Optimal system of subalgebras and invariant solutions for a nonlinear wave equation

Talib, Ahmed Abedelhussain

January 2009

This thesis is devoted to use Lie group analysis to obtain all invariant solutions by constructing optimal system of one-dimensional subalgebras of the Lie algebra L5 for a nonlinear wave equation. I will show how the given symmetries ( Eq.2) are admitted by using partial differential equation (Eq.1), In addition to obtain the commutator table by using the same given symmetries. Subsequently, I calculate the transformations of the generators with the Lie algebra L5, which provide the 5-parameter group of linear transformations for the operators. Finally, I construct the invariant solutions for each member of the optimal system.

Non-linear wave equation

Admitted

Symmetries

Commutator table

Lie equations

Generators

Optimal system

Invariants.

Klein-Gordon models with non-effective time-dependent potential

Nascimento, Wanderley Nunes do

19 February 2016

Submitted by Livia Mello (liviacmello@yahoo.com.br) on 2016-09-23T20:38:51Z No. of bitstreams: 1 TeseWNN.pdf: 1247691 bytes, checksum: 63f743255181169a9bb4ca1dfd2312c2 (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-09-26T20:35:27Z (GMT) No. of bitstreams: 1 TeseWNN.pdf: 1247691 bytes, checksum: 63f743255181169a9bb4ca1dfd2312c2 (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-09-26T20:35:33Z (GMT) No. of bitstreams: 1 TeseWNN.pdf: 1247691 bytes, checksum: 63f743255181169a9bb4ca1dfd2312c2 (MD5) / Made available in DSpace on 2016-09-26T20:35:40Z (GMT). No. of bitstreams: 1 TeseWNN.pdf: 1247691 bytes, checksum: 63f743255181169a9bb4ca1dfd2312c2 (MD5) Previous issue date: 2016-02-19 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / In this thesis we study the asymptotic properties for the solution of the Cauchy problem for the Klein-Gordon equation with non-effective time-dependent potential. The main goal was define a suitable energy related to the Cauchy problem and derive decay estimates for such energy. Strichartz’ estimates and results of scattering and modified scattering was established. The C m theory and the stabilization condition was applied to treat the case where the coefficient of the potential term has very fast oscillations. Moreover, we consider a semi-linear wave model scale-invariant time- dependent with mass and dissipation, in this step we used linear estimates related with the semi-linear model to prove global existence (in time) of energy solutions for small data and we show a blow-up result for a suitable choice of the coefficients. / Nesta tese estudamos as propriedades assintóticas para a solução do problema de Cauchy para a equação de Klein-Gordon com potencial não efetivo dependente do tempo. O principal objetivo foi definir uma energia adequada relacionada ao problema de Cauchy e derivar estimativas para tal energia. Estimativas de Strichartz e resultados de scatering e scatering modificados também foram estabelecidos. A teoria C m e a condição de estabilização foram aplicados para tratar o caso em que o coeficiente da massa oscila muito rápido. Além disso, consideramos um mod- elo de onda semi-linear scale-invariante com massa e dissipação dependentes do tempo, nesta etapa usamos as estimativas lineares de tal modelo para provar ex- istência global (no tempo) de solução de energia para dados iniciais suficientemente pequenos e demonstramos um resultado de blow-up para uma escolha adequada dos coeficientes.

Klein-Gordon time-dependent equation

WKB Analysis

Strichartz estimates

Semi-linear wave equation

Power non-linearity

CIENCIAS EXATAS E DA TERRA::MATEMATICA

Etude d'une équation non linéaire, non dispersive et complètement integrable et de ses perturbations / Study of a nonlinear, non-dispersive, completely integrable equation and its perturbations

