Surface impedance studies as applied to EM surface wave propagation

Sokolov, Vladimir,

January 1970

Thesis (M.S.)--University of Wisconsin--Madison, 1970. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Microwaves. Impedance (Electricity)

A study of the building algorithm for the bus impedance matrix

Kruempel, Kenneth Charles,

January 1970

Thesis (Ph. D.)--University of Wisconsin--Madison, 1970. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Algorithms. Impedance (Electricity)

A piezoelectric velocity probe

Falstad, Robert D.

January 1960

Thesis (M.S.)--University of Wisconsin--Madison, 1960. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaf 42).

Pyro- and piezo-electricity. Gases.

Research on operating and integrating inductive elements in dimmable electroic ballasts /

Chan, Samuel Sau-Man.

January 2005

Thesis (Ph. D.)--City University of Hong Kong, 2005. / "Submitted to Department of Electronic Engineering in partial fulfillment of the requirements for the degree of Doctor of Philosophy." Includes bibliographical references (leaves 109-118).

Transient error resilience in network-on-chip communication fabrics

Ganguly, Amlan,

January 2007

Thesis (M.S. in electrical engineering)--Washington State University, May 2007. / Includes bibliographical references (p. 70-73).

Investigating the magnetic properties of tissue with MRI phase at 7T

Tendler, Benjamin Charles

January 2017

In this thesis, the potential of MRI phase to reveal the magnetic properties of tissue is thoroughly investigated. Extending beyond the well established field of quantitative susceptibility mapping (QSM), consideration is given to the influence of susceptibility anisotropy, chemical exchange, non-spherical susceptibility inclusions and multi-compartmental signal evolution from both a theoretical and experimental viewpoint. The first experimental chapter discusses a collaborative project with Cardiff University Brain Research Imaging Centre (CUBRIC) and the Department of Neurobiology in Tel-Aviv University to investigate neuroplasticity changes in rats. In this chapter the contribution from the SPMIC is described, detailing an analysis pipeline to generate and optimise isotropic susceptibility and R2∗ maps from multi-echo gradient echo (GE) in-vivo rat datasets obtained on a 7T Bruker Biospec 70/30 MR system. The second experimental chapter investigates the potential of frequency difference mapping (FDM), a recently developed phase processing technique which characterises multi-compartmental signal evolution to probe microstructure content. In this chapter, a novel FDM processing algorithm is introduced which does not require the use of sophisticated phase unwrapping and image filtering. To test the effectiveness of the FDM algorithm on experimental data, ten healthy volunteers underwent a single-slice, sagittal, multi-echo GE scan on a Philips Achieva 7T MR system. Results revealed consistent contrast over the corpus callosum relative to the surrounding tissue and a high sensitivity to small changes in microstructure content. Though fitting experimental magnitude and frequency difference evolution to a three-pool white matter model, the signal evolution over the corpus callosum is described in terms of physical properties of the nerve fibres. The final experimental chapter investigates the magnetic properties of skeletal muscle. A skeletal muscle sample (in the form of a section of pork tenderloin) was placed within an agar phantom and scanned via a multi-orientation, dual-echo GE protocol on a Philips Achieva 7T MR system. Measured phase data were post-processed and novel least-squares minimisation algorithms were developed to investigate the isotropic susceptibility, anisotropic susceptibility, chemical exchange and cylindrical microstructure inclusion properties of the sample. Analysis revealed that the skeletal muscle sample was significantly more diamagnetic than agar, χI = (−121 ± 22)ppb, and a large chemical exchange contribution was also observed within the tissue, E = (31 ± 11)ppb, relative to the surrounding agar. The experimental protocol was not sensitive enough to reveal quantitative information about the anisotropic susceptibility properties of the sample, yielding an an upper bound of 10 ppb. No evidence of cylindrical susceptibility inclusions was observed within the experimental field perturbation maps.

QC501 Electricity and magnetism

Quantitative methods in magnetization transfer and chemical exchange saturation transfer at 7T

Geades, Nicolas

January 2017

Ultra-High field (7T) MRI provides high sensitivity which allows for new qualitative and quantitative methodologies to be developed, that provide clinically useful information. The work presented in this thesis is focussed on developing a quick and reliable quantitative MT and CEST methodology, taking account of the difficulties encountered at high field. The method developed here has been tested on various studies, in both healthy and diseased brain, in an effort to aid the understanding of myelination in the human brain. The work in this thesis uses the quantitative measure of MT as a marker for myelination, and it shows strong correlations between MT-based myelination and functional connectivity, as well as very strong correlation between MT and NOE. These findings showcase the potential of NOE as a myelin marker as well, as long as the MT vs. NOE relationship remains the same in pathology. Myelination is investigated (via MT and NOE) in Multiple Sclerosis (MS) and Glioma, showing a strong coupling between the two exists even in pathology. Amide Proton Transfer (APT) is also investigated in Glioma, showing similar trends to MT and NOE. High resolution anatomical images can provide valuable information on the extend of the pathology, but quantitative information of the NMR properties of tissue (like MT, NOE and APT) has the potential to detect earlier abnormalities, and give a quantitative measure of healing or degeneration caused by pathology.

QC501 Electricity and magnetism

Monitoring movement in MRI by measuring changes in the EMF induced in head-mounted coils

Bhuiyan, E. H.

