Non-Orthogonal Multiple Access Schemes with Partial Relay Selection

In this paper, non-orthogonal multiple access (NOMA) in amplify-and-forward relay systems with partial relay selection (PRS) is investigated. More specifically, new exact closed-form expressions for the outage probabilities at two users are derived, based on which an asymptotic analysis at high signal- to-noise ratio (SNR) is carried out. Additionally, in order to investigate the performance gap between the NOMA and orthogonal multiple access (OMA) schemes, a closed-form approximate expression at high SNR for the sum rate is derived. Furthermore, relying on our results, the impact of the PRS on the sum rate and outage probability of the proposed NOMA scheme is examined. In particular, the derived asymptotic expressions show that the proposed scheme can improve over the traditional OMA not only the sum rate but also the user fairness. Finally, simulation results are presented to corroborate the analytical results

Non-orthogonal multiple access schemes with partial relay selection

In this paper, non-orthogonal multiple access (NOMA) in amplify-and-forward relay systems with partial relay selection (PRS) is investigated. More specifically, new exact closed-form expressions for the outage probabilities at two users are derived, based on which an asymptotic analysis at high signal- to-noise ratio (SNR) is carried out. Additionally, in order to investigate the performance gap between the NOMA and orthogonal multiple access (OMA) schemes, a closed-form approximate expression at high SNR for the sum rate is derived. Furthermore, relying on our results, the impact of the PRS on the sum rate and outage probability of the proposed NOMA scheme is examined. In particular, the derived asymptotic expressions show that the proposed scheme can improve over the traditional OMA not only the sum rate but also the user fairness. Finally, simulation results are presented to corroborate the analytical results

Non-Orthogonal Multiple Access schemes for Next Generation Cellular Networks: System Model and Performance Consideration

The dissertation deals with next generation cellular networks, especially in regard to the integration of wireless networks which apply non-orthogonal multiple access (NOMA) and other advanced techniques such as multi-antennae, radio frequency energy harvesting (EH), physical layer security (PLS) and satellite communication. Firstly, the dissertation investigates a multi-antenna transmission model to enhance the performance of communications. A novel model of power distribution to NOMA users, who joined both direct link and relay link, is designed to improve transmission quality. Further, we deploy the power beacon, which is able to feed energy to power-constraint relay node to further support transmission to destinations. Secondly, the dissertation studies the secrecy performance of a PLS in cognitive radio (CR)-NOMA networks. The multi-input single-output (MISO) architecture combining transmit antenna selection (TAS) strategy is considered to achieve secure performance analysis such as the secrecy outage probability (SOP). Further, optimal power allocation (PA) factor can be obtained to optimize SOP performance. Since the presence of an illegitimate user, we improve the SOP by adopting relay selection (RS) combining decode-and-forward (DF) with full-duplex (FD)relaying. Finally, as the strongest contribution of the dissertation, an application of the NOMA technique, which improves the spectral efficiency, in satellite networks is introduced. Satellite communication systems integrate with emerging small-cell networks to provide seamless connectivity and high-speed broadband access for mobile users in future wireless networks. In the dissertation, we study a hybrid satellite-terrestrial relay system (HSTRS). To characterizing the HSTRS-assisted small-cell network, Shadowed-Rician fading for satellite links and Nakagami-m fading for terrestrial links are adopted.Disertační práce se zabývá buňkovými sítěmi příští generace, zejména s ohledem na integraci bezdrátových sítí, které používají neortogonální vícenásobný přístup (NOMA) a další pokročilé techniky, jako jsou víceanténové systémy, získávání energie z elektromagnetického záření (EH), zabezpečení fyzické vrstvy (PLS) a satelitní komunikace. Disertační práce nejprve zkoumá model komunikace s více anténami s cílem dosáhnout vyšší efektivity přenosu. Nový model distribuce energie uživatelům NOMA, kteří se připojili přímým spojem anebo zprostředkovaně (přes realy uzel), je navržen tak, aby zlepšil kvalitu přenosu. Dále je v modelu navržen výkonový maják, který je schopen dodávat energii do relay uzlu, aby podpořil přenos k příjemcům. Za druhé, disertační práce studuje výkonnost PLS v sítích kognitivního rádia (CR)-NOMA. V návrhu je uvažována architektura více vstupů s jedním výstupem (MISO) kombinující strategii výběru vysílací antény (TAS), přičemž úroveň zabezpečení je zkoumána metrikou pravděpodobnosti výpadku utajení (SOP). Dále lze pro optimalizaci výkonu SOP získat faktor optimálního přidělování energie (PA). Vzhledem k předpokládané přítomnosti nelegitimního uživatele vylepšujeme SOP pomocí výběru relay uzlu (RS) kombinující režimy dekóduj a přepošli (DF) s plně duplexním (FD) přenosem. A konečně, jako nejsilnější přínos disertační práce, je představena aplikace techniky vícenásobného přístupu NOMA v satelitních sítích, která vylepšuje spektrální účinnost. Satelitní komunikační systémy se integrují s nově vznikajícími buňkovými sítěmi malého dosahu. Zajišťují bezproblémové připojení a vysokorychlostní širokopásmový přístup pro mobilní uživatele v budoucích bezdrátových sítích. V disertační práci studujeme hybridní satelitně-terestrický relay systém (HSTRS). K popisu sítě malých buněk s asistencí HSTRS je v případě satelitní komunikace použit útlumový model "Shadowed-Rician" a v případě terestrické pak "Nakagami-m."440 - Katedra telekomunikační technikyvyhově

