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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

Finite-horizon Online Energy-efficient Transmissionscheduling Schemes Forcommunication Links

Bacinoglu, Tan Baran 01 January 2013 (has links) (PDF)
The proliferation of embedded systems, mobile devices, wireless sensor applications and in- creasing global demand for energy directed research attention toward self-sustainable and environmentally friendly systems. In the field of communications, this new trend pointed out the need for study of energy constrained communication and networking. Particularly, in the literature, energy efficient transmission schemes have been well studied for various cases. However, fundamental results have been obtained mostly for offline problems which are not applicable to practical implementations. In contrast, this thesis focuses on online counterparts of offline transmission scheduling problems and provides a theoretical background for energy efficient online transmission schemes. The proposed heuristics, Expected Threshold and Expected Water Level policies, promise an adequate solution which can adapt to short-time-scale dynamics while being computationally efficient.
22

A Simulation Study Of Scheduling Algorithms For Packet Switching Networks

Babur, Ozgur 01 December 2003 (has links) (PDF)
A scheduling algorithm has the primary role in implementing the quality of service guaranteed to each flow by managing buffer space and selecting which packet to send next with a fair share of network. In this thesis, some scheduling algorithms for packet switching networks are studied. For evaluating their delay, jitter and throughput performances, a discrete event simulator has been developed. It has been seen that fair scheduling provides, fair allocation of bandwidth, lower delay for sources using less than their full share of bandwidth and protection from ill-behaved resources.
23

Packet Order Matters! : Improving Application Performance by Deliberately Delaying Packets / Paketsekvensen betyder! : Förbättra applikationsprestanda genom att avsiktligt fördröja paket

Ghasemirahni, Hamid January 2021 (has links)
Data-centers increasingly deploy commodity servers with high-speed network interfaces to enable low-latency communication. However, achieving low latency at high data rates crucially depends on how the incoming traffic interacts with the system's caches. When packets that need to be processed in the same way are consecutive, i.e., exhibit high temporal and spatial locality, CPU caches deliver great benefits. This licentiate thesis systematically studies the impact of temporal and spatial traffic locality on the performance of commodity servers equipped with high-speed network interfaces. The results are that (i) the performance of a variety of widely deployed applications degrade substantially with even the slightest lack of traffic locality, and (ii) a traffic trace from our organization's link to/from its upstream provider reveals poor traffic locality as networking protocols, drivers, and the underlying switching/routing fabric spread packets out in time (reducing locality).  To address these issues, we built Reframer, a software solution that deliberately delays packets and reorders them to increase traffic locality. Despite introducing µs-scale delays of some packets, Reframer increases the throughput of a network service chain by up to 84% and reduces the flow completion time of a web server by 11% while improving its throughput by 20%. / Datacenter distribuerar alltmer rå varuservrar med höghastighets-nätverksgränssnitt för att möjliggöra kommunikation med låg latens. Att uppnå låg latens vid höga datahastigheter beror dock mycket på hur den inkommande trafiken interagerar med systemets cacheminnen. När paket som behöver bearbetas på samma sätt är konsekutiva, dvs. uppvisar hög tids- och rumslig lokalitet, ger cacher stora fördelar. I denna licentiatuppsats studerar vi systematiskt effekterna av tidsmässig och rumslig trafikplats på  prestanda för rå varuservrar utrustade med höghastighetsnätgränssnitt.Vå ra resultat visar att (i) prestandan för en mängd allmänt distribuerade applikationer försämras avsevärt med till och med den minsta bristen på trafikplats, och (ii) visar ett trafikspår från vår organisation dålig trafikplats som nätverksprotokoll, drivrutiner och den underliggande omkopplingen/dirigera tygspridningspaket i tid (minska lokaliteten). För att ta itu med dessa problem byggde vi Reframer, en mjukvarulösning som medvetet fördröjer paket och ordnar dem för att öka trafikplatsen. Trots införandet av µs-skalafördröjningar för vissa paket visar vi att Reframer ökar genomströmningen för en nätverkstjänstkedja med upp till 84% och minskar flödet för en webbserver med 11% samtidigt som dess genomströmning förbättras med 20%. / <p>QC 20210512</p> / ULTRA
24

Diffuser: Packet Spraying While Maintaining Order : Distributed Event Scheduler for Maintaining Packet Order while Packet Spraying in DPDK / Diffusor: Packet Spraying While Upprätthålla Ordning : Distribuerad händelseschemaläggare för att upprätthålla paketordning medan Paketsprutning i DPDK

