Global ETD Search

31	Chaoization and stabilization of electric motor drives and their industrial applications Wang, Zheng, 王政 January 2008 (has links) published_or_final_version / Electrical and Electronic Engineering / Doctoral / Doctor of Philosophy Electric motors, Alternating current. Electric motors, Direct current. Chaotic behavior in systems.
32	Imaging the neuromodulation of pain Lin, Richard L. January 2011 (has links) Chronic pain is a major health problem that affects approximately 20% of the adult population, but only 60% of its patients find success in managing their condition. As an alternative therapeutic tool, transcranial direct current stimulation (tDCS) has appeared promising in recent literature, with several papers using the left dorsolateral prefrontal cortex (L-DLPFC) as the stimulation target due to its inherent role in pain modulation. However, the underlying mechanisms of this treatment have never been directly investigated. The thesis intends to explore this question through the application of a combination of tDCS, functional and structural imaging, and an ongoing pain model. The first study investigated the task-free effects of L-DLPFC tDCS by using concurrent arterial spin labeling (ASL) perfusion imaging. Anodal (excitatory) tDCS was associated with an increase in regional cerebral blood flow (rCBF) of L-DLPFC, while cathodal (inhibitory) tDCS was related to a relative decrease. Regions connected to L-DLPFC, such as thalamus and primary somatosensory cortex, also experienced significant perfusion changes. Further analyses found modulations of L-DLPFC–thalamic functional correlations, which was particularly relevant due to the importance of the thalamus in antinociceptive processing. To understand pain neuromodulation, a robust ongoing pain model was required to serve as a platform for the investigation. Thus, electrical, thermal, and capsaicin stimuli were tested in a series of studies. The former two did not produce an ongoing pain sensation, thus failing to replicate a chronic pain experience on healthy volunteers. However, topical application of capsaicin appeared to induce such a response, which entailed a pain intensity rating between 5 and 7 on a 0-10 visual analogue scale for at least 30 minutes. Careful screening ensued to select capsaicin responders from the cohort, who served as the research volunteers for the remainder of the thesis. Combining these two studies, rCBF changes associated with tDCS-induced pain neuromodulation were then directly investigated with concurrent ASL and the above capsaicin model. Behavioral measurements suggested a significant reduction in pain intensity for the anodal tDCS condition over the sham tDCS condition, which corroborated the results from previous pain-tDCS studies. Modulations of L-DLPFC and thalamic rCBF continued to be observed with anodal tDCS. In addition, the activity of the posterior insula, an indicator of ongoing pain intensity, was higher for the sham tDCS condition than for the anodal tDCS condition. The final study explored the importance of L-DLPFC–thalamic connection in pain modulation with diffusion tensor imaging (DTI). Probability tractography and tract-based spatial statistics (TBSS) were used to extract the mean fractional anisotropy (FA) of the tract. As hypothesized, the mean FA values within this tract positively correlated with the pain intensity changes, which indicated that individuals with stronger structural connection enjoyed greater alleviation from L-DLPFC tDCS. As a whole, the above studies suggest that the clinical efficacy of L-DLPFC tDCS in pain treatment may arise from the resulting top-down modulation of the thalamus. Further studies on chronic pain patients may offer further verification of the mechanism that has been proposed in this thesis. 616.0472
33	Transcranial stimulation to enhance cortical plasticity in the healthy and stroke-affected motor system Amadi, Ugwechi January 2012 (has links) This thesis investigated transcranial direct current stimulation (tDCS) as applied to the motor system, and its ability to modulate underlying cortical processes and resultant motor behaviours. Functional magnetic resonance imaging (fMRI) and transcranial magnetic stimulation (TMS) were employed to assess the extent to which tDCS induces quantifiable changes in neural structure and function in controls and stroke patients. Modifications in the connectivity of intrinsic functional networks following tDCS application were examined using resting state fMRI. Polarity-specific changes were found: cathodal (inhibitory) tDCS increased the strength of the default mode network and increased functional coupling between major nodes within the motor network. No significant effects were found following anodal (excitatory) tDCS. Although anodal tDCS elicited only subtle changes in resting activity, it is known to produce robust modifications of behaviour. Single and paired-pulse TMS were used to investigate the neurophysiological underpinnings of these changes. Consistent with the theory of homeostatic plasticity, anodal tDCS applied prior to task performance increased GABAA-mediated cortical inhibition and worsened behaviour. The specificity of these changes suggests a central role for the mechanism of surround inhibition. A longitudinal clinical trial in chronic stroke patients was conducted to determine the utility of tDCS as an adjunct in motor rehabilitation. Serial MRI scans revealed that, when combined with motor training, anodal tDCS increased functional activity and grey matter in primarily ipsilesional motor areas. These brain changes were correlated with behavioural improvements in the stroke-affected upper limb. The laterality of connectivity at baseline, as measured by resting state activity and corticospinal tract integrity, was predictive of response to the rehabilitation program, particularly in those stroke patients who received tDCS. Asymmetry favouring the contralesional hemisphere predicted greater behavioural gains. Such results underscore the importance of re-normalisation of structure and functional activity toward the lesioned hemisphere in stroke rehabilitation.
