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Analytic and Numerical aspects of isospectral flows

dc.creatorKaur, Amandeep
dc.date.accessioned2018-11-24T23:21:06Z
dc.date.available2018-01-16T10:00:13Z
dc.date.available2018-11-24T23:21:06Z
dc.date.issued2018-01-15
dc.identifierhttps://www.repository.cam.ac.uk/handle/1810/270631
dc.identifier.urihttp://repository.aust.edu.ng/xmlui/handle/123456789/3696
dc.description.abstractIn this thesis we address the analytic and numerical aspects of isospectral flows. Such flows occur in mathematical physics and numerical linear algebra. Their main structural feature is to retain the eigenvalues in the solution space. We explore the solution of Isospectral flows and their stochastic counterpart using explicit generalisation of Magnus expansion. \par In the first part of the thesis we expand the solution of Bloch--Iserles equations, the matrix ordinary differential system of the form $ X'=[N,X^{2}],\ \ t\geq0, \ \ X(0)=X_0\in \textrm{Sym}(n),\ N\in \mathfrak{so}(n), $ where $\textrm{Sym}(n)$ denotes the space of real $n\times n$ symmetric matrices and $\mathfrak{so}(n)$ denotes the Lie algebra of real $n\times n$ skew-symmetric matrices. This system is endowed with Poisson structure and is integrable. Various important properties of the flow are discussed. The flow is solved using explicit Magnus expansion and the terms of expansion are represented as binary rooted trees deducing an explicit formalism to construct the trees recursively. Unlike classical numerical methods, e.g.\ Runge--Kutta and multistep methods, Magnus expansion respects the isospectrality of the system, and the shorthand of binary rooted trees reduces the computational cost of the exponentially growing terms. The desired structure of the solution (also with large time steps) has been displayed. \par Having seen the promising results in the first part of the thesis, the technique has been extended to the generalised double bracket flow $ X^{'}=[[N,X]+M,X], \ \ t\geq0, \ \ X(0)=X_0\in \textrm{Sym}(n),$ where $N\in \textrm{diag}(n)$ and $M\in \mathfrak{so}(n)$, which is also a form of an Isospectral flow. In the second part of the thesis we define the generalised double bracket flow and discuss its dynamics. It is noted that $N=0$ reduces it to an integrable flow, while for $M=0$ it results in a gradient flow. We analyse the flow for various non-zero values of $N$ and $M$ by assigning different weights and observe Hopf bifurcation in the system. The discretisation is done using Magnus series and the expansion terms have been portrayed using binary rooted trees. Although this matrix system appears more complex and leads to the tri-colour leaves; it has been possible to formulate the explicit recursive rule. The desired structure of the solution is obtained that leaves the eigenvalues invariant in the solution space.
dc.languageen
dc.publisherUniversity of Cambridge
dc.publisherDepartment of Applied Mathematics and Theoretical Physics (DAMTP)
dc.publisherWolfson College
dc.subjectIsospectral flow
dc.subjectordinary differential equations
dc.subjecteigenvalues
dc.subjectMagnus expansion
dc.subjectLie group
dc.subjectLie algebra
dc.subjectbinary trees
dc.subjectCayley transform
dc.subjectdouble bracket flow
dc.subjectToda lattice
dc.subjectQR algorithm
dc.titleAnalytic and Numerical aspects of isospectral flows
dc.typeThesis


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