Spelling suggestions: "subject:"harmonic oscillator"" "subject:"armonic oscillator""
11 |
On some physical aspects of the group properties of point transformations of harmonic oscillatorsContreras, Carmen Rosa 01 January 1991 (has links)
The purpose of our work is to study the physical aspects of the application of the Lie group analysis to simple harmonic oscillators and related systems which can or cannot be canonical ones. The mathematical part of the problem has been studied by many authors. Quite recently L. Hubbard, C.Wulfman and H. Rabitz and C. Wulfman and H.Rabitz have developed a method for a group theoretical analysis applicable to a more general class of linear systems of Ordinary Differential Equations (ODE).
|
12 |
On the Determination of Spectral Properties of Certain Families of OperatorsBaker, Charles Edmond January 2015 (has links)
No description available.
|
13 |
Synchronization Of Linearly And Nonlinearly Coupled Harmonic OscillatorsPenbegul, Ali Yetkin 01 May 2011 (has links) (PDF)
In this thesis, the synchronization in the arrays of identical and non-identical coupled harmonic oscillators is studied. Both linear and nonlinear coupling is considered. The study consists of two main parts. The first part concentrates on theoretical analysis and the second part contains the simulation results.
The first part begins with introducing the harmonic oscillators and the basics of synchronization. Then some theoretical aspects of synchronization of linearly and nonlinearly coupled harmonic oscillators are presented. The theoretical results say that linearly coupled identical harmonic oscillators synchronize for any frequency of oscillation. For nonlinearly coupled identical harmonic oscillators, synchronization is shown to occur at large enough frequency values.
In the second part, the simulator and simulation results are presented. A GUI is designed in MATLAB to run the simulations. In the simulations, synchronization of coupled harmonic oscillators are studied according to different coupling strength values, different frequency values, different coupling graph types (e.g. all-to-all, ring, tree) and different coupling function types (e.g. linear, saturation, cubic). The simulation results do not only support the theoretical part of the thesis but also give some idea about the part of the synchronization of coupled harmonic oscillators uncovered by theory.
|
14 |
Fabrication and characterization of a double torsional mechanical oscillator and its applications in gold micromass measurementsLu, Wei, 1975- 05 October 2012 (has links)
We report the design and fabrication of a micro-mechanical oscillator for use in extremely small force detection experiments such as transverse force measurements of a moving vortex and Nuclear Magnetic Resonance Force Microscopy (NMRFM). We study the basic physics of the double torsional mechanical oscillator, and pursue double torsional oscillators with small spring constants, high resonance frequencies, and high quality factors. Using a series of semiconductor manufacturing techniques, especially using the electron-beam lithography technique, we successfully micro-fabricate double torsional mechanical oscillators from silicon-on-insulator wafers. We conduct characterization experiments to extract important parameters of a mechanical oscillator, including the resonance frequencies, spring constants, and quality factors. We focus on the four typical resonance modes of these oscillators, and then compare the force detection sensitivity of each mode. Eventually we apply these force sensitive oscillators to gold micro-mass measurements, and achieve very small mass detection. In the future we are going to continue to micro-fabricate thinner oscillators to reduce the spring constants, and improve the quality factors by designing more suitable geometric shapes and by pursuing annealing studies. Thus, we might be able to achieve single nuclear spin measurements using NMRFM. / text
|
15 |
Coherence and decoherence processes of a harmonic oscillator coupled with finite temperature field: exact eigenbasis solution of Kossakowski-Linblad's equationTay, Buang Ann 28 August 2008 (has links)
Not available / text
|
16 |
Coherence and decoherence processes of a harmonic oscillator coupled with finite temperature field exact eigenbasis solution of Kossakowski-Linblad's equation /Tay, Buang Ann, Petrosky, Tomio Y., Sudarshan, E. C. G. January 2004 (has links) (PDF)
Thesis (Ph. D.)--University of Texas at Austin, 2004. / Supervisors: Tomio Petrosky and E.C.G. Sudarshan. Vita. Includes bibliographical references.
