Veerkragtigheidsmeganismes wat onderwys ondersteun

Afrika, Bernitto Timothy Afrika

04 1900

Thesis (MEd)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: Education supporting factors is of great importance for children who are growing up in very challenging circumstances. The challenge of poverty affects people differently and people also react differently towards it. If educators can understand why certain children can withstand certain risk factors such as severe contextual backlogs, whilst others cannot, they will have a better understanding where to intervene, and also how to put preventative measures in place. (Garmenzy, 1991). This resilience who is intrinsic amongst children, acts as protective factors against certain developmental factors to which children might be exposed to. The different supportive structures who is critical for the learners, acts as extrinsic protective factors. The stronger the protective factors are, the better the parents can resist the pressure from poverty (Ross,1995). This study therefore aimed to understand what education supporting factors exist for learners who are growing up in challenging circumstances. The researcher worked from an interpretive paradigm. The study’s orientation is a basic qualitative research and included the following: purposive sample selection to identify research participants, open questionnaires to gather their biographic information, individual interviews and field notes to generate data, and content analysis to analyse data. Research findings indicate that the encouragement and extensive support that the learners enjoy plays a huge role in their lives. The study also highlighted that if the learners’ intrinsic resilience can be further developed and when the extensive support is sustainable, the learners can be successful and handle life’s challenges. / AFRIKAANSE OPSOMMING: Onderwys ondersteunende faktore is van groot belang by kinders wat in uitdagende omstandighede groot word. Die uitdaging van armoede raak mense op verskillende maniere en mense reageer verskillend daarop. As opvoeders kan verstaan waarom sommige kinders risiko faktore soos erge kontekstuele agterstande kan weerstaan, terwyl ander nie kan nie, sal hulle ’n beter kans staan deur te weet hoe om in te gryp, en hoe om voorkomende maatreëls te tref (Garmenzy, 1991). Hierdie veerigtigheid wat inherent onder leerders is, tree as beskermende faktore op teen ontwikkelingsfaktore waaraan die kind blootgestel kan word. Die verskillende ondersteuningsnetwerke wat kritiek is vir die leerders, tree op as eksterne beskermende faktore, want hoe sterker die ondersteuning is, hoe beter kan ouers die druk wat deur armoede veroorsaak word weerstaan (Ross,1995). Die studie het dit ten doel om te verstaan en insig te bekom met watter faktore onderwys ondersteun, vir leerders wat in uitdagende omstandighede grootword. Die navorser het binne ’n interpretivistiese paradigma gewerk. Die studie se orientasie is ’n basiese kwalitatiewe navorsing en het die volgende ingesluit: doelbewuste seleksie om te bepaal wie die deelnemers was, oop vraelyste om hul biografiese inligting te bekom, individuele onderhoude en veldnotas om data te genereer, asook inhoudsanalise om die data te analiseer. Navorsingsbevindinge dui daarop dat die aanmoediging en uitgebreide ondersteuning wat die leerders geniet ’n groot rol in hul lewens speel. Uit die studie was dit duidelik dat as die leerders se inherente veerkragtigheid verder ontwikkel word en die uitgebreide ondersteuning is volhoubaar, kan die leerders suksesvol wees en die alledaagse uitdagings met gemak hanteer.

Theses -- Educational psychology

Dissertations -- Educational psychology

Teacher-student relationships

UCTD

Educational Psychology

Enhanced Fast Rerouting Mechanisms for Protected Traffic in MPLS Networks

Hundessa Gonfa, Lemma

03 April 2003

Multiprotocol Label Switching (MPLS) fuses the intelligence of routing with the performance of switching and provides significant benefits to networks with a pure IP architecture as well as those with IP and ATM or a mix of ther Layer 2 technologies. MPLS technology is key to scalable virtual private networks (VPNs) and end-to-end quality of service (QoS), enabling efficient utilization of existing networks to meet future growth. The technology also helps to deliver highly scalable, differentiated end-to-end IP services with simpler configuration, management, and provisioning for both Internet providers and end-users. However, MPLS is a connection-oriented architecture. In case of failure MPLS first has to establish a new label switched path (LSP) and then forward the packets to the newly established LSP. For this reason MPLS has a slow restoration response to a link or node failure on the LSP.The thesis provides a description of MPLS-based architecture as a preferred technology for integrating ATM and IP technologies, followed by a discussion of the motivation for the fast and reliable restoration mechanism in an MPLS network. In this thesis first we address the fast rerouting mechanisms for MPLS networks and then we focus on the problem of packet loss, packet reordering and packet delay for protected LSP in MPLS-based network for a single node/link failure. In order to deliver true service assurance for guaranteed traffic on a protected LSP we use the fast rerouting mechanism with a preplanned alternative LSP. We propose enhancements to current proposals described in extant literature. Our fast rerouting mechanism avoids packet disorder and significantly reduces packet delay during the restoration period.An extension of the Fast Rerouting proposal, called Reliable and Fast Rerouting (RFR), provides some preventive actions for the protected LSP against packet loss during a failure. RFR maintains the same advantages of Fast Rerouting while eliminating packet losses, including those packet losses due to link or node failure (circulating on the failed links), which were considered to be "inevitable" up to now.For the purpose of validating and evaluating the behavior of these proposals a simulation tool was developed. It is based on the NS, a well-known network simulator that is being used extensively in research work. An extension featuring the basic functionality of MPLS (MNS) is also available for the NS, and this is the basis of the developed simulation tool.Simulation results allow the comparison of Fast Rerouting and RFR with previous rerouting proposals.In addition to this we propose a mechanism for multiple failure recovery in an LSP. This proposal combines the path protection, segment protection and local repair methods. In addition to the multiple link/node failure protection, the multiple fault tolerance proposal provides a significant reduction of delay that the rerouted traffic can experience after a link failure, because the repair action is taken close to the point of failure.Then we proceed to address an inherent problem of the preplanned alternative LSP. As alternative LSPs are established together with the protected LSP it may happen that the alternative is not the optimal LSP at the time the failure occurs. To overcome this undesired behavior, we propose the Optimal and Guaranteed Alternative Path (OGAP). The proposal uses a hybrid of fast-rerouting and a dynamic approach to establish the optimal alternative LSP while rerouting the affected traffic using the preplanned alternative LSP. This hybrid approach provides the best of the fast rerouting and the dynamic approaches.At the same time we observed that the protection path becomes in fact unprotected from additional failures after the traffic is rerouted onto it.To address this we propose a guarantee mechanism for protection of the new protected LSP carrying the affected traffic, by establishing an alternative LSP for the rerouted traffic after a failure, avoiding the vulnerability problem for the protected traffic.Finally, we present a further optimization mechanism, adaptive LSP, to enhance the existing traffic engineering for Quality of Services (QoS)provision and improve network resource utilization. The adaptive LSP proposal allows more flexibility in network resource allocation and utilization by adapting the LSP to variations in all network loads,resulting in an enhancement of existing MPLS traffic engineering.

QoS(Quality of Services)

survivability

LSR(Label Switching Router)

alternative path

resilence

protected traffic

fast reroute

protected path

MPLS(Multiprotocol Label Switching)

LSP(Label Switching Path)

3304.Tecnologia dels ordinadors

62

621.3