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On Spectral Properties of Single Layer PotentialsZoalroshd, Seyed 28 June 2016 (has links)
We show that the singular numbers of single layer potentials on smooth curves asymptotically behave like O(1/n). For the curves with singularities, as long as they contain a smooth sub-arc, the resulting single layer potentials are never trace-class. We provide upper bounds for the operator and the Hilbert-Schmidt norms of single layer potentials on smooth and chord-arc curves. Regarding the injectivity of single layer potentials on planar curves, we prove that among single layer potentials on dilations of a given curve, only one yields a non-injective single layer potential. A criterion for injectivity of single layer potentials on ellipses is given. We establish an isoperimetric inequality for Schatten p−norms of logarithmic potentials over quadrilaterals and its analogue for Newtonian potentials on parallelepipeds.
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Sturm-Liouville theoryTing, Lycretia Englang 01 January 1996 (has links)
No description available.
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Geometric structures of eigenfunctions with applications to inverse scattering theory, and nonlocal inverse problemsCao, Xinlin 04 June 2020 (has links)
Inverse problems are problems where causes for desired or an observed effect are to be determined. They lie at the heart of scientific inquiry and technological development, including radar/sonar, medical imaging, geophysical exploration, invisibility cloaking and remote sensing, to name just a few. In this thesis, we focus on the theoretical study and applications of some intriguing inverse problems. Precisely speaking, we are concerned with two typical kinds of problems in the field of wave scattering and nonlocal inverse problem, respectively. The first topic is on the geometric structures of eigenfunctions and their applications in wave scattering theory, in which the conductive transmission eigenfunctions and Laplacian eigenfunctions are considered. For the study on the intrinsic geometric structures of the conductive transmission eigenfunctions, we first present the vanishing properties of the eigenfunctions at corners both in R2 and R3, based on microlocal analysis with the help of a particular type of planar complex geometrical optics (CGO) solution. This significantly extends the previous study on the interior transmission eigenfunctions. Then, as a practical application of the obtained geometric results, we establish a unique recovery result for the inverse problem associated with the transverse electromagnetic scattering by a single far-field measurement in simultaneously determining a polygonal conductive obstacle and its surface conductive parameter. For the study on the geometric structures of Laplacian eigenfunctions, we separately discuss the two-dimensional case and the three-dimensional case. In R2, we introduce a new notion of generalized singular lines of Laplacian eigenfunctions, and carefully investigate these singular lines and the nodal lines. The studies reveal that the intersecting angle between two of those lines is closely related to the vanishing order of the eigenfunction at the intersecting point. We provide an accurate and comprehensive quantitative characterization of the relationship. In R3, we study the analytic behaviors of Laplacian eigenfunctions at places where nodal or generalized singular planes intersect, which is much more complicated. These theoretical findings are original and of significant interest in spectral theory. Moreover, they are applied directly to some physical problems of great importance, including the inverse obstacle scattering problem and the inverse diffraction grating problem. It is shown in a certain polygonal (polyhedral) setup that one can recover the support of the unknown scatterer as well as the surface impedance parameter by finitely many far-field patterns. Our second topic is concerning the fractional partial differential operators and some related nonlocal inverse problems. We present some prelimilary knowledge on fractional Sobolev Spaces and fractional partial differential operators first. Then we focus on the simultaneous recovery results of two interesting nonlocal inverse problems. One is simultaneously recovering potentials and the embedded obstacles for anisotropic fractional Schrödinger operators based on the strong uniqueness property and Runge approximation property. The other one is the nonlocal inverse problem associated with a fractional Helmholtz equation that arises from the study of viscoacoustics in geophysics and thermoviscous modelling of lossy media. We establish several general uniqueness results in simultaneously recovering both the medium parameter and the internal source by the corresponding exterior measurements. The main method utilized here is the low-frequency asymptotics combining with the variational argument. In sharp contrast, these unique determination results are unknown in the local case, which would be of significant importance in thermo- and photo-acoustic tomography.
