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1	Topics in the spectral theory of non adjoint operators Boulton, Lyonell January 2001 (has links) No description available. 510 Hilbert spaces
2	White noise analysis and stochastic evolution equations Sorensen, Julian Karl. January 2001 (has links) (PDF) Bibliography: leaves 127-128. Stochastic analysis Hilbert spaces
3	White noise analysis and stochastic evolution equations / Julian Sorensen. Sorensen, Julian Karl January 2001 (has links) Bibliography: leaves 127-128. / xiv, 128 leaves ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Pure Mathematics, 2001 Stochastic analysis Hilbert spaces
4	White noise analysis and stochastic evolution equations / Sorensen, Julian Karl. January 2001 (has links) (PDF) Thesis (Ph.D.)-- University of Adelaide, Dept. of Pure Mathematics, 2001. / Bibliography: leaves 127-128. Stochastic analysis. Hilbert spaces.
5	Subspace methods and informative experiments for system identification Chui, Nelson Loong Chik January 1997 (has links) No description available. 510 Hilbert spaces; Markov parameters
6	Kleinian Groups in Hilbert Spaces Das, Tushar 08 1900 (has links) The theory of discrete groups acting on finite dimensional Euclidean open balls by hyperbolic isometries was borne around the end of 19th century within the works of Fuchs, Klein and Poincaré. We develop the theory of discrete groups acting by hyperbolic isometries on the open unit ball of an infinite dimensional separable Hilbert space. We present our investigations on the geometry of limit sets at the sphere at infinity with an attempt to highlight the differences between the finite and infinite dimensional theories. We discuss the existence of fixed points of isometries and the classification of isometries. Various notions of discreteness that were equivalent in finite dimensions, no longer turn out to be in our setting. In this regard, the robust notion of strong discreteness is introduced and we study limit sets for properly discontinuous actions. We go on to prove a generalization of the Bishop-Jones formula for strongly discrete groups, equating the Hausdorff dimension of the radial limit set with the Poincaré exponent of the group. We end with a short discussion on conformal measures and their relation with Hausdorff and packing measures on the limit set. Kleinian group Hilbert spaces dynamical systems
7	Galois quantum systems, irreducible polynomials and Riemann surfaces Vourdas, Apostolos 08 June 2009 (has links) No / Finite quantum systems in which the position and momentum take values in the Galois field GF(p), are studied. Ideas from the subject of field extension are transferred in the context of quantum mechanics. The Frobenius automorphisms in Galois fields lead naturally to the "Frobenius formalism" in a quantum context. The Hilbert space splits into "Frobenius subspaces" which are labeled with the irreducible polynomials associated with the yp¿y. The Frobenius maps transform unitarily the states of a Galois quantum system and leave fixed all states in some of its Galois subsystems (where the position and momentum take values in subfields of GF(p)). An analytic representation of these systems in the -sheeted complex plane shows deeper links between Galois theory and Riemann surfaces. ©2006 American Institute of Physics Quantum theory Hilbert spaces Polynomials Galois fields
8	Symmetry Representations in the Rigged Hilbert Space Formulation of Sujeewa Wickramasekara, sujeewa@physics.utexas.edu 14 February 2001 (has links) No description available.
9	On the Representations of Lie Groups and Lie Algebras in Rigged Hilbert Sujeewa Wickramasekara, sujeewa@physics.utexas.edu 14 February 2001 (has links) No description available.
10	Fast methods for identifying high dimensional systems using observations Plumlee, Matthew 08 June 2015 (has links) This thesis proposes new analysis tools for simulation models in the presence of data. To achieve a representation close to reality, simulation models are typically endowed with a set of inputs, termed parameters, that represent several controllable, stochastic or unknown components of the system. Because these models often utilize computationally expensive procedures, even modern supercomputers require a nontrivial amount of time, money, and energy to run for complex systems. Existing statistical frameworks avoid repeated evaluations of deterministic models through an emulator, constructed by conducting an experiment on the code. In high dimensional scenarios, the traditional framework for emulator-based analysis can fail due to the computational burden of inference. This thesis proposes a new class of experiments where inference from half a million observations is possible in seconds versus the days required for the traditional technique. In a case study presented in this thesis, the parameter of interest is a function as opposed to a scalar or a set of scalars, meaning the problem exists in the high dimensional regime. This work develops a new modeling strategy to nonparametrically study the functional parameter using Bayesian inference. Stochastic simulations are also investigated in the thesis. I describe the development of emulators through a framework termed quantile kriging, which allows for non-parametric representations of the stochastic behavior of the output whereas previous work has focused on normally distributed outputs. Furthermore, this work studied asymptotic properties of this methodology that yielded practical insights. Under certain regulatory conditions, there is the following result: By using an experiment that has the appropriate ratio of replications to sets of different inputs, we can achieve an optimal rate of convergence. Additionally, this method provided the basic tool for the study of defect patterns and a case study is explored. Model calibration Computer experiments Reproducing kernel Hilbert spaces Gaussian process

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