|
17 |
Osciladores log-periódicos e tipo Caldirola-Kanai / Log-periodic and Kanai-Caldirola oscillatorsBessa, Vagner Henrique Loiola January 2012 (has links)
BESSA, Vagner Henrique Loiola. Osciladores log-periódicos e tipo Caldirola-Kanai. 2012. 66 f. Dissertação (Mestrado em Física) - Programa de Pós-Graduação em Física, Departamento de Física, Centro de Ciências, Universidade Federal do Ceará, Fortaleza, 2012. / Submitted by Edvander Pires (edvanderpires@gmail.com) on 2015-10-19T18:23:14Z
No. of bitstreams: 1
2012_dis_vhlbessa.pdf: 26350485 bytes, checksum: 4eb844c05187fb66d3b274a9f8d1b0ed (MD5) / Approved for entry into archive by Edvander Pires(edvanderpires@gmail.com) on 2015-10-20T20:53:49Z (GMT) No. of bitstreams: 1
2012_dis_vhlbessa.pdf: 26350485 bytes, checksum: 4eb844c05187fb66d3b274a9f8d1b0ed (MD5) / Made available in DSpace on 2015-10-20T20:53:49Z (GMT). No. of bitstreams: 1
2012_dis_vhlbessa.pdf: 26350485 bytes, checksum: 4eb844c05187fb66d3b274a9f8d1b0ed (MD5)
Previous issue date: 2012 / In this work we present the classical and quantum solutions of two classes of time-dependent harmonic oscillators, namely: (a) the log-periodic and (b) the Caldirola-Kanai-type oscillators. For class (a) we study the following oscillators: (I) $m(t)=m_0frac{t}{t_0}$, (II) $m(t)=m_0$ and (III) $m(t)=m_0ajust{frac{t}{t_0}}^2$. In all three cases $omega(t)=omega_0frac{t_0}{t}$. For class (b) we study the Caldirola-Kanai oscillator (IV)where $omega(t)=omega_0$ and $m(t)=m_0 ext{exp}ajust{gamma t}$ and the oscillator with $omega(t)=omega_0$ and $m(t)=m_0ajust{1+frac{t}{t_0}}^alpha$, for $alpha=2$ (V) and $alpha=4$ (VI). To obtain the classical solution for each oscillator we solve the respective equation of motion and analyze the behavior of $q(t)$, $p(t)$ as well as the phase diagram $q(t)$ vs $p(t)$. To obtain the quantum solutions we use a unitary transformation and the Lewis and Riesenfeld quantum invariant method. The wave functions obtained are written in terms of a function ($ ho$) which is solution of the Milne-Pinney equation. Futhermore, for each system we solve the respective Milne-Pinney equation and discuss how the uncertainty product evolves with time. / Nesse trabalho apresentamos as soluções clássicas e quânticas de duas classes de osciladores harmônicos dependentes de tempo, a saber: (a) o oscilador log-periódico e (b) o oscilador tipo Caldirola-Kanai. Para a classe (a) estudamos os seguintes osciladores: (I) $m(t)=m_0frac{t}{t_0}$, (II) $m(t)=m_0$ e (III) $m(t)=m_0ajust{frac{t}{t_0}}^2$. Nesses três casos $omega(t)=omega_0frac{t_0}{t}$. Para a classe (b) estudamos o oscilador (IV) de Caldirola-Kanai onde $omega(t)=omega_0$ e $m(t)=m_0 ext{Exp}ajust{gamma t}$ e osciladores com $omega(t)=omega_0$ e $m(t)=m_0ajust{1+frac{t}{t_0}}^alpha$, para (V) $alpha=2$ e (VI) $alpha=4$. Para obter as soluções clássicas de cada oscilador resolvemos suas respectivas equações de movimento e analisamos o comportamento de $q(t)$, $p(t)$ assim como do diagrama de fase $q(t)$ vs $p(t)$. Para obter as soluções quânticas usamos uma transformação unitária e o método dos invariantes quânticos de Lewis e Riesenfeld. A função de onda obtida é escrita em termos de uma função $ ho$, que é solução da equação de Milne-Pinney. Ainda, para cada sistema resolvemos a respectiva equação de Milne-Pinney e discutimos como o produto da incerteza evolui no tempo.
|
18 |
Relaxation in harmonic oscillator systems and wave propagation in negative index materialsChimonidou, Antonia 02 June 2010 (has links)
This dissertation is divided up into two parts, each examining a distinct
theme. The rst part of our work concerns itself with open quantum systems and
the relaxation phenomena arising from the repeated application of an interaction
Hamiltonian on systems composed of quantum harmonic oscillators. For the second
part of our work, we shift gears and investigate the wave propagation in left-handed
media, or materials with simultaneously negative electric permeability and magnetic
permeability . Each of these two parts is complete within its own context.
