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A grammar of WanoBurung, Willem January 2016 (has links)
This thesis is a descriptive analysis of Wano, a Trans-New Guinea language found in West Papua which is spoken by approximately 7,000 native speakers. The thesis includes: (i) an introduction of Wano topography and demography; a brief ethnographic sketch; some sociolinguistic issues such as name taboo, counting system and kinship terms; and typological profile of the language in chapter 1; (ii) morphophonological properties in chapter 2; (iii) forms and functions of nouns in chapter 3; (iv) verbs in chapter 4; (v) deixis in chapter 5; (vi) clause elements in chapter 6; and (vii) intransitive/transitive non-verbal predication in chapter 7; (viii) clause combination is consecutively observed in terms of coordination and subordination in chapter 8; serial verb constructions in chapter 9; clause linking in chapter 10; and bridging linkage in chapter 11. Chapter 12 sums-up the overall thesis. Wano has 11 consonantal and 5 vocalic phonemes expressed through their allophonic variations, consonantal assimilation and vocalic diphthongs. The only fricative phoneme attested is bilabial fricative /Î2/. There are two open and two closed syllable patterns where all consonants are syllable-onset, while approximants can also be syllable-coda. Vowels are syllable-nucleus. Stress is syllable-final which will be penultimate in cliticization. The phonology-morphology interface provides a significant contribution to the shaping of conjugational verbs, which, in turn, plays an essential role to an understanding of Wano verbal system where distinction between roots, stems, citation forms, sequential forms and tense-aspect-mood is defined. Wano is a polysynthetic language that displays an agglutinative-fusional morphology. Although the alienable-inalienable noun distinction is essentially simple in its morphology, the sex-distinction of the possessor between kin terms allows room for semantic-pragmatic complexity in the interpretation of their various uses. Wano has four non-verbal predications, consists of experiential event, nominal, adjectival, and deictic predicates. Wano is a verb-final language that allows pronominal pro-drop and has no rigid word order for arguments. A clause may consist only of (i) a single verb, (ii) a single inalienable noun, (iii) a serial verb construction, (iv) a combination of an inalienable noun with a verb, and or (v) a combination of an inalienable noun with a serial verb construction. To maintain discourse coherency, Wano makes use of tail-head linkage construction. The thesis consists of: pre-sections (i-xxxiii), contents (1-478), bibliography (479-498), and appendices (499-594) that include verb paradigms, noun paradigms, some oral texts and dialectal wordlist.
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Critical Success Factors: an Analysis of some factors at a Nuclear Power utility in South AfricaGaletta, Wilhelmina 26 January 2022 (has links)
Background: Over the years literature mainly focussed on time, cost and quality, also known as the triple constraint or ‘iron triangle', as the main factors to be considered as important for project success. Since then, many other factors were considered by various authors with the most cited being the work of Pinto and Slevin in 1988 who produced the Project Implementation Profile (PIP) which expanded on the triple constraint and listed ten Critical Success Factors (CSF) to be considered toward project success. The indication was that the success of projects can be improved if these factors were considered across the lifecycle of the project and they can be tailor-made to be specific to a particular industry. With this in mind, this research study has been conducted at a nuclear power plant (NPP) and it explores the applicability of the CSFs of the PIP towards nuclear project success. Purpose: The purpose of the thesis/dissertation was to gain and understanding from various stakeholders of what constitutes CSFs for projects undertaken at a NPP in South Africa; testing if those listed in the PIP would suffice or if additional factors need to be included specifically for nuclear projects. Research objectives: The research study considered the following research objectives: Understanding which CSFs of the PIP were important for nuclear projects and evaluate which of them are perceived by various stakeholders to be important to nuclear project success. Thereafter some CSFs of the PIP were analysed towards identifying if there were factors not included in the PIP but that were pertinent to nuclear project success. Research design and methodology: A mixed methods approach was adopted to this research. An interpretive case-study was conducted post event to understand phenomena through the participants' interpretation of their context. The case-study methodology was chosen and data collected using multiple data sources such as interviews with project managers who had successfully implemented projects and some system engineers who had conducted effectiveness reviews on such projects, gleaning the database of completed projects as well as Operating Experience (OE) / lessons learnt at Koeberg Nuclear Power Station (KNPS). This was