Global ETD Search

11	Paving the Way for Next Generation Wireless Data Center Networks AlGhadhban, Amer M. 05 1900 (has links) Data Centers (DCs) have become an intrinsic element of emerging technologies such as big data, artificial intelligence, cloud services; all of which entails interconnected and sophisticated computing and storage resources. Recent studies of conventional data center networks (DCNs) revealed two key challenges: a biased distribution of inter-rack traffic and unidentified flow classes: delay sensitive mice flows (MFs) and throughput-hungry elephant flows (EFs). Unfortunately, existing DCN topologies support only uniform distribution of capacities, provide limited bandwidth flexibilities and lacks of efficient flow classification mechanism. Fortunately, wireless DCs can leverage wireless communication emerging technologies, such as multi-terabit free-space optic (FSO), to provide flexible and reconfigurable DCN topologies. It is worth noting that indoor FSO links are less vulnerable to outdoor FSO channel impairments. Consequently, indoor FSO links are more robust and can offer high bandwidths with long stability, which can further be enhanced with wavelength division multiplexing (WDM) methods. In this thesis, we alleviate the bandwidth inefficiency by FSO links that have the desired agility by allocating the transmission powers to adapt link capacity for dynamically changing traffic conditions, and to reduce the maintenance costs and overhead. While routing the two classes along the same path causes unpleasant consequences, the DC researchers proposed traffic management solutions to treat them separately. However, the solutions either suffer from packet reordering and high queuing delay, or lack of accurate visibility and estimation on end-to-end path status. Alternatively, we leverage WDM to design elastic network topologies (i.e., part of the wavelengths are assigned to route MFs and the remaining for EFs). Since bandwidth demands can be lower than available capacity of WDM channels, we use traffic grooming to aggregate multiple flows into a larger flow and to enhance the link utilization. On the other hand, to reap the benefits of the proposed WDM isolated topology, an accurate and fast EF detection mechanism is necessary. Accordingly, we propose a scheme that uses TCP communication behavior and collect indicative packets for its flow classification algorithm, it demonstrates perfect flow classification accuracy, and is in order of magnitudes faster than existing solutions with low communication and computation overhead. Wireless Data Center Free Space Optics (FSO) Traffic Grooming (TG) Flow Classification Software Defined Network (SDN) Delay Analysis
12	Data Collection and Capacity Analysis in Large-scale Wireless Sensor Networks Ji, Shouling 01 August 2013 (has links) In this dissertation, we study data collection and its achievable network capacity in Wireless Sensor Networks (WSNs). Firstly, we investigate the data collection issue in dual-radio multi-channel WSNs under the protocol interference model. We propose a multi-path scheduling algorithm for snapshot data collection, which has a tighter capacity bound than the existing best result, and a novel continuous data collection algorithm with comprehensive capacity analysis. Secondly, considering most existing works for the capacity issue are based on the ideal deterministic network model, we study the data collection problem for practical probabilistic WSNs. We design a cell-based path scheduling algorithm and a zone-based pipeline scheduling algorithm for snapshot and continuous data collection in probabilistic WSNs, respectively. By analysis, we show that the proposed algorithms have competitive capacity performance compared with existing works. Thirdly, most of the existing works studying the data collection capacity issue are for centralized synchronous WSNs. However, wireless networks are more likely to be distributed asynchronous systems. Therefore, we investigate the achievable data collection capacity of realistic distributed asynchronous WSNs and propose a data collection algorithm with fairness consideration. Theoretical analysis of the proposed algorithm shows that its achievable network capacity is order-optimal as centralized and synchronized algorithms do and independent of network size. Finally, for completeness, we study the data aggregation issue for realistic probabilistic WSNs. We propose order-optimal scheduling algorithms for snapshot and continuous data aggregation under the physical interference model. Wireless sensor networks Data collection Data aggregation Delay analysis Capacity analysis Protocol interference model Physical interference model Generalized physical interference model Deterministic network model Probabilistic network model
13	Návrh a optimalizace spínaného komparátoru v 250 nm CMOS technologii / Design and parameters optimization of latched comparator in 250 nm CMOS process Matěj, Jan January 2017 (has links) This diploma thesis deals with design methods and optimization techniques of dynamic latched comparators. It compares latched and continuous comparators and describes their principle. Then it analyses three popular latched comparator structures with respect to offset, speed and kickback noise. It shows practical comparator design focused on offset precision.