In the rst part of this dissertation, we introduce a relaxation-generating
model which we use to study the process by which quantum correlations are created when an interaction Hamiltonian is repeatedly applied to bipartite harmonic oscillator
systems for some characteristic time interval . The two important time scales
which enter our results are discussed in detail. We show that the relaxation time
obtained by the application of this repeated interaction scheme is proportional to
both the strength of interaction and to the characteristic time interval . Through
discussing the implications of our model, we show that, for the case where the oscillator
frequencies are equal, the initial Maxwell-Boltzmann distributions of the
uncoupled parts evolve to a new Maxwell-Boltzmann distribution through a series
of transient Maxwell-Boltzmann distributions, or quasi-stationary, non-equilibrium
states. We further analyze the case in which the two oscillator frequencies are unequal
and show how the application of the same model leads to a non-thermal steady
state. The calculations are exact and the results are obtained through an iterative
process, without using perturbation theory.
In the second part of this dissertation, we examine the response of a plane
wave incident on a
at surface of a left-handed material, a medium characterized
by simultaneously negative electric permittivity and magnetic permeability . We
do this by solving Maxwell's equations explicitly. In the literature up to date,
it has been assumed that negative refractive materials are necessarily frequency
dispersive. We propose an alternative to this assumption by suggesting that the
requirement of positive energy density can be relaxed, and discuss the implications
of such a proposal. More speci cally, we show that once negative energy solutions
are accepted, the requirement for frequency dispersion is no longer needed. We
further argue that, for the purposes of discussing left-handed materials, the use of
group velocity as the physically signi cant quantity is misleading, and suggest that
any discussion involving it should be carefully reconsidered. / text
|
19 |
Finite Quantum Theory of the Harmonic OscillatorShiri-Garakani, Mohsen 12 July 2004 (has links)
We apply the Segal process of group simplification to the linear harmonic oscillator. The result is a
finite quantum theory with three quantum constants instead of the usual one. We compare the classical (CLHO), quantum (QLHO), and finite (FLHO) linear harmonic oscillators and their canonical or unitary groups. The FLHO is isomorphic to a
dipole rotator with N=l(l+1) states where l is very large for physically interesting case. The position and momentum variables are quantized with uniform finite spectra. For fixed quantum constants and large N there are three broad classes of FLHO: soft, medium, and hard corresponding respectively to cases where ratio of the of potential energy to kinetic energy in the Hamiltonian is very small, almost equal to one, or very large
The field oscillators responsible for infra-red and
ultraviolet divergences are soft and hard respectively. Medium oscillators approximate the QLHO. Their
low-lying states have nearly the same zero-point
energy and level spacing as the QLHO, and nearly obeying the Heisenberg uncertainty principle and the equipartition principle. The corresponding rotators are nearly polarized along the z-axis.
The soft and hard FLHO's have infinitesimal
0-point energy and grossly violate equipartition and the Heisenberg uncertainty principle. They do not resemble the QLHO at all. Their low-lying energy states correspond to rotators polaroizd along x-axis or y-axis respectively. Soft oscillators have
frozen momentum, because their maximum potential energy is too small to produce one quantum of momentum. Hard oscillators have frozen position, because their maximum kinetic energy is too small to produce one quantum of momentum. Hard oscillators have frozen position, because their maximum kinetic energy is too small to excite one quantum of position.
|
20 |
The Bose/Fermi oscillators in a new supersymmetric representationIhl, Matthias, 1977- 25 October 2011 (has links)
This work deals with the application of supermathematics to supersymmetrical problems arising in physics. Some recent developments are presented in detail. A reduction scheme for general supermanifolds to vector bundles is presented, which significantly simplifies their mathematical treatment in a physical context. Moreover, some applications of this new approach are worked out, such as the Fermi oscillator. / text
|
Page generated in 0.0668 seconds