done to determine the common factors that led to the analysed projects' individual success. Multiple cases at KNPS and the factors considered for nuclear project success, outside of the CSFs of the PIP were used to conduct the research. The design methodology used towards getting to the CSF framework for nuclear projects was informed by factors considered by the World Organisation of Nuclear Operators (WANO), Institute for Nuclear Plant Operators (INPO) and the International Atomic Energy Agency (IAEA), all organisations that are key role players in the nuclear field. This paper utilised tools and techniques to demonstrate how a framework for determining nuclear project success can be adopted. Research findings: The results revealed that while CSFs were generally understood but not known in the PIP format. Furthermore, in order for the CSFs to be applicable to nuclear project success, additional factors that are pertinent to nuclear projects needed to be included and a specific framework developed accordingly. Research Limitations: The research study focused on projects within the nuclear project management department (NPM), in order to simplify the data collection process. Strategic information that was deemed as sensitive or confidential could not be revealed explicitly during the course of data gathering and therefore inferences had to be made. Another limitation was the timing of the distribution which took place during an outage, yielding a low response rate during the allotted time compelling the Researcher to extend the time period for data collection. Finally, the uneven distribution of responses in the various phases of the nuclear project lifecycle posed a challenge with the Execution Phase being the dominating phase. This uneven distribution of results meant that the overall findings would be governed by the Execution Phase. This had an implication on the generalisability of the results. Furthermore, with the respondents' ratings of the CSF being subjective; this may have had an impact on the accuracy of results. Originality: The CSF framework for nuclear project success, when applied can provide valuable pointers for Koeberg and the nuclear industry when implementing nuclear projects for success. Practical implication: This information can be shared across NPM and related departments who form part of the nuclear project lifecycle. The information and lessons learned can also be shared in the nuclear industry by way of OE. The paper will benefit other NPP operators in applying the CSFs that are introduced in the framework to nuclear projects and provide them with the ability to monitor and control nuclear project success at each phase of the nuclear project lifecycle towards ensuring nuclear project success. The framework will allow the project manager and project team to identify, analyse, respond and monitor and control CSFs that project participants should plan for to ensure nuclear project success so as not to negatively impact the plant and the business at large with dire consequences that are introduced by project failure.
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Přístupy k zajištění jaderné bezpečnosti u reaktorů 3. generace / Approach to the nuclaer safety of the 3rd generation nuclear reactorsPavlíček, Michal January 2010 (has links)
The main target of the master´s thesis is reviewing the generation III nuclear reactors in term of the nuclear safety. At first we have to learn some theory of the nuclear safety in order to understand safety systems of the generation III nuclear reactors. Therefore the thesis is divided into two parts. Legislative and technical approaches to nuclear safety are mentioned in the first part. Regulatory bodies, whose task is to supervise nuclear safety in the nuclear power plants, belongs to the legislative approaches. There are defined terms such as defence in depth, redundancy, diversity, etc. There are mentioned methods to assessing nuclear safety – deterministic and probabilistic methods, especially probabilistic methods, for which a simple example is provided. There are also mentioned active and passive safety systems and their significance for nuclear safety and inherent safety too. There is an example of the function of the active and passive safety systems of the EDU nuclear power plant in conclusion of this issue. The second part deals with description of the selected nuclear reactors in context of the construction of the new units of nuclear power plant in Temelín. The nuclear reactors from companies, which applied for the public tender opened by ČEZ, a. s., for the construction of the ETE 3+4. Thus, the nuclear reactor MIR-1200 by ATOMSTROYEXPORT (Russian Federation), the nuclear reactor AP1000 by WESTINGHOUSE (USA) and the nuclear reactor EPR by AREVA (France) are taken into account . Comparison of the generation II and these generation III+ nuclear reactors necessarily belongs to this master´s thesis. These the generation III+ nuclear reactors are compared with the nuclear reactor VVER 440 (EDU) and in particular with the nuclear reactor VVER 1000, which is operated in the nuclear power plant Temelín. The final chapter contains generally appraisal of the whole problem.
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