Pocovnicu, Oana

29 September 2011

On étudie dans cette thèse l'équation de Szegö sur la droite réelle ainsi que ses perturbations. Cette équation a été introduite il y a quelques années par Gérard et Grellier comme modèle mathématique d'une équation non linéaire totalement non dispersive.L'équation de Szegöapparait naturellement dans l'étude de l'équation de Schrödinger non linéaire (NLS) danscertaines situations sur-critiques où l'on constate un manque de dispersion, par exemplelorsque l'on considère NLS sur le groupe de Heisenberg. Par conséquent, une des motivationsde cette thèse est d'établir des résultats concernant l'équation de Szegö qui pourrontéventuellement être utilisés dans le contexte de l'équation de Schrödinger non linéaire.Le premier résultat de cette thèse est la classification des solitons de l'équation de Szegö.On montre que ce sont tous des fonctions rationnelles ayant un unique pôle qui est simple.De plus, on prouve que les solitons sont orbitalement stables.La propriété la plus remarquable de l'équation de Szegö est le fait qu'elle est complètement intégrable, ce qui permet notamment d'établir une formule explicite de sa solution.Comme applications de cette formule, on obtient les trois résultats suivants. (A) On montreque les solutions fonctions rationnelles génériques se décomposent en une somme de solitonset d'un reste qui est petit lorsque le temps tend vers l'infini. (B) On met en évidence unexemple de solution non générique dont les grandes normes de Sobolev tendent vers l'infiniavec le temps. (C) On détermine des coordonnées action-angle généralisées lorsque l'on restreintl'équation de Szegö à une sous-variété de dimension finie. En particulier, on en déduitqu'une grande partie des trajectoires de cette équation sont des spirales autour de cylindrestoroïdaux.Comme l'équation de Szegö est complètement intégrable, il est ensuite naturel d'étudierses perturbations et d'établir de nouvelles propriétés pour celles-ci à partir des résultatsconnus pour l'équation de Szegö. Une des perturbations de l'équation de Szegö est une équation desondes non linéaire (NLW) de donnée bien préparée.On prouve que si la donnée initiale de NLW est petite et à support dans l'ensemble desfréquences positives, la solution de NLW est alors approximée pour un temps long par lasolution de l'équation de Szegö. Autrement dit, on démontre ainsi que l'équation de Szegöest la première approximation de NLW. On construit ensuite une solution de NLW dont lesgrandes normes de Sobolev augmentent (relativement à la norme de la donnée initiale).Sur le tore T, Gérard et Grellier ont démontré un résultat analogue d'approximation deNLW. On améliore ce résultat en trouvant une approximation plus fine, de deuxième ordre.Dans une dernière partie, on s'intéresse à l'équation de Szegö perturbée par un potentielmultiplicatif petit. On étudie l'interaction de ce potentiel avec les solitons. Plus précisément,on montre que, si la donnée initiale est celle d'un soliton pour l'équation non perturbée, lasolution de l'équation perturbée garde la forme d'un soliton sur un long temps. De plus, ondéduit la dynamique effective, i.e. les équations différentielles satisfaites par les paramètresdu soliton. / In this Ph.D. thesis, we study the Szegö equation on the real lineas well as its perturbations.It was recently introduced by Gérard and Grellier as a toy model of a non-lineartotally non dispersive equation. The Szegö equation appears naturally in the study of thenon-linear Schrödinger equation (NLS) in super-critical situations where dispersion lacks,for example, when one considers NLS on the Heisenberg group. Consequently, one of themotivations of this Ph.D. thesis is fi nding new results for the Szegö equation in hope thatthey could be eventually used in the context of the non-linear Schrödinger equation.Our first result is a classification of the solitons of the Szegö equation. We show thatthey are all rational functions with one simple pole. In addition, we prove the orbitalstability of solitons.The Szegö equation has the remarkable property of being completely integrable. Thisallows us to find an explicit formula for solutions. We obtain three applications of thisformula. (A) We prove soliton resolution for solutions which are generic rational functions.(B) We construct an example of non-generic solution whose high Sobolev norms grow toinfinity over time. (C) We find generalized action-angle variables when restricting the Szegöequation to a finite dimensional sub-manifold. In particular, this yields that most of thetrajectories of the Szegö equation are spirals around toroidal cylinders.Since the Szegö equation is completely integrable, it is natural to study its perturbationsand deduce new properties of such perturbations from the known results for the Szegöequation. One perturbation of the Szegö equation is a non-linear wave equation(NLW) with small initial data.We prove that the Szegö equation is the first order approximation of NLW. More precisely,if an initial condition of NLW is small and supported only on non-negative frequencies, thenthe corresponding solution can be approximated by the solution of the Szegö equation, fora long time. We then construct a solution of NLW whose high Sobolev norms grow.On the torus T, Gérard and Grellier proved an analogous first order approximationresult for NLW. By considerning the second order approximation, we obtain an improvedresult with a smaller error.Lastly, we consider the Szegö equation perturbed by a small multiplicative potential.We study the interaction of this potential with solitons. More precisely, we show that, if theinitial condition is that of a soliton for the unperturbed Szegö equation, then the solutionpreserves the shape of a soliton for a long time. In addition, we prescribe the effectivedynamics, i.e. we derive the differential equations satisfied by the parameters of the soliton.

Équation de Szegö

Paire de Lax

Opérateur de Hankel

Soliton

Coordonnées action-angle

Équation des ondes non linéaire

Méthode du groupe de renormalisation

Szegö equation

Lax pair

Hankel operators

Soliton resolution

Action-angle coordinates

Non-linear wave equation

Renormalisation group method

Semi-linear waves with time-dependent speed and dissipation

Bui, Tang Bao Ngoc

11 June 2014

The main goal of our thesis is to understand qualitative properties of solutions to the Cauchy problem for the semi-linear wave model with time-dependent speed and dissipation. We greatly benefited from very precise estimates for the corresponding linear problem in order to obtain the global existence (in time) of small data solutions. This reason motivated us to introduce very carefully a complete description for classification of our models: scattering, non-effective, effective, over-damping. We have considered those separately.

info:eu-repo/classification/ddc/510

ddc:510

info:eu-repo/classification/ddc/515

ddc:515

info:eu-repo/classification/ddc/532

ddc:532

info:eu-repo/classification/ddc/534

ddc:534