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Vibrations of plates with massesSolov'ëv, Sergey I. 31 August 2006 (has links)
This paper presents the investigation of the
nonlinear eigenvalue problem describing free
vibrations of plates with elastically attached
masses. We study properties of eigenvalues and
eigenfunctions and prove the existence theorem.
Theoretical results are illustrated by numerical
experiments.
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Eigenfunctions in chaotic quantum systemsBäcker, Arnd 12 June 2008 (has links)
The structure of wavefunctions of quantum systems strongly depends on the underlying classical dynamics. In this text a selection of articles on eigenfunctions in systems with fully chaotic dynamics and systems with a mixed phase space is summarized. Of particular interest are statistical properties like amplitude distribution and spatial autocorrelation function and the implication of eigenfunction structures on transport properties. For systems with a mixed phase space the separation into regular and chaotic states does not always hold away from the semiclassical limit, such that chaotic states may completely penetrate into the region of the regular island. The consequences of this flooding are discussed and universal aspects highlighted.
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Evaluation of applying Crum-based transformation in solving two point boundary value problemsJogiat, Aasif January 2016 (has links)
A dissertation submitted to the Faculty of Engineering and the Built Environment, University of the
Witwatersrand, in ful llment of the requirements for the degree of Master of Science in Engineering, Johannesburg, 2016 / The aim of this research project is evaluating the application of the Crum-based transformation
in solving engineering systems modelled as two-point boundary value problems. The boundary
value problems were subjected to the various combinations of Dirichlet, Non-Dirichlet and Affine
boundary conditions. The engineering systems that were modelled were in the elds of electrostatics,
heat conduction and longitudinal vibrations. Other methods such as the Z-transforms and iterative
methods have been discussed. An attractive property of the Crum-based transformation is that
it can be applied to cases where the eigenparameters (function of eigenvalues) generated in the
discrete case are negative and was therefore chosen to be explored further in this dissertation. An
alternative matrix method was proposed and used instead of the algebraic method in the Crum-
based transformation. The matrix method was tested against the algebraic method using three unit
intervals. The analysis revealed, that as the number of unit intervals increase, there is a general
increase in the accuracy of the approximated continuous-case eigenvalues generated for the discrete
case. The other observed general trend was that the accuracy of the approximated continuous-
case eigenvalues decrease as one ascends the continuous-case eigenvalue spectrum. Three cases:
(Affine, Dirichlet), (Affine, Non-Dirichlet) and (Affine, Affine) generated negative eigenparameters.
The approximated continuous-case eigenvalues, derived from the negative eigenparameters, were
shown not to represent true physical natural frequencies since the discrete eigenvalues, derived from
negative eigenparameters, do not satisfy the condition for purely oscillatory behaviour. The research
has also shown that the Crum-based transformation method was useful in approximating the shifted
eigenvalues of the continuous case, in cases where the generated eigenparameters were negative:
since, as the number of unit intervals increase, the post-transformed approximated eigenvalues
improved in accuracy. The accuracy was also found to be better in the post-transformed case than
in the pre-transformed case. Furthermore, the approximated non-shifted and shifted continuous-
case eigenvalues (except the approximated continuous-case eigenvalues generated from negative
eigenparameters) satis ed the condition for purely oscillatory behaviour. / MT2017
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Dynamic analysis model of a class E2 converter for low power wireless charging linksBati, A., Luk, P.C.K., Aldhaher, S., See, C.H., Abd-Alhameed, Raed, Excell, Peter S. 07 January 2019 (has links)
Yes / A dynamic response analysis model of a Class E2 converter for wireless power transfer applications is presented. The converter operates at 200 kHz and consists of an induction link with its primary coil driven by a class E inverter and the secondary coil with a voltage-driven class E synchronous rectifier. A seventh-order linear time invariant state-space model is used to obtain the eigenvalues of the system for the four modes resulting from the operation of the converter switches. A participation factor for the four modes is used to find the actual operating point dominant poles for the system response. A dynamic analysis is carried out to investigate the effect of changing the separation distance between the two coils, based on converter performance and the changes required of some circuit parameters to achieve optimum efficiency and stability. The results show good performance in terms of efficiency (90–98%) and maintenance of constant output voltage with dynamic change of capacitance in the inverter. An experiment with coils of the dimension of 53 × 43 × 6 mm3 operating at a resonance frequency of 200 kHz, was created to verify the proposed mathematical model and both were found to be in excellent agreement.