Purushotham Srinivas, Vignesh January 2023 (has links)
The demand for high-speed networking applications has made Network Processors (NPs) and Central Computing Units (CPUs) increasingly parallel and complex, containing numerous on-chip processing cores. This parallelism can only be exploited fully by the underlying packet scheduler by efficiently utilizing all the available cores. Classically, packets have been directed towards the processing cores at flow granularity, making them susceptible to traffic locality. Ensuring a good load balance among the processors improves the application’s throughput and packet loss characteristics. Hence, packet-level schedulers dispatch flows to the processing core at a packet granularity to improve the load balance. However, packet-level scheduling combined with advanced parallelism introduces out-of-order departure of the processed packets. Simultaneously optimizing both the load balance and packet order is challenging. In this degree project, we micro-benchmark the DPDK’s (Dataplane Development Kit) event scheduler and identify many performance and scalability bottlenecks. We find the event scheduler consumes around 40% of the cycles on each participating core for event scheduling. Additionally, we find that DSW (Distributed Software Scheduler) cannot saturate all the workers with traffic because a single NIC (Network Interface Card) queue is polled for packets in our test setup. Then we propose Diffuser, an event scheduler for DPDK that combines the functional properties of both the flow and packet-level schedulers. The diffuser aims to achieve optimal load balance while minimizing out-of-order packet transmission. Diffuser uses stochastic flow assignments along with a load imbalance feedback mechanism to adaptively control the rate of flow migrations to optimize the scheduler’s load distribution. Diffuser reduces packet reordering by at least 65% with ten flows of 100 bytes at 25 MPPS (Million Packet Per Second) and at least 50% with one flow. While Diffuser improves the reordering performance, it slightly reduces throughput and increases latency due to flow migrations and reduced cache locality / Efterfrågan på höghastighets-nätverksapplikationer har gjort nätverkspro-cessorer (NP) och centrala beräkningsenheter (CPU:er) alltmer parallella, komplexa och innehållande många processorkärnor. Denna parallellitet kan endast utnyttjas fullt ut av den underliggande paketschemaläggaren genom att effektivt utnyttja alla tillgängliga kärnor. Vanligtvis har paketschemaläggaren skickat paket till olika kärnor baserat på flödesgranularitet, vilket medför trafik-lokalitet. En bra belastningsbalans mellan processorerna förbättrar applikationens genomströmning och minskar förlorade paket. Därför skickar schemaläggare på paketnivå istället flöden till kärnan med en paketgranularitet för att förbättra lastbalansen. Schemaläggning på paketnivå kombinerat med avancerad parallellism innebär dock att de behandlade paketen avgår i oordning. Att samtidigt optimera både lastbalans och paketordning är en utmaning. I detta examensprojekt utvärderar vi DPDKs (Dataplane Development Kit) händelseschemaläggare och hittar många flaskhalsar i prestanda och skalbarhet. Vi finner att händelseschemaläggaren konsume-rar cirka 40 % av cyklerna på varje kärna.Dessutom finner vi att DSW (Schemaläggare för distribuerad programvara) inte kan mätta alla arbetande kärnor med trafik eftersom en enda nätverkskorts-kö används i vår testmiljö. Vi introducerar också Diffuser, en händelse-schemaläggare för DPDK som kombinerar egenskaperna hos både flödes-och paketnivåschemaläggare. Diffuser ämnar att uppnå optimal lastbalans samtidigt som den minimerar paketöverföring i oordning. Den använder stokastiska flödestilldelningar tillsammans med en återkopplingsmekanism för lastobalans för att adaptivt kontrollera flödesmigreringar för att optimera lastfördelningen. Diffuser minskar omordning av paket med minst 65 % med tio flöden på 100 byte vid 25 MPPS (Miljoner paket per sekund) och minst 50 % med endast ett flöde. Även om Diffuser förbättrar omordningsprestandan, minskar den genomströmningen något och ökar latensen på grund av flödesmigreringar och minskad cache-lokalitet.
25

