Vývoj standardů mobilních sítí

Import 21/10/2013This bachelor thesis deals primarily with a development of LTE technologies and its possibilities of deployment in the Czech Republic and abroad. The thesis is initially focused on the development of mobile network standards since the advent of 3rd generation networks in Release 99 up to the newest Release 12 where the main telecommunication technologies are continuously described along with their advantages. As the LTE represents next evolution step in a field of mobile data transmission, the comparison of LTE and HSPA+ physical layers is also included. Among other it describes information blocks from transport channel over the transmission path and regaining of user data. The development of LTE networks in the world deals with an actual progress of the deployment of this technology. In detail, there are described countries where the LTE is in a commercial service among with a comparison of used frequency bands. Addressing with issue of development and deployment of LTE in the Czech Republic is a content of the last part. With regard to the current network state of each provider, it is also focused on legislation, backbone networks and frequency planning which is closely related to the forthcoming auction of the Digital Dividend.Tato bakalářská práce pojednává především o vývoji LTE technologíí a jejich možnostech nasazení v České Republice a ve světě. Práce se nejprve zaměřuje na vývoj mobilních standardů od nástupu sítí třetí generace, Release 99, až po doposud nejnovější Release 12, kde jsou postupně probrány vrcholové telekomunikační technologie a jejich přednosti. V práci jsou dále popsány rozdíly fyzických vrstev mezi technologiemi HSPA+ a LTE, jelikož se jedná o další evoluční krok v oblasti datových přenosů. Popis obsahuje blokové srovnání od samotné inicializace transportního kanálu, po přenosovou cestu a opětovného získání užitečné informace. Vývoj LTE sítí ve světě pojednává o aktuálním stavu vývoje a rozšíření této technologie. Podrobně jsou zde popsány země, kde se LTE používá spolu se srovnáním použitých frekvenčních pásem. Poslední část řeší otázku vývoje a nasazení LTE v České Republice. S ohledem na aktuální stav sítí jednotlivých operátoru je sekce zaměřena také na legislativu, páteřní sítě a frekvenční plánování, s čímž souvisí také očekáváná aukce z digitální dividendy.440 - Katedra telekomunikační technikyvelmi dobř

Resource Allocation in LTE Advanced for QoS and Energy Efficiency

Long Term Evolution (LTE) and LTE-Advanced (LTE-A) are establishing themselves as the new standard of 4G cellular networks in Europe and in several other parts of the world. Their success will largely depend on their ability to support Quality of Service for different types of users, at reasonable costs. The quality of service will depend on how effectively the cell bandwidth is shared among the users. The cost will depend – among many other factors – on how effectively we exploit the cell capacity. Being able to exploit bandwidth efficiently postpones the time when network upgrades are required. On the other hand, operation costs also depend on the energy efficiency of the cellular network, which should avoid wasting power when few users are connected. As for bandwidth efficiency, the recent LTE/LTE-A standards introduced MIMO (Multiple Input Multiple Output) transmission modes, which allow both reliability and efficiency to be increased. MIMO can increase the throughput significantly. In a MIMO system, the selection of the MIMO transmission modes (whether Transmission Diversity, Spatial Multiplexing, or Multi-User MIMO) plays a key feature in determining the achievable rate and the error probability experienced by the users. MIMO-unaware scheduling policies, which neglect the transmission mode selection problem, do not perform well under MIMO. In the current literature, few MIMO-aware LTE-A scheduling policies have been designed. However, despite being proposed for LTE-A, these solutions do not take into account some constraints inherent to LTE-A, hence leading to unfeasible allocations. In this work, we propose a new framework for Transmission Mode Selection and Frequency. Domain Packet Scheduling, which is compliant with the constraints of the LTE-A standard. The resource allocation framework accommodates real-time requirements and fairness on demand, while the bulk of the resources are allocated in an opportunistic fashion, i.e. so as to maximize the cell throughput. Our results show that our proposal provides real-time connections with the desired level of QoS, without utterly sacrificing the cell throughput. As far as energy efficiency is concerned, we studied the problem of minimizing the RF power used by the eNodeB, while maintaining the same level of service for the users. We devised a provisioning framework that exploits the Multicast/Broadcast over a Single Frequency Network (MBSFN) mechanism to deactivate the eNodeB on some Transmission Time Intervals (TTI), and computes the minimum-power activation required for guaranteeing a given level of service. Our results show that the provisioning framework is stable, and that it allows significant savings with respect to an always-on policy, with marginal impact on the latency experienced by the users

Resource management in future mobile networks: from millimetre-wave backhauls to airborne access networks

The next generation of mobile networks will connect vast numbers of devices and support services with diverse requirements. Enabling technologies such as millimetre-wave (mm-wave) backhauling and network slicing allow for increased wireless capacities and logical partitioning of physical deployments, yet introduce a number of challenges. These include among others the precise and rapid allocation of network resources among applications, elucidating the interactions between new mobile networking technology and widely used protocols, and the agile control of mobile infrastructure, to provide users with reliable wireless connectivity in extreme scenarios. This thesis presents several original contributions that address these challenges. In particular, I will first describe the design and evaluation of an airtime allocation and scheduling mechanism devised specifically for mm-wave backhauls, explicitly addressing inter-flow fairness and capturing the unique characteristics of mm-wave communications. Simulation results will demonstrate 5x throughput gains and a 5-fold improvement in fairness over recent mm-wave scheduling solutions. Second, I will introduce a utility optimisation framework targeting virtually sliced mm-wave backhauls that are shared by a number of applications with distinct requirements. Based on this framework, I will present a deep learning solution that can be trained within minutes, following which it computes rate allocations that match those obtained with state-of-the-art global optimisation algorithms. The proposed solution outperforms a baseline greedy approach by up to 62%, in terms of network utility, while running orders of magnitude faster. Third, the thesis investigates the behaviour of the Transport Control Protocol (TCP) in Long-Term Evolution (LTE) networks and discusses the implications of employing Radio Link Control (RLC) acknowledgements under different link qualities, on the performance of transport protocols. Fourth, I will introduce a reinforcement learning approach to optimising the performance of airborne cellular networks serving users in emergency settings, demonstrating rapid convergence (approx. 2.5 hours on a desktop machine) and a 5dB improvement of the median Signal-to-Noise-plus-Interference-Ratio (SINR) perceived by users, over a heuristic based benchmark solution. Finally, the thesis discusses promising future research directions that follow from the results obtained throughout this PhD project