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Laminar flow with an axially varying heat transfer coefficientWells, Robert G. January 1986 (has links)
A theoretical study of convective heat transfer is presented for a laminar flow subjected to an axial variation in the external heat transfer coefficient (or dimensionless Biot number). Since conventional techniques fail for a variable boundary condition parameter, a variable eigenfunction approach is developed. An analysis is carried out for a periodic heat transfer coefficient, which serves as a model for heat transfer from a duct fitted with an array of evenly spaced fins. Three solution methods for the variable eigenfunction technique are examined: an Nth order approximation method, an iterative method and a stepwise periodic method. The stepwise periodic method provides the most convenient and accurate solution for a stepwise periodic Biot number. Graphical results match exactly to ones obtained by Charmchi and Sparrow from a finite-difference scheme. A connected region technique is also developed to provide limited exact results to test the validity of the three solution methods.
The study of a finned duct by a stepwise periodic Biot number is carried out via a parametric study, an average (constant) Biot number approximation and an assumed velocity profile analysis. Results for the parametric study show that external finning yields substantial heat transfer enhancement over an unfinned duct, especially when the Biot number of the unfinned regions is low. A decrease in the interfin spacing causes increased enhancement. Variations of the period of the Biot number causes relatively small changes in enhancement as long as the ratio of finned to unfinned surface remains unchanged. An average (constant) Biot number approximation for a specified finned tube is compared to the stepwise periodic Biot number solution. The results show that the constant Biot number approximation provides accurate results. Finally, the results for the influence of the assumed velocity profile demonstrate that a constant velocity flow provides increased heat transfer and more effective enhancement by external finning than a laminar fully developed flow, especially at high Biot numbers.
This study provides insight into heat transfer enhancement due to finning and also develops a solution methodology for problems involving variable boundary condition parameters. / M.S.
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On the Cauchy problem for the linearized GPKdV and gauge transformations for a quadratic pencil and AKNS systemYordanov, Russi Georgiev 06 June 2008 (has links)
The present work in the area of soliton theory studies two problems which arise when seeking analytic solutions to certain nonlinear partial differential equations.
In the first one, Lax pairs associated with prolonged eigenfunctions and prolonged squared eigenfunctions (prolonged squares) are derived for a Schrödinger equation with a potential depending polynomially on the spectral parameter (of degree N) and its respective hierarchy of nonlinear evolution equations (here named generalized polynomial Korteweg-de Vries equations or GPKdV).
It is shown that the prolonged squares satisfy the linearized GPKdV equations. On that basis, the Cauchy problem for the linearized GPKdV has been solved by finding a complete set of such prolonged squares and applying an expansion formula derived in another work by the author.
The results are a generalization of the ones by Sachs (SIAM J. Math. Anal. 14, 1983, 674-683).
Moreover, a condition on the so-called recursion operator A is derived which generates the whole hierarchy of Lax pairs associated with the prolonged squares.
As for the second part of the work, it developed a scheme for deriving gauge transformations between different linear spectral problems. Then the scheme is applied to obtain all known Darboux transformations for a quadratic pencil (the spectral problem considered in the first part at N = 2), Schrödinger equation (N = 1), Ablowitz-Kaup-Newell-Segur (AKNS) system and also derive the Jaulent-Miodek transformation. Moreover, the scheme yields a large family of new transformations of the above types. It also gives some insight on the structure of the transformations and emphasizes the symmetry with respect to inversion that they possess. / Ph. D.
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The Generalized Operator Based Prony MethodStampfer, Kilian 17 January 2019 (has links)
No description available.
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