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81	Self-optimization of Radio Resources on IEEE 802.11 Networks García Villegas, Eduardo 18 February 2010 (has links) Les xarxes d'àrea local sense fils (WLANs), principalment les basades en les diverses versions de les normes IEEE 802.11, i més concretament, aquelles operant en mode infraestructura (ús de punts d'accés o APs), són avui dia les tecnologies més populars per a l'accés ràdio de banda ampla a xarxes IP, ja sigui per a estendre petites xarxes LAN domèstiques (SOHO), o per a proporcionar accés d'Internet en espais públics. A més, amb l'arribada de productes amb el certificat Wi-Fi, els diferents fabricants de dispositius WLAN proporcionen un alt nivell d'interoperabilitat.No obstant això, la creixent densitat de punts d'accés WLAN ha començat a revelar els efectes negatius i les deficiències de les normes IEEE 802.11 inicials. Un dels factors clau del seu èxit, l'ús de la bandes de freqüència lliures (bandes ISM), és al mateix temps un dels seus grans inconvenients. Aquestes freqüències són de lliure accés al públic en general, i es defineixen dins d'una petita porció de l'espectre. En conseqüència, són generalment compartides entre diversos usuaris, dispositius de tecnologies diferents, etc.. A més, el control d'accés al medi definit per l'IEEE 802.11 (CSMA, o "escoltar abans de parlar") requereix una atenció especial a tots els problemes sorgits al voltant de les interferències.En aquest escenari, les xarxes WLAN IEEE no estan en condicions d'arribar a explotar tot el seu potencial. Malgrat aquest fet, unes polítiques intel·ligents sobre la gestió dels recursos ràdio (RRM) poden ajudar a reduir al mínim els efectes perjudicials de les interferències i d'una distribució desigual de la càrrega oferta. En aquesta tesi, es demostra que els mecanismes de RRM eficients són capaços de millorar notablement el rendiment d'una WLAN basada en l'IEEE 802.11.Aquesta tesi estudia la forma d'entendre els problemes de rendiment que són endèmics en les WLANs IEEE 802.11, així com les formes de minimitzar aquests efectes negatius per mitjà de la gestió de recursos ràdio. De fet, aquests problemes no són nous i han estat àmpliament estudiats des de l'aparició de xarxes de comunicacions mòbils, però les característiques particulars de les xarxes WLAN 802,11 requereixen nous enfocaments.Els mecanismes RRM en l'àmbit de les xarxes WLAN IEEE 802.11 són bàsicament destinats a reduir el grau de contenció i la interferència. Aquesta reducció es tradueix en una millor qualitat d'experiència (QoE), d'acord amb la percepció dels usuaris. Amb aquesta finalitat, RRM ha de proporcionar mecanismes eficients d'assignació de canals, algoritmes de selecció de modulació, control de potència i repartiment de càrrega. Atesa la naturalesa dinàmica de la propagació ràdio, i a causa de la mobilitat dels usuaris, els paràmetres que defineixen l'entorn sense fils varien amb el temps. Llavors, per tal de mantenir el rendiment en nivells acceptables, s'han de trobar mecanismes RRM que permetin una reconfiguració automàtica i dinàmica de la xarxa en resposta als canvis en el medi. En resum, podem construir el nostre escenari d'interès a partir de dispositius Wi-Fi intel·ligents capaços de cooperar, ja sigui de forma centralitzada o distribuïda, per tal de fer un millor ús dels minsos recursos ràdio.La nostra contribució als mecanismes RRM en xarxes WLAN s'inicia amb l'estudi i la caracterització de la interferència en l'àmbit particular de les xarxes IEEE 802.11. A continuació, desenvolupem un model de capacitat per a grans xarxes WLAN multi cel·la que té en compte tant l'efecte de la càrrega de la xarxa, com el de les interferències entre cel·les. El model també inclou l'efecte de l'adaptació automàtica de modulació que porten a terme molts dispositius. Aquestes estimacions de la capacitat són útils per a avaluar els beneficis d'un mecanisme RRM. Per exemple, aquestes estimacions són la base sobre la qual desenvolupem una innovadora solució per a la gestió de freqüències. Aquest mecanisme d'assignació de freqüències fa ús de tot l'espectre disponible (tant si es tracta de canals ISM solapats o no), ja que té en compte els efectes dels dos tipus d'interferència que trobem en xarxes IEEE 802.11: co-canal i per canal adjacent. Per tal de fer front a una distribució desigual de la càrrega, fet que es dóna típicament en els anomenats hotspots, es proposen dos mecanismes de repartiment de càrrega (un cop definit el concepte de càrrega): un enfocament distribuït gestionat per les estacions client, i un mecanisme de "cell breathing".Tots aquests mecanismes han de ser integrats en una arquitectura de gestió aglutinadora. En aquest sentit, s'han desenvolupat dues arquitectures de RRM: una arquitectura centralitzada, com a part del projecte UAMN, i un sistema distribuït. / WLANs, primarily the various versions of IEEE 802.11 standards, and more precisely, those operating in infrastructure mode, are nowadays the most popular technologies for providing broadband radio access to IP networks, whether to extend Small Office/Home Office (SOHO) network LANs or to provide Internet access in public places. Moreover, with the advent of Wi-Fi certified products, different competitive brands of WLAN devices