34	Parallel multi-modal optimal design and sensitivity assessment for electric power systems Yazdanpanah Goharrizi, Ali 05 April 2016 (has links) This thesis proposes a novel algorithm to optimize multi-modal, nonlinear, black-box objective functions for electric power system design using an electromagnetic transients (EMT) simulator. The algorithm discovers multiple local optimal solutions for a given complex power system, and then generates accurate surrogate models of an objective function around each discovered local optimal solution. These surrogate models represent the local behaviour of the objective function that can be used in the subsequent stages of sensitivity analyses. Using surrogate models instead of intensive transient simulation during sensitivity analysis reduces computational intensity and simulation time. This makes the proposed algorithm particularly suited for optimization of computationally expensive black-box functions. The stages of the algorithm can be implemented independently and hence the computations can be done in parallel. Therefore, the algorithm is implemented in a parallel environment to gain significant speed-up in the design of electric power systems. Comparative studies in terms of objective function evaluation and computation time are provided. Using several multi-modal benchmark objective functions, the superiority of the proposed algorithm compared to other recently developed algorithms is demonstrated. Additionally, the application of the algorithm in the design process of complex electric power system demonstrated through several examples. The case studies show that the parallelized algorithm provides computational savings up to 39 times compared to the conventional sequential approach. / May 2016 power system optimization surrogate model sensitivity assessment parallel algorithm high voltage direct current drive system
35	Comparison of the lightning performance between the poles of the Cahora-Bassa ±533 kV HVDC lines Strelec, Gavin Jason January 2016 (has links) This work contributes toward research in the field of lightning performance of High Voltage Direct Current (HVDC) transmission lines, focusing on the impact of the line polarity on the incidence of line faults. Although there has been some recent research into the influence of polarity, there appears to be no confirmed effect that might influence the design of new lines. The research presents an investigation into the lightning performance of the two poles of the Cahora-Bassa HVDC transmission line. In order to compare the performance of the two polarities, the average lightning exposure over an 8-year period was confirmed to be very similar for both lines. Lightning stroke data from the South African Lightning Detection Network was correlated with fault times from the transmission-line protection scheme. The classification of the lightning related faults was used to determine the relative performance of the two poles, particularly in relation to polarity, and to infer if there was any influence of polarity on the lightning attachment process. This investigation for the Cahora-Bassa scheme shows that twenty-three out of twenty-five lightning related faults occurred on the positive pole. The results concur with performance experience on several HVDC lines from China and Canada, which indicate that lightning related faults favour the positive pole by a ratio of between 8:1 and 10:1. This represents a valuable contribution, which substantiates that HVDC line polarity has an influence on the lightning attachment process, and indicates that there is a need to re-examine the lightning shielding design for HVDC transmission lines. / GS2016 Telephone lines--Lightning protection Lightning High voltages
36	Efeito da estimulação transcraniana de corrente contínua nos sintomas vasomotores do climatério : ensaio clínico randomizado, cego, em paralelo, controlado com placebo-sham Bianchi, Mônia Steigleder January 2015 (has links) Introdução: Climatério é definido como o período de tempo onde ocorre a mudança de vida reprodutiva para não reprodutiva, com extensão de duração variável. Durante esse período e após o estabelecimento da menopausa, é comum o surgimento de diversos sintomas que expressam o esgotamento dos folículos ovarianos. Dentre os sintomas, o mais comumente relatado pelas mulheres são os sintomas vasomotores ou fogachos. Além da Terapia de Reposição Hormonal (TRH), outras medicações como os Inibidores Seletivos da Recaptação da Serotonina (ISRS) têm sido empregadas na tentativa de melhorá-los. Justificativa: TRH não pode ser aplicado a todas as mulheres com sintomas. As medicações não hormonais, apesar de apresentarem melhores respostas que placebo, ainda demonstram pouco impacto clínico na redução dos sintomas vasomotores. Esta lacuna permite avaliar outras alternativas terapêuticas, como a Estimulação Transcraniana por Corrente Direta (ou tDCS, do inglês transcranial direct current stimulation). O racional para estudar o efeito desta técnica neste contexto, é o seu possível