14	Improving the Schedulability of Real Time Systems under Fixed Preemption Point Scheduling Markovic, Filip January 2018 (has links) During the past decades of research in Real-Time systems, non-preemptive scheduling and fully preemptive scheduling have been extensively investigated, as well as compared with each other. However, it has been shown that none of the two scheduling paradigms dominates over the other in terms of schedulability. In this context, Limited Preemptive Scheduling (LPS) has emerged as an attractive alternative with respect to, e.g., increasing the overall system schedu- lability, efficiently reducing the blocking by lower priority tasks (compared to non-preemptive scheduling) as well as efficiently controlling the number of preemptions, thus controlling the overall preemption-related delay (compared to fully-preemptive scheduling). Several approaches within LPS enable the above mentioned advantages. In our work, we consider the Fixed Preemption Point Scheduling (LP-FPP) as it has been proved to effectively reduce the preemption-related delay compared to other LPS approaches. In particular, LP-FPP facilitates more precise estimation of the preemption-related delays, since the preemption points of a task in LP-FPP are explicitly selected during the design phase, unlike the other LPS approaches where the preemption points are determined at runtime. The main goal of the proposed work is to improve the schedulability of real-time systems under the LP-FPP approach. We investigate its use in different domains, such as: single core hard real-time systems, partitioned multi-core systems and real-time systems which can occasionally tolerate deadline misses. We enrich the state of the art for the single core hard real-time systems by proposing a novel cache-related preemption delay analysis, towards reducing the pessimism of the previously proposed methods. In the context of partitioned multi-core scheduling we propose a novel partitioning criterion for the Worst-Fit Decreasing based partitioning, and we also contribute with the comparison of existing partitioning strategies for LP-FPP scheduling. Finally, in the context of real-time systems which can occasionally tolerate deadline misses, we contribute with a probabilistic response time analysis for LP-FPP scheduling and a preemption point selection method for reducing the deadline-misses of the tasks. Real-Time Systems Limited Preemptive Scheduling Fixed Preemption Points Scheduling Probabilistic response time analysis Cache-Related Preemption Delay Analysis Computer Sciences Datavetenskap (datalogi)
15	Modélisation, évaluation et validation des systèmes temps réel distribués / Modeling, evaluation and validation of distributed real time systems. Benammar, Nassima 17 September 2018 (has links) Dans cette thèse, nous analysons les réseaux des systèmes temps-réel distribués et plus particulièrement ceux des domaines de l’avionique et de l’automobile. Nous nous sommes focalisés sur deux protocoles : « Avionic Full DupleX Switched Ethernet » (AFDX), « Audio Vidéo Bridging Ethernet » (AVB). Dans ces domaines critiques, le déterminisme du réseau doit être garanti. Il consiste, notamment, en la détermination d’une borne garantie du délai de bout en bout de traversée du réseau pour chaque trame ; et un dimensionnement des files d’attente des trames suffisamment grand pour garantir qu’aucune d’entre elle ne débordera et ainsi, éviter toute perte de trame.Il existe plusieurs méthodes pour l’évaluation des délais et nous avons, principalement, travaillé sur la méthode « Forward end-to-end delay Analysis » (FA). FA avait déjà été définie avec la politique d’ordonnancement « First-In-First-Out » dans le contexte de l’AFDX. Nous sommes repartis de cette approche, nous l’avons reformulé et généralisé à n’importe quel réseau Ethernet commuté. Nous l’avons aussi étendu aux priorités statiques et au protocole AVB et sa politique de service « Credit Based Shaper ». Pour chaque contribution, des démonstrations formelles ont été présentées et une expérimentation incluant une comparaison de FA avec les principales approches d’évaluation sur un exemple industriel. Finalement, nous avons développé et démontré formellement une approche pour le dimensionnement des files d’attente en termes de nombre de trames. Cette approche a été expérimentée également sur une configuration industrielle. / In this thesis, we analyze networks in the context of distributed real-time systems, especially in the fields of avionics, with “Avionics Full DupleX Switched Ethernet” (AFDX), and automobile, with “Audio Video Bridging Ethernet” (AVB). For such applications, network determinism needs to be guaranteed. It involves, in particular, assessing a guaranteed bound on the end-to-end traversal time across the network fr each frame; and dimensioning the buffers in order to avoid any loss of frame because of a buffer overflow.There are several methods for worst-case delay analysis, and we have mainly worked on the “Forward end-to-end Delay Analysis” (FA) method. FA had already been developed for “First-In-First-Out” scheduling policy in the AFDX context, so we generalized it to any Switched Ethernet network. We have also extended it to handle static priorities and the AVB protocol, shaping policy named “Credit Based Shaper” (CBS). Each contribution has been formaly proved and experiments have been led on industrial configurations. For our experimentations, we have compared our results with the results of competing approaches. Finally, we have developed and formally demonstrated an approach for buffer dimensioning in terms of number of frames. This approach has also been tested on an industrial configuration and has produced tight bounds. Réseau temps réel Système temps réel distribué Afdx Avb Validation Analyse de délai de bout en bout Dimensionnement de files d'attente Real time network Distributed real time system Afdx Avb Validation End-To-End delay analysis Buffer dimensionning 004.6 004.33