are interoperable at a basic level of service.However, the increasing density of WLAN access points has started to reveal the negative effects and shortcomings of the original IEEE 802.11 standards. One of its key success factors, the use of unlicensed Industrial Scientific Medical (ISM) frequency bands, is at the same time one of its major drawbacks. These frequencies are freely available to the general public. On the other hand, such frequencies are defined within a small portion of the spectrum and are usually shared among several users. Besides, the medium access defined by the IEEE 802.11 (CSMA, or "listen before talk") requires a special attention to all interference issues.In this scenario, IEEE WLANs are unable to exploit all their potential. However, intelligent radio resource management (RRM) policies could be applied to minimize the harmful effects of interference and an uneven load distribution. Throughout this dissertation, it is shown that efficient RRM mechanisms are able to improve notably the performance of a legacy IEEE WLAN.This thesis explores ways of understanding the performance issues that are endemic to IEEE 802.11 WLANs, as well as ways of minimizing these negative effects by means of radio resource management. In fact, these problems are not new and have been studied extensively since the advent of mobile communications networks, but the particular characteristics of the 802.11 WLANs require new approaches.RRM mechanisms in the field of IEEE 802.11 WLANs are basically intended to reduce contention and interference. This reduction is translated into an improved Quality of Experience (QoE), as perceived by the users. To this end, RRM should provide efficient channel allocation mechanisms, modulation selection algorithms, power control and load balancing. Given the dynamic nature of radio propagation, and due to user mobility, the parameters that define the wireless environment vary in time. Therefore, in order to maintain the required performance, we should find mechanisms that allow a dynamic and automatic reconfiguration of the network in response to the changes in the environment. To sum up, we build our scenario of interest with intelligent Wi-Fi devices capable of cooperating either in a centralized or a distributed manner, in order to make a better use of the shared and scarce radio resources.Our contribution to RRM on WLANs starts with the study and characterization of interference in the particular field of IEEE 802.11 networks. Following, we develop a capacity model for large WLAN deployments that takes both the effect of carried traffic and inter-cell interference into account. The model also includes the effect of rate adaptation. These capacity estimations are useful to evaluate the benefits of a RRM mechanism, for example, it was used as the metric observed by a frequency management approach. This frequency assignment mechanism makes use of all the available spectrum (overlapping and non-overlapping ISM channels), since it takes the effects of both co-channel and adjacent-channel interference into account. In order to cope with the uneven load distribution usually found on hot-spots, two load balancing mechanisms are proposed after defining the concept of load: a client-driven approach, and a cell-breathing mechanism. All these mechanisms need to be integrated into a single architecture. In this regard, two radio resource management architectures are developed: a centralized architecture, as part of the UAMN project, and a distributed scheme. radiocomunicació optimization radio resources Wi-fi 802.11 WLAN telemàtica 621.3
82	Full-Duplex Infrastructure Nodes: Achieving Long Range with Half-duplex Mobiles Everett, Evan 06 September 2012 (has links) One of the primary sources of inefficiency in today's wireless networks is the half-duplex constraint - the assumption that nodes cannot transmit and receive simultaneously in the same band. The reason for this constraint and the hurdle to full-duplex operation is self-interference: a node's transmit signal appears at its own receiver with very high power, desensitizing the receiver electronics and precluding the reception of a packet from a distant node. Recent research has demonstrated that full-duplex can indeed be feasible by employing a combination of analog and digital self-interference cancellation mechanisms. However, two glaring limitations remain. The first is that the full-duplex state-of-the-art requires at least two antennas and extra RF resources that space-constrained mobile devices may not be able to accommodate. The second limitation is range: current full-duplex demonstrations have been for ranges less than 10~m. At longer distances nodes must transmit with higher power to overcome path loss, and the power differential between the self-interference and the signal-of-interest becomes more that the current cancellation mechanisms can handle. We therefore present engineering solutions for answering the following driving questions: (a) can we leverage full-duplex in a network consisting mostly of half-duplex mobiles? and (b) can we extend the range of full-duplex by achieving self-interference suppression sufficient for full-duplex to outperform half-duplex at ranges exceeding 100 m? In answer to the first question, we