January 2017

Image quality is degraded by involuntary movement of the subject in an MRI scanner. It is fairly challenging in MRI of the brain to monitor the involuntary head movement accurately. Though there are a few techniques to monitor head movement of the subject for prospective motion correction, it is still an unsolved problem in MRI. In this study, head movement inside an MR scanner is monitored via measurement of changes in the voltage induced in head mounted coils by switched magnetic field gradients. The motion of a rigid body such as the human head is decomposed into two components: namely translation and rotation. There are three degrees of freedom (DOFs) for translational motion i.e. translation along the x, y and z axes and three rotational degrees of freedom for rotational motion i.e. rotation about the x, y and z axes. Head movement is monitored in a gradient field by measuring the change in induced voltage in head mounted coils. To calculate the change in induced voltage I follow two approaches: circular loops simulation, analytical as well as numerical calculations. I show that by using a standard method one can form a linear model to identify the position and orientation of the coils. An experimental arrangement is set up to check the validity of the analytical and numerical calculations. Experiments carried out with a rig of five coils verified that the changes in induced voltage in the coils is linear with respect to the changes in position of the coils. The linear model is also verified by comparing estimated positions obtained by using the coils to those found by image realignment of fast field echo (FFE) images using Statistical Parametric Mapping (SPM). We experimentally evaluate the new approach for monitoring head movement inside an MR scanner, which exploits the linear variation of the voltages induced in a set of coils by time-varying magnetic field gradients with respect to small changes in position/orientation. This approach was tested by attaching five coils to a structured agar phantom and a healthy volunteer's head. The results suggest that it is possible to estimate the position and orientation with 0.22 mm and 0.24˚ root-mean-square error using this set-up. The new approach could be used for prospective or retrospective motion correction. An experiment is also carried out by using free running EPI (Echo Planar Imaging) to track the head movement inside an MR scanner. There is a strong relation between head movement and EPI waveforms, the central point of the experiment is to track the head displacements via measuring induced voltage in the coils by using EPI waveforms during execution of free running EPI. The results obtained from the experiment reveal that the method is promising.

QC501 Electricity and magnetism

MBE growth, characterisation and physics of antiferromagnetic copper manganese arsenide

Hills, Victoria Anne

January 2016

Research into antiferromagnetic materials for application in spintronics has rapidly expanded in recent years. The prediction and observation of spin based phenomena with antiferromagnets as the active components, has expanded the field and there is a need for high quality materials that are compatible with existing III-V semiconductor systems to expand this research. Copper manganese arsenide is one such material and will be the subject of this thesis. Early studies had shown that this material grows epitaxially on both gallium arsenide and gallium phosphide substrates by molecular beam epitaxy. This thesis builds on this early work by further characterising CuMnAs, improving the techniques used to grow it, and enhancing our understanding of the material. A key result of this thesis is that the Néel temperature of CuMnAs can be studied using temperature dependent transport measurements. This method allows for a range of layer thickness (from between 5 and 140 nm) to be studied. We find that the Néel temperature of CuMnAs is suppressed by around 100K when the layer thickness is less than 10nm. At the thicknesses studied there is agreement (around (480±5)K) with the more established neutron diffraction technique for measuring Néel temperature, which was also used to determine the magnetic structure of the CuMnAs studied. In addition to measurement of the Néel temperature of CuMnAs, a detailed study is made in this thesis of the ideal growth conditions for ultrathin (sub 10nm) films of CuMnAs. Post-growth examination of ultrathin layers of CuMnAs showed that significant portions of material were missing due to poor adhesion. This thesis shows the results of the development of several different nucleation and growth methods, which were used to improve the adhesion of the CuMnAs layer to the substrate. These methods are evaluated using atomic force microscopy, x-ray diffraction, magnetometry and transport measurements. CuMnAs has previously shown to strongly prefer growth under stoichiometric conditions, as non-stoichiometric conditions have tended to favour the formation of clusters of the excess material. In excess Mn conditions these clusters are ferromagnetic MnAs inclusions that are conducting and contribute to the magnetic behaviour. This thesis presents the results of a simulation study of the conductivity of ferromagnetic elements in a non-ferromagnetic medium. This approach could be extended to allow the number of inclusions in a CuMnAsl layer to be approximated from transport measurements. Finally, this thesis will also look at the effects of alloying CuMnAs with phosphorous. This reduces the lattice constants of the material while retaining the same crystal and magnetic structure. In thick films of the alloy the Néel temperature increases from that of CuMnAs.

538

QC501 Electricity and magnetism

Narrowband powerline communications on the domestic mains in the CENELEC frequencies

Cooper, David

January 2000

The object of this dissertation is to identify effective techniques for powerline communication using the low voltage (240V) domestic mains electricity supply in the sub 150 kHz frequency range as defined by the European CENELEC standard, concentrating on narrowband techniques suitable for low data rate telemetry applications. In order to conduct a comparison of communications techniques a model of the channel is invaluable. However a survey of the existing literature reveals that the presently available Knowledge of the channel characteristics and impairments of the low voltage mains is limited. In particular there is no widely accepted quantitative model of the mains as a narrowband communications link. The study consisted of four main phases. First, a new piece of equipment, the 'Channel Probe', was developed to perform channel soundings of the mains. The second phase was largely experimental; empirical channel sounding results were collected using the Channel Probe. In the third phase a model was defined to fit the empirical results and a quantitative simulation was constructed based on this model. Lastly, communications techniques were studied using this simulation. This document presents the key impairments introduced by the channel, and proposes a novel narrowband channel model. Quantitative values for these phenomena are identified and justified against the measured results. The simulation that was constructed in accordance with this channel model is entirely novel, and is used to study suitable modulation schemes, receiver structures and algorithms. Original performance results from this simulation are presented, and a novel low complexity narrowband communication scheme is presented which has significant advantages over existing commercially available systems.

621.319

Electricity supply; Telemetry