16	Medium Access Control, Packet Routing, and Internet Gateway Placement in Vehicular Ad Hoc Networks Omar, Hassan Aboubakr January 2014 (has links) Road accidents represent a serious social problem and are one of the leading causes of human death and disability on a global scale. To reduce the risk and severity of a road accident, a variety of new safety applications can be realized through wireless communications among vehicles driving nearby each other, or among vehicles and especially deployed road side units (RSUs), a technology known as a vehicular ad hoc network (VANET). Most of the VANET-enabled safety applications are based on broadcasting of safety messages by vehicles or RSUs, either periodically or in case of an unexpected event, such as a hard brake or dangerous road condition detection. Each broadcast safety message should be successfully delivered to the surrounding vehicles and RSUs without any excess delay, which is one of the main functions of a medium access control (MAC) protocol proposed for VANETs. This thesis presents VeMAC, a new multichannel time division multiple access (TDMA) protocol specifically designed to support the high priority safety applications in a VANET scenario. The ability of the VeMAC protocol to deliver periodic and event-driven safety messages in VANETs is demonstrated by a detailed delivery delay analysis, including queueing and service delays, for both types of safety messages. As well, computer simulations are conducted by using MATLAB, the network simulator ns-2, and the microscopic vehicle traffic simulator VISSIM, in order to evaluate the performance of the VeMAC protocol, in comparison with the IEEE 802.11p standard and the ADHOC MAC protocol (another TDMA protocol proposed for ad hoc networks). A real city scenario is simulated and different performance metrics are evaluated, including the network goodput, protocol overhead, channel utilization, protocol fairness, probability of a transmission collision, and safety message delivery delay. It is shown that the VeMAC protocol considerably outperforms the existing MAC schemes, which have significant limitations in supporting VANET safety applications. In addition to enhancing road safety, in-vehicle Internet access is one of the main applications of VANETs, which aims at providing the vehicle passengers with a low-cost access to the Internet via on-road gateways. This thesis presents a new strategy for deploying Internet gateways on the roads, in order to minimize the total cost of gateway deployment, while ensuring that a vehicle can connect to an Internet gateway (using multihop communications) with a probability greater than a specified threshold. This cost minimization problem is formulated by using binary integer programming, and applied for optimal gateway placement in a real city scenario. To the best of our knowledge, no previous strategy for gateway deployment has considered the probability of multihop connectivity among the vehicles and the deployed gateways. In order to allow a vehicle to discover the existence of an Internet gateway and to communicate with the gateway via multihops, a novel data packet routing scheme is proposed based on the VeMAC protocol. The performance of this cross-layer design is evaluated for a multichannel VANET in a highway scenario, mainly in terms of the end-to-end packet delivery delay. The packet queueing at each relay vehicle is considered in the end-to-end delay analysis, and numerical results are presented to study the effect of various parameters, such as the vehicle density and the packet arrival rate, on the performance metrics. The proposed VeMAC protocol is a promising candidate for MAC in VANETs, which can realize many advanced safety applications to enhance the public safety standards and improve the safety level of drivers/passengers and pedestrians on roads. On the other hand, the proposed gateway placement strategy and packet routing scheme represent a strong step toward providing reliable and ubiquitous in-vehicle Internet connectivity. Medium Access Control Packet Routing Internet Gateway Placement Vehicular Ad Hoc Networks Time Division Multiple Access Packet Delay Analysis Road Safety Applications In-Vehicle Internet Access IEEE 802.11p Reliable Broadcast
17	Výběr vhodné sběrnice pro Distribuovaný Fly-by-Wire systém / Selection of Airplane Data Bus for Distributed Fly-by-Wire System Funderák, Marcel January 2010 (has links) This thesis is dealing with selection of proper airplane data bus for distributed Fly-by-Wire system. The parameters of such data bus are defined here and description of such data buses are given as well. The proper data bus which fulfils the given parameters is selected. Next the safety and time-delay analysis are provided.
18	Fuzzy Time-Delay Model in Fault-Tree Analysis for Critical Path Method Alsaqqa, Obada 21 May 2015 (has links) No description available. Civil Engineering Engineering Mathematics Logic Management Operations Research Industrial Engineering Construction Management CPM Delay Likelihood Fault Tree Analysis FFTA FTA Fuzzy Fault Tree Fuzzy Fault Tree Analysis Fuzzy Logic Fuzzy Model PERT Project Delay Risk Management Scheduling Time Delay Analysis Time Overrun Uncertainty

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