propose moving the burden of full-duplexing solely to access points (APs), enabling the AP to boost network throughput by receiving an uplink signal from one half-duplex mobile, while simultaneously transmitting a downlink signal to another half-duplex mobile in the same band. In answer to the second question we propose an AP antenna architecture that uses a careful combination of three mechanisms for passive suppression of self-interference: directional isolation, absorptive shielding, and cross-polarization. Results from a 20 MHz OFDM prototype demonstrate that the proposed AP architecture can achieve 90+ dB total self-interference suppression, enabling >50% uplink rate gains over half-duplex for ranges up to 150 m. Full-duplex Wireless communication antennas polarization WiFi 802.11
83	Multi-interface Multi-channel wireless mesh networks Munawar, Mohammad Ahmad January 2004 (has links) In this thesis we propose a multi-channel wireless network based on nodes that use multiple 802. 11 radio interfaces. The proposed system is singular, as it does not require new hardware or a new MAC, but instead leverages commodity 802. 11-based products. With this system, we target scenarios where the nodes are stationary and where their location can often be controlled. We evaluate the performance in this setup using an ad-hoc network approach whereby nodes generate as well as forward data. We also present and appraise a purely-wireless multi-channel infrastructure, which operates like the WLAN infrastructure-based networks in existence today, but without any fixed-line support. In such an infrastructure nodes dedicated for routing purposes provide wireless connectivity to users. We show that a multi-interface system provide significantly higher capacity in many scenarios. Our work puts forward various challenges, points to various anomalies in the operation of the 802. 11 MAC protocol, and shows the need to tackle unfairness issues. Our experiments demonstrate that the mere use of more dual-interface nodes does not necessarily create higher capacity. We also show that traffic differentiation significantly increases aggregate throughput in realistic scenarios. Finally, we provide an example of how simple channel-allocation algorithms in controlled random topologies can allow us to take advantage of a multi-interface system. Electrical & Computer Engineering 802.11 wireless mesh multi-channel
84	The Efficacy of Source Rate Control in Achieving Fairness in Wireless Mesh Networks Li, Lily Lei January 2007 (has links) The use of 802.11-based wireless mesh networks (WMNs) as an alternative network backbone technology is growing rapidly. The primary advantages of this approach are ease of deployment and lower cost. However, such networks typically exhibit poor fairness properties, often starving nodes if they are too many hops distant from the gateway. Researchers have shown a growing interest in this problem in recent years. Many solutions proposed amount to some level of source rate control, either by policing directly at the source, or via TCP congestion control reacting to a gateway-enforced rate limit. However, there has been limited study on the effectiveness of source rate control. In this thesis we first demonstrate that source rate control can only partially solve the fairness issue in 802.11-based WMNs, with some routers experiencing an undesirable degree of unfairness, which we call structural unfairness. We then identify the four necessary factors that cause structural unfairness. If we can eliminate or reduce any one of these conditions, we can eliminate or ameliorate the unfairness problem. We first investigate two techniques to improve 802.11 MAC scheduling: fixing the contention window and packet spacing at every router node, both means achievable with commodity 802.11 hardware. We show that the combination of these mechanisms provides a significant gain in fairness. We also perform case studies using another three techniques, channel re-assignment, routing changes, and careful router placement, to remove or reduce other necessary conditions. We demonstrate that these techniques, whenever applicable, can eliminate the unfairness problem entirely at times, or at least improve the situation. 802.11 fairness MAC Wireless Mesh Networks Electrical and Computer Engineering
85	Vertical Handoff between 802.11 and 802.16 Wireless Access Networks Zhang, Yongqiang January 2008 (has links) Heterogeneous wireless networks will be dominant in the next-generation wireless networks with the integration of various wireless access networks. Wireless mesh networks will become to a key technology as an economically viable solution for wide deployment of high speed, scalable and ubiquitous wireless Internet services. In this thesis, we consider an interworking architecture of wireless mesh backbone and propose an effective vertical handoff scheme between 802.11 and 802.16 wireless access networks. The proposed vertical handoff scheme aims at reducing handoff signaling overhead on the wireless backbone and providing a low handoff delay to mobile nodes. The handoff signaling procedure in different scenarios is discussed. Together with call admission control, the vertical handoff scheme directs a new call request in the 802.11 network to the 802.16 network, if the admission of the new call in the 802.11 network can degrade quality-of-service (QoS) of the existing real-time traffic flows. Simulation results demonstrate the performance of the handoff scheme with respect to signaling cost, handoff delay, and QoS support. Vertical Handoff 802.11 802.16 Wireless Mesh Network Electrical and Computer Engineering