efeito modulatório autonômico. O que reforça a escolha desta técnica é o fato de ter eficácia demonstrada em outras patologias como depressão, dor, doença Parkinson dentre outras. A tDCS é um método de neuromodulação transcraniana não invasivo, que se baseia na aplicação de correntes contínuas de baixa intensidade, através de eletrodos colocados sobre o escalpo, de forma simples e indolor. Objetivo: Avaliar o efeito da tDCS (tratamento ativo) comparada ao tDCS-sham (placebo) nos sintomas vasomotores de mulheres na pós- menopausa como objetivo primário; e como objetivo secundário, seus efeitos na qualidade de vida. Método: Ensaio Clínico Randomizado realizado em 30 pacientes pós-menopáusicas com queixa de pelo menos 05 episódios de fogachos/dia. Participantes foram selecionadas no ambulatório de Climatério do Serviço de Ginecologia e Obstetrícia do Hospital de Clínicas de Porto Alegre e via chamamento de jornal. Estas foram randomizadas para um dos grupos: tDCS ou placebo-sham. A intervenção consistiu na aplicação de sessões diárias de estimulação com corrente elétrica de 02 mili Ampere, pelo período de 10 dias consecutivos, à exceção dos finais de semana. Por uma semana anterior à intervenção e por 30 dias após, as participantes registravam o número e intensidade dos fogachos ao dia. Responderam ao Women´s Health Questionaire (WHQ) antes e ao termino da intervenção. Resultados: A média de fogachos/dia se comportou de forma semelhante nos dois grupos havendo uma redução do número de fogachos nas três primeiras semanas após intervenção com retorno ao basal a partir da quarta semana pós-aplicação. No grupo tDCS, se observou uma tendência a uma transferência dos fogachos intensos para leves sugerindo uma melhora clínica. Os resultados, apesar de não apresentarem significância estatística, reforçam a ideia de ampliar a investigação, com maior número de pacientes e com maior tempo de duração além do caráter inovador da pesquisa. / Introduction: Menopause is defined as a period where there is a change from the reproductive stage to a nonreproductive phase, with variable duration. During this period and following the establishment of menopause, there is usually an onset of several symptoms indicating the depletion of ovarian follicles. Among the symptoms, the ones that are more frequently reported by women are vasomotor symptoms or hot flashes. In addition to Hormone Replacement Therapy (HRT), other medications such as Selective Serotonin Reuptake Inhibitors (SSRIs) have been employed to treat them. Justification: HRT may not be applied to all women with symptoms. Non-hormonal medications, despite having better responses than placebo, have still shown little clinical impact on the reduction of vasomotor symptoms. This gap allows other therapeutic alternatives to be considered, such as Transcranial Direct Current Stimulation (tDCS). The rationale for studying the effect of this technique in this context is its possible autonomic modulatory effect. What reinforces the choice of this technique is the efficacy which it has demonstrated in other disorders such as depression, pain, Parkinson's disease, among others. tDCS is a non-invasive transcranial neuromodulation method based on the application of continuous low-intensity currents through electrodes placed to the scalp, in a simple and painless way. Goal: To evaluate the effect of tDCS (active treatment) compared to tDCS-sham (placebo) on vasomotor symptoms in postmenopausal women as a primary endpoint and its effects on quality of life as a secondary endpoint. Method: Randomized Clinical Trial conducted in 30 postmenopausal patients complaining of at least five episodes of hot flashes per day. Participants were selected at the Gynecology and Obstetrics Service Menopause Outpatient Clinic, Hospital de Clínicas de Porto Alegre and via a newspaper call. These were randomized to one of the groups: tDCS or placebo-sham. The intervention consisted of daily sessions in which stimulation was applied with an electric current of 02 milliamperes for 10 consecutive days, except on weekends. Participants recorded the number and intensity of hot flashes per day for one week before and for 30 days after the intervention. They answered the Women’s Health Questionnaire (WHQ) before and after the intervention completion. Results: The mean of hot flashes/day behaved in a similar way in both groups, and there was a reduction in hot flashes in the first three weeks following the intervention with a return to baseline starting in the fourth week after the administration. In the tDCS group, a trend towards a conversion of intensive hot flashes into mild ones was noted, which suggested a clinical improvement. The results, despite not showing statistical significance, supported the idea of extending the investigation with a larger number of patients and longer duration, in addition to the innovating nature of the research. Menopausa Fogachos Menopause Transcranial direct current stimulation Vasomotor symptoms/hot flashes
