (AF) relaying in conjunction with distributed optimal beamforming. We employ zero forcing beamforming (ZFB) as a sub-optimal scheme, and compare both approaches through simulations. For both schemes, we derive closed-form expressions and asymptotic expressions for the outage probability and bit error rate (BER) over independent and identically distributed Rayleigh fading channels for binary phase shift keying (BPSK) and M-ary quadrature amplitude modulation (M-QAM) schemes. Numerical results show the effectiveness of the combination of the cooperative diversity and distributed beamforming in compensating for the loss in the secondary system's performance due to the primary user's co-channel interference (CCI). To further improve the spectrum efficiency, we employ distributed beamforming in two-way AF cooperative spectrum-sharing systems in the presence of multiple PUs. For this system, we investigate the transmission protocols over two, three and four time-slots. Our results show that the three time-slot protocol outperforms the two time-slot and four time-slot protocols in certain scenarios where it offers a good compromise between bandwidth efficiency and system performance. We extend the two-way relaying system to the DF scheme, where two practical two-way relaying strategies are investigated, namely, DF-XORing (bit-wise level) and DF-superposition (symbol-wise level). For each relaying strategy, we derive general optimal beamforming vectors and sup-optimal ZFB vectors at the relays. Employing ZFB, we present an analytical framework of the secondary system considering the effect of the primary-secondary mutual CCIs. Our results show that, when the received signals at the relays are weighted equally, the DF-XOR always outperforms both DF-superposition and AF relaying. In the last part of the thesis, we consider a limited feedback system model by assuming partial channel state information (CSI) of the interference channel between the secondary relays and primary receiver. In particular, the CSI feedback is limited only to the quantized channel direction information (CDI). To investigate the effect of the quantized CDI on the secondary system's performance, we derive closed-form expressions for the outage probability and the BER considering the mutual secondary-primary CCI. In the simulation results, we compare the system performance of the limited feedback with the perfect CSI. Our results show that the performance improves as the number of feedback bits increases

The Multispectral Imaging Science Working Group. Volume 3: Appendices

The status and technology requirements for using multispectral sensor imagery in geographic, hydrologic, and geologic applications are examined. Critical issues in image and information science are identified