86	Interference Management in Dense 802.11 Networks Ahmed, Nabeel 16 September 2009 (has links) Wireless networks are growing at a phenomenal rate. This growth is causing an overcrowding of the unlicensed RF spectrum, leading to increased interference between co-located devices. Existing decentralized medium access control (MAC) protocols (e.g. IEEE 802.11a/b/g standards) are poorly designed to handle interference in such dense wireless environments. This is resulting in networks with poor and unpredictable performance, especially for delay-sensitive applications such as voice and video. This dissertation presents a practical conflict-graph (CG) based approach to designing self-organizing enterprise wireless networks (or WLANs) where interference is centrally managed by the network infrastructure. The key idea is to use potential interference information (available in the CG) as an input to algorithms that optimize the parameters of the WLAN.We demonstrate this idea in three ways. First, we design a self-organizing enterprise WLAN and show how the system enhances performance over non-CG based schemes, in a high fidelity network simulator. Second, we build a practical system for conflict graph measurement that can precisely measure interference (for a given network configuration) in dense wireless environments. Finally, we demonstrate the practical benefits of the conflict graph system by using it in an optimization framework that manages associations and traffic for mobile VoIP clients in the enterprise. There are a number of contributions of this dissertation. First, we show the practical application of conflict graphs for infrastructure-based interference management in dense wireless networks. A prototype design exhibits throughput gains of up to 50% over traditional approaches. Second, we develop novel schemes for designing a conflict graph measurement system for enterprise WLANs that can detect interference at microsecond-level timescales and with little network overhead. This allows us to compute the conflict graph up to 400 times faster as compared to the current best practice proposed in the literature. The system does not require any modifications to clients or any specialized hardware for its operation. Although the system is designed for enterprise WLANs, the proposed techniques and corresponding results are applicable to other wireless systems as well (e.g. wireless mesh networks). Third, our work opens up the space for designing novel fine-grained interference-aware protocols/algorithms that exploit the ability to compute the conflict graph at small timescales. We demonstrate an instance of such a system with the design and implementation of an architecture that dynamically manages client associations and traffic in an enterprise WLAN. We show how mobile clients sustain uninterrupted and consistent VoIP call quality in the presence of background interference for the duration of their VoIP sessions. interference 802.11 modeling measurement testbed VoIP Computer Science
87	Implementation of the IEEE 802.11a MAC layer in C language / Implementering av IEEE 802.11a MAC-lagret i programspråket C Guillen, Carlos Alonso January 2004 (has links) Wireless communication is being developed in the last years day by day, there are several standards that talks about it. We are going to go through the IEEE standard 802.11 which talks about wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications. Looking this more carefully we will study MAC specifications and its environment. The work that ISY department at Institute of Technology of Linkoping University has proposed is to design a MAC sublayer implementation for WLANs using C language programming and testing it with the test environment called “test bench”. This test bench will simulate LLC sublayer and PHY layer, in this way, our MAC implementation will has to interact with it. Therefore we will simulate a wireless network where we are going to have a short number of stations and we are going to look at carefully the MAC sublayer response in an ad hoc network. Electronics IEEE 802.11 WLAN MAC C language Elektronik Electronics Elektronik