37	Conception d'un module électronique de puissance pour application haute tension / Design of a power electronic module for high voltage application Reynes, Hugo 24 April 2018 (has links) Satisfaire les besoins en énergie de manière responsable est possible grâce aux énergies renouvelables, notamment éoliennes et solaires. Cependant ces centres de captation d’énergie sont éloignés dans zones de consommation. Le transport de l’énergie via des réseaux HVDC (haute tension courant continu) permet un rendement et une flexibilité avantageuse face au transport HVAC (haute tension courant alternatif). Ceci est rendu possible grâce aux convertisseurs utilisant l’électronique de puissance. Les récents développements sur les semi-conducteurs à large bande interdite, plus particulièrement le carbure de silicium (SiC) offrent la possibilité de concevoir ces convertisseurs plus simples, utilisant des briques technologiques de plus fort calibre (≤ 10 kV). Cependant le packaging, essentiel à leur bon fonctionnement, ne suit pas ces évolutions. Dans cette thèse, nous explorons les technologies actuelles ainsi que les limites physique et normatives liées au packaging haute tension. Des solutions innovantes sont proposées pour concevoir un module de puissance haute tension, impactant que faiblement les paramètres connexes (résistance thermique, isolation électrique et paramètres environnementaux). Les éléments identifiés comme problématiques sont traités individuellement. La problématique des décharges partielles sur les substrats céramiques métallisés est développée et une solution se basant sur les paramètres géométriques a été testée. Le boitier standard type XHP-3 a été étudié et une solution permettant de le faire fonctionner à 10 kV à fort degré de pollution a été développée. / The supply of carbon-free energy is possible with renewable energy. However, windfarms and solar power plants are geographically away from the distribution points. Transporting the energy using the HVDC (High Voltage Direct Current) technology allow for a better yield along the distance and result in a cost effective approach compared to HVAC (High Voltage Alternative Current) lines. Thus, there is a need of high voltage power converters using power electronics. Recent development on wide bandgap semiconductors, especially silicon carbide (SiC) allow a higher blocking voltage (around 10 kV) that would simplify the design of such power electronic converters. On the other hand, the development on packaging technologies needs to follow this trend. In this thesis, an exploration of technological and normative limitation has been done for a high voltage power module design. The main hot spot are clearly identified and innovative solutions are studied to provide a proper response with a low impact on parasitic parameters. Partial Discharges (PD) on ceramic substrates is analyzed and a solution of a high Partial Discharge Inception Voltage (PDIV) is given based on geometrical parameters. The XHP-3 like power modules are studied and a solution allowing a use under 10 kV at a high pollution degree (PD3) is given. Electronique de puissance Module de puissance Packaging High voltage Direct Current - HVDC Medium Voltage Direct Current - MVDC Insulated Gate Bipolar Transistor - IGBT Mosfet Décharges partielles Power Electronics Power Module Packaging High voltage Direct Current - HVDC Medium Voltage Direct Current - MVDC Insulated Gate Bipolar Transistor - IGBT Mosfet Insulation Partial discharges 621.317 072
38	Comparative Study of HVAC and HVDC Transmission Systems With Proposed Machine Learning Algorithms for Fault Location Detection January 2019 (has links) abstract: High Voltage Direct Current (HVDC) Technology has several features that make it particularly attractive for specific transmission applications. Recent years have witnessed an unprecedented growth in the number of the HVDC projects, which demonstrates a heightened interest in the HVDC technology. In parallel, the use of renewable energy sources has dramatically increased. For instance, Kuwait has recently announced a renewable project to be completed in 2035; this project aims to produce 15% of the countrys energy consumption from renewable sources. However, facilities that use renewable sources, such as solar and wind, to provide clean energy, are mostly placed in remote areas, as their installation requires a massive space of free land. Consequently, considerable challenges arise in terms of transmitting power generated from renewable sources of energy in remote areas to urban areas for further consumption. The present thesis investigates different transmission line systems for transmitting bulk energy from renewable sources. Specifically, two systems will be focused on: the high-voltage alternating current (HVAC) system and the high-voltage direct current (HVDC) system. In order to determine the most efficient way of transmitting bulk energy from renewable sources, different aspects of the aforementioned two types of systems are analyzed. Limitations inherent in both HVAC and HVDC systems have