Packet Scheduling on the Wireless Channel

Mondal, Santanu January 2014 (has links) (PDF)
Scheduling has always been an indispensable part of resource allocation in wireless networks. Accurate information about channel-state is assumed as a modeling simplification. However, in a real-life network ,e.g., Long Term Evolution(LTE) or IEEE 802.16e WiMAX, the channel-state information feedback to the transmitter can have uncertainty. The primary reason being that although resource allocation is done at the finer granularity of a Physical Resource Block (PRB), channel-state information is still feedback at the coarser granularity of a sub band, which is a group of PRBs. This is done to reduce the feedback traffic from the users to the Base Station. However, this averaging causes information loss and hence, the resulting uncertainty at the scheduler. Moreover, uncertainty might be present in the channel-estimates because of the very process of estimation. In the first part of the thesis, we model the channel-estimate in accuracy and characterize the network stability region. Compared to earlier works, we allow the channel estimates to have dependence among themselves, which is a more realistic situation in a modern LTE or WiMax network. We then propose two simple Max Weight based scheduling schemes that achieve any rate in the interior of the stability region. We also derive an asymptotically tight upper bound on the mean queueing delay in our system under one of the throughput-optimal policies we propose. The above policies ensure stability of the network and we have also obtained bounds on the mean queueing delays. However, different applications may require certain quality of service which may not be satisfied by these policies. Thus, we also propose a throughput-optimal policy for the network under traffic with heterogeneous QoS constraints and present some numerical results studying its performance. In the second part of the thesis, we study the problem of energy-efficient scheduling under average delay constraint. For wireless access technologies, the largest power consumer is the Base Station(BS). Any reduction in the power consumption in a BS will reduce carbon footprint from the Information and Communication Technology sector. We concentrate on the problem of minimizing the total non-renewable power consumed in a Green BS, that is powered by renewable energy sources ,e.g., solar/wind energy and may also be connected to the power grid or diesel generators. Specifically, we consider the problem of minimizing the average grid power consumption of a Green BS downlink in scheduling multiple users with average delay constraints. We have a packetized model for the data packets (i.e., the packets cannot be fragmented) which is a more realistic model for packet-switched networks. The power function is a non-decreasing convex function of the queue-lengths and only one user is allowed to transmit in a slot. We prove the existence of a power optimal policy under delay constraints for multiple users. We analyse the problem and provide some structural results for the optimal policy.
26

Intelligent based Packet Scheduling Scheme using Internet Protocol/Multi-Protocol Label Switching (IP/MPLS) Technology for 5G. Design and Investigation of Bandwidth Management Technique for Service-Aware Traffic Engineering using Internet Protocol/Multi-Protocol Label Switching (IP/MPLS) for 5G

Mustapha, Oba Z. January 2019 (has links)
Multi-Protocol Label Switching (MPLS) makes use of traffic engineering (TE) techniques and a variety of protocols to establish pre-determined highly efficient routes in Wide Area Network (WAN). Unlike IP networks in which routing decision has to be made through header analysis on a hop-by-hop basis, MPLS makes use of a short bit sequence that indicates the forwarding equivalence class (FEC) of a packet and utilises a predefined routing table to handle packets of a specific FEC type. Thus header analysis of packets is not required, resulting in lower latency. In addition, packets of similar characteristics can be routed in a consistent manner. For example, packets carrying real-time information can be routed to low latency paths across the networks. Thus the key success to MPLS is to efficiently control and distribute the bandwidth available between applications across the networks. A lot of research effort on bandwidth management in MPLS networks has already been devoted in the past. However, with the imminent roll out of 5G, MPLS is seen as a key technology for mobile backhaul. To cope with the 5G demands of rich, context aware and multimedia-based user applications, more efficient bandwidth management solutions need to be derived. This thesis focuses on the design of bandwidth management algorithms, more specifically QoS scheduling, in MPLS network for 5G mobile backhaul. The aim is to ensure the reliability and the speed of packet transfer across the network. As 5G is expected to greatly improve the user experience with innovative and high quality services, users’ perceived quality of service (QoS) needs to be taken into account when deriving such bandwidth management solutions. QoS expectation from users are often subjective and vague. Thus this thesis proposes the use of fuzzy logic based solution to provide service aware and user-centric bandwidth management in order to satisfy requirements imposed by the network and users. Unfortunately, the disadvantage of fuzzy logic is scalability since dependable fuzzy rules and membership functions increase when the complexity of being modelled increases. To resolve this issue, this thesis proposes the use of neuro-fuzzy to solicit interpretable IF-THEN rules.The algorithms are implemented and tested through NS2 and Matlab simulations. The performance of the algorithms are evaluated and compared with other conventional algorithms in terms of average throughput, delay, reliability, cost, packet loss ratio, and utilization rate. Simulation results show that the neuro-fuzzy based algorithm perform better than fuzzy and other conventional packet scheduling algorithms using IP and IP over MPLS technologies. / Tertiary Education Trust Fund (TETFUND)

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