88	Multi-interface Multi-channel wireless mesh networks Munawar, Mohammad Ahmad January 2004 (has links) In this thesis we propose a multi-channel wireless network based on nodes that use multiple 802. 11 radio interfaces. The proposed system is singular, as it does not require new hardware or a new MAC, but instead leverages commodity 802. 11-based products. With this system, we target scenarios where the nodes are stationary and where their location can often be controlled. We evaluate the performance in this setup using an ad-hoc network approach whereby nodes generate as well as forward data. We also present and appraise a purely-wireless multi-channel infrastructure, which operates like the WLAN infrastructure-based networks in existence today, but without any fixed-line support. In such an infrastructure nodes dedicated for routing purposes provide wireless connectivity to users. We show that a multi-interface system provide significantly higher capacity in many scenarios. Our work puts forward various challenges, points to various anomalies in the operation of the 802. 11 MAC protocol, and shows the need to tackle unfairness issues. Our experiments demonstrate that the mere use of more dual-interface nodes does not necessarily create higher capacity. We also show that traffic differentiation significantly increases aggregate throughput in realistic scenarios. Finally, we provide an example of how simple channel-allocation algorithms in controlled random topologies can allow us to take advantage of a multi-interface system. Electrical & Computer Engineering 802.11 wireless mesh multi-channel
89	Vertical Handoff between 802.11 and 802.16 Wireless Access Networks Zhang, Yongqiang January 2008 (has links) Heterogeneous wireless networks will be dominant in the next-generation wireless networks with the integration of various wireless access networks. Wireless mesh networks will become to a key technology as an economically viable solution for wide deployment of high speed, scalable and ubiquitous wireless Internet services. In this thesis, we consider an interworking architecture of wireless mesh backbone and propose an effective vertical handoff scheme between 802.11 and 802.16 wireless access networks. The proposed vertical handoff scheme aims at reducing handoff signaling overhead on the wireless backbone and providing a low handoff delay to mobile nodes. The handoff signaling procedure in different scenarios is discussed. Together with call admission control, the vertical handoff scheme directs a new call request in the 802.11 network to the 802.16 network, if the admission of the new call in the 802.11 network can degrade quality-of-service (QoS) of the existing real-time traffic flows. Simulation results demonstrate the performance of the handoff scheme with respect to signaling cost, handoff delay, and QoS support. Vertical Handoff 802.11 802.16 Wireless Mesh Network Electrical and Computer Engineering
90	Interference Management in Dense 802.11 Networks Ahmed, Nabeel 16 September 2009 (has links) Wireless networks are growing at a phenomenal rate. This growth is causing an overcrowding of the unlicensed RF spectrum, leading to increased interference between co-located devices. Existing decentralized medium access control (MAC) protocols (e.g. IEEE 802.11a/b/g standards) are poorly designed to handle interference in such dense wireless environments. This is resulting in networks with poor and unpredictable performance, especially for delay-sensitive applications such as voice and video. This dissertation presents a practical conflict-graph (CG) based approach to designing self-organizing enterprise wireless networks (or WLANs) where interference is centrally managed by the network infrastructure. The key idea is to use potential interference information (available in the CG) as an input to algorithms that optimize the parameters of the WLAN.We demonstrate this idea in three ways. First, we design a self-organizing enterprise WLAN and show how the system enhances performance over non-CG based schemes, in a high fidelity network simulator. Second, we build a practical system for conflict graph measurement that can precisely measure interference (for a given network configuration) in dense wireless environments. Finally, we demonstrate the practical benefits of the conflict graph system by using it in an optimization framework that manages associations and traffic for mobile VoIP clients in the enterprise. There are a number of contributions of this dissertation. First, we show the practical application of conflict graphs for infrastructure-based interference management in dense wireless networks. A prototype design exhibits throughput gains of up to 50% over traditional approaches. Second, we develop novel schemes for designing a conflict graph measurement system for enterprise WLANs that can detect interference at microsecond-level timescales and with little network overhead. This allows us to compute the conflict graph up to 400 times faster as compared to the current best practice proposed in the literature. The system does not require any modifications to clients or any specialized hardware for its operation. Although the system is designed for enterprise WLANs, the proposed techniques and corresponding results are applicable to other wireless systems as well (e.g. wireless mesh networks). Third, our work opens up the space for designing novel fine-grained interference-aware protocols/algorithms that exploit the ability to compute the conflict graph at small timescales. We demonstrate an instance of such a system with the design and implementation of an architecture that dynamically manages client associations and traffic in an enterprise WLAN. We show how mobile clients sustain uninterrupted and consistent VoIP call quality in the presence of background interference for the duration of their VoIP sessions. interference 802.11 modeling measurement testbed VoIP Computer Science

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