been discussed. At present, artificial intelligence plays an important role in power system control and monitoring. Consequently, in this thesis, the fault issue has been analyzed in transmission systems, with a specific consideration of machine learning tools that can help monitor transmission systems by detecting fault locations. These tools, called models, are used to analyze the collected data. In the present thesis, a focus on such models as linear regression (LR), K-nearest neighbors (KNN), linear support vector machine (LSVM) , and adaptive boost (AdaBoost). Finally, the accuracy of each model is evaluated and discussed. The machine learning concept introduced in the present thesis lays down the foundation for future research in this area so that to enable further research on the efficient ways to improve the performance of transmission line components and power systems. / Dissertation/Thesis / Masters Thesis Electrical Engineering 2019 Electrical engineering High Voltage Direct Current Kuwait 2035 Project Machine Learning Renewable Integration
39	Effects of Expectations on Cognitive Enhancement Interventions in Young and Older Adults Rabipour, Sheida 20 September 2018 (has links) With increasing life expectancy and global population of older adults, preserving cog- nitive function throughout life represents a growing priority. Numerous approaches to cognitive enhancement exist, but few have scientific merit. Among the most preva- lent – and commercialized – approaches are cognitive training (“brain training”) and non-invasive brain stimulation through electric currents applied at the surface of the scalp. The present dissertation describes a collection of work contextualizing the appeal of these cognitive enhancement methods and addressing some of the most pervasive limitations of research in this field thus far. One largely ignored issue in cognitive intervention research pertains to people’s expectations of programs and their relationship with intervention outcomes. In a series of initial studies, we developed and validated the Expectation Assessment Scale (EAS), a tool created to measure as well as prime expectations of outcomes in the context of cognitive enhancement interventions. In our first two studies, we probed expectations of cognitive training or non-invasive brain stimulation in over 1,000 young, middle-aged, and older adults. Ratings on the EAS suggested that older adults may have particularly high expectations of cognitive training, but that expectations can be primed to increase or decrease – at least in hypothetical scenarios. We used these data to assess the psychometric properties of the EAS with item-response theory, and confirmed its internal consistency. Next, we incorporated the EAS into two cognitive enhancement trials, one in- vestigating a computerized cognitive training intervention in nearly 100 older adults and another examining non-invasive brain stimulation in nearly 100 young adults. Both trials had a double-blind balanced-placebo design in which participants were assigned to the intervention or control condition, and then subdivided to receive ei- ther high or low expectation priming (i.e., primed to have high or low expectations of the program’s effectiveness). Although expectation ratings replicated our previous findings, results from these trials suggest little, if any, effect of either expectations or the intervention on performance outcomes. We nevertheless found that participants enjoyed their assigned program and that those who received high expectation prim- ing tended to report a more positive experience. Our findings put into question the effectiveness of such interventions and support the need for more rigorous trials of cognitive enhancement. Expectations Cognitive enhancement Brain training Non-invasive brain stimulation Placebo effects
40	Cortical Stimulation Mapping of Heschl’s Gyrus in the Auditory Cortex for Tinnitus Treatment Huang, Austin 01 January 2019 (has links) Tinnitus is the perception of sound in the absence of an actual sound stimulus. Recent developments have shifted the focus to the central nervous system and the neural correlate of tinnitus. Broadly, tinnitus involves cortical map rearrangement, pathological neural synchrony, and increased spontaneous firing rates. Various cortical regions, such as Heschl’s gyrus in the auditory cortex, have been found to be associated with different aspects of tinnitus, such as perception and loudness. I propose a cortical stimulation mapping study of Heschl’s gyrus using a depth and subdural electrode montage to conduct electrocorticography. This study would provide high-resolution data on abnormal frequency band oscillations characteristic of tinnitus and pinpoint regions where they occur. The validity of the neural synchrony model would also be tested in this study. tinnitus coordinated reset ECoG electrocorticography tDCS transcranial direct current stimulation Computational Neuroscience Speech and Hearing Science

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