On Throughput Maximization of Grant-Free Access with Reliability-Latency Constraints

Enabling autonomous driving and industrial automation with wireless networks poses many challenges, which are typically abstracted through reliability and latency requirements. One of the main contributors to latency in cellular networks is the reservation-based access, which involves lengthy and resource-inefficient signaling exchanges. An alternative is to use grant-free access, in which there is no resource reservation. A handful of recent works investigated how to fulfill reliability and latency requirements with different flavors of grant-free solutions. However, the resource efficiency, i.e., the throughput, has been only the secondary focus. In this work, we formulate the throughput of grant-free access under reliability-latency constraints, when the actual number of arrived users or only the arrival distribution are known. We investigate how these different levels of knowledge about the arrival process influence throughput performance of framed slotted ALOHA with $K$-multipacket reception, for the Poisson and Beta arrivals. We show that the throughput under reliability-latency requirements can be significantly improved for the higher expected load of the access network, if the actual number of arrived users is known. This insight motivates the use of techniques for the estimation of the number of arrived users, as this knowledge is not readily available in grant-free access. We also asses the impact of estimation error, showing that for high reliability-latency requirements the gains in throughput are still considerable.Comment: Accepted for publication in ICC'201

3-D Hybrid VLC-RF Indoor IoT Systems with Light Energy Harvesting

In this paper, a 3-dimensional (3-D) hybrid visible light communication (VLC)-radio frequency (RF) indoor internet of things system with spatially random terminals with one photodiode (e.g., indoor sensors: temperature sensors, humidity sensors, and indoor air quality sensors) is considered. Specifically, homogeneous Poisson point process is adopted to model to the distribution of the terminals, which means that the number of the terminals obeys Poisson distribution, and the positions of the terminals are uniformly distributed. VLC and RF communications are employed over downlink and uplink, respectively. Meanwhile, the terminals are designed to harvest the energy from the light emitted by the light-emitting diode over the downlink, which is used for the transmissions over the uplink. The light energy harvesting model is considered after introducing the line of sight propagation model for VLC. Then, the outage performance has been studied for the VLC downlink and non-orthogonal multiple access schemes over the RF uplink, respectively, by using stochastic geometry theory, while considering the randomness of the number of the terminals, and all terminals are spatially and randomly distributed in the 3-D room and all RF uplinks follow Rician fading. Finally, the approximated analytical expressions for the outage probability are derived and verified through Monte Carlo simulations

Optical Non-Orthogonal Multiple Access for Visible Light Communication

The proliferation of mobile Internet and connected devices, offering a variety of services at different levels of performance, represents a major challenge for the fifth generation wireless networks and beyond. This requires a paradigm shift towards the development of key enabling techniques for the next generation wireless networks. In this respect, visible light communication (VLC) has recently emerged as a new communication paradigm that is capable of providing ubiquitous connectivity by complementing radio frequency communications. One of the main challenges of VLC systems, however, is the low modulation bandwidth of the light-emitting-diodes, which is in the megahertz range. This article presents a promising technology, referred to as "optical- non-orthogonal multiple access (O-NOMA)", which is envisioned to address the key challenges in the next generation of wireless networks. We provide a detailed overview and analysis of the state-of-the-art integration of O-NOMA in VLC networks. Furthermore, we provide insights on the potential opportunities and challenges as well as some open research problems that are envisioned to pave the way for the future design and implementation of O-NOMA in VLC systems