Fourier multipliers and stability of semigroups
Abstract
This is part of a meeting of the North British Functional Analysis Seminar
In this talk I will present some new $L_p$-$L_q$-Fourier multiplier theorems which hold for operator-valued symbols under geometric restrictions on the underlying Banach spaces such as (Fourier) (co)type. I will show how the multiplier theorems can be applied to obtain new stability results for semigroups arising in evolution equations. This is based on joint work with Jan Rozendaal (ANU, Canberra).
Square functions and random sums and their role in the analysis of Banach spaces
Abstract
This is part of a meeting of the North British Functional Analysis Seminar.
In this talk I will present an overview on generalized square functions in Banach spaces and some of their recent uses in “Analysis in Banach Spaces”. I will introduce the notions of $R$-boundedness and $\gamma$-radonifying operators and discuss their origins and some of their applications to harmonic analysis, functional calculus, control theory, and stochastic analysis.
A randomluy forced Burgers equation on the real line
Abstract
In this talk I will consider the Burgers equation with a homogeneous Possion process as a forcing potential. In recent years, the randomly forced Burgers equation, with forcing that is ergodic in time, received a lot of attention, especially the almost sure existence of unique global solutions with given average velocity, that at each time only depend on the history up to that time. However, in all these results compactness in the space dimension of the forcing was essential. It was even conjectured that in the non-compact setting such unique global solutions would not exist. However, we have managed to use techniques developed for first and last passage percolation models to prove that in the case of Poisson forcing, these global solutions do exist almost surely, due to the existence of semi-infinite minimizers of the Lagrangian action. In this talk I will discuss this result and explain some of the techniques we have used.
This is joined work Yuri Bakhtin and Konstantin Khanin.
Pathwise Holder convergence of the implicit Euler scheme for semi-linear SPDEs with multiplicative noise
Abstract
Pathwise Holder convergence with optimal rates is proved for the implicit Euler scheme associated with semilinear stochastic evolution equations with multiplicative noise. The results are applied to a class of second order parabolic SPDEs driven by space-time white noise. This is joint work with Sonja Cox.
The stochastic Weiss conjecture
Abstract
The stochastic Weiss conjecture is the statement that for linear stochastic evolution equations governed by a linear operator $A$ and driven by a Brownian motion, a necessary and sufficient condition for the existence of an invariant measure can be given in terms of the operators $\sqrt{\lambda}(\lambda-A)^{-1}$. Such a condition is presented in the special case where $-A$ admits a bounded $H^\infty$-calculus of angle less than $\pi/2$. This is joint work with Jamil Abreu and Bernhard Haak.
Multigrid solvers for quantum dynamics - a first look
Abstract
The numerical study of lattice quantum chromodynamics (QCD) is an attempt to extract predictions about the world around us from the standard model of physics. Worldwide, there are several large collaborations on lattice QCD methods, with terascale computing power dedicated to these problems. Central to the computation in lattice QCD is the inversion of a series of fermion matrices, representing the interaction of quarks on a four-dimensional space-time lattice. In practical computation, this inversion may be approximated based on the solution of a set of linear systems.
In this talk, I will present a basic description of the linear algebra problems in lattice QCD and why we believe that multigrid methods are well-suited to effectively solving them. While multigrid methods are known to be efficient solution techniques for many operators, those arising in lattice QCD offer new challenges, not easily handled by classical multigrid and algebraic multigrid approaches. The role of adaptive multigrid techniques in addressing the fermion matrices will be highlighted, along with preliminary results for several model problems.
Spectral analysis of the discrete Helmholtz operator preconditioned with a shifted laplacian
Abstract
Joint work with Yogi Erlangga and Kees Vuik.
Shifted Laplace preconditioners have attracted considerable attention as a technique to speed up convergence of iterative solution methods for the Helmholtz equation. In this paper we present a comprehensive spectral analysis of the Helmholtz operator preconditioned with a shifted Laplacian. Our analysis is valid under general conditions. The propagating medium can be heterogeneous, and the analysis also holds for different types of damping, including a radiation condition for the boundary of the computational domain. By combining the results of the spectral analysis of the preconditioned Helmholtz operator with an upper bound on the GMRES-residual norm we are able to provide an optimal value for the shift, and to explain the mesh-depency of the convergence of GMRES preconditioned with a shifted Laplacian. We illustrate our results with a seismic test problem.
14:15
The Heston model with stochastic interest rates and pricing options with Fourier-cosine expansions.
Abstract
In this presentation we discuss the Heston model with stochastic interest rates driven by Hull-White or Cox-Ingersoll-Ross processes.
We present approximations in the Heston-Hull-White hybrid model, so that a characteristic function can be derived and derivative pricing can be efficiently done using the Fourier Cosine expansion technique.
This pricing method, called the COS method, is explained in some detail.
We furthermore discuss the effect of the approximations in the hybrid model on the instantaneous correlations, and check the influence of the correlation between stock and interest rate on the implied volatilities.
Spectral analysis of the discrete Helmholtz operator preconditioned with a shifted Laplacian
Abstract
Shifted Laplace preconditioners have attracted considerable attention as
a technique to speed up convergence of iterative solution methods for the
Helmholtz equation. In the talk we present a comprehensive spectral
analysis of the discrete Helmholtz operator preconditioned with a shifted
Laplacian. Our analysis is valid under general conditions. The propagating
medium can be heterogeneous, and the analysis also holds for different types
of damping, including a radiation condition for the boundary of the computational
domain. By combining the results of the spectral analysis of the
preconditioned Helmholtz operator with an upper bound on the GMRES-residual
norm we are able to derive an optimal value for the shift, and to
explain the mesh-depency of the convergence of GMRES preconditioned
with a shifted Laplacian. We will illustrate our results with a seismic test
problem.
Joint work with: Yogi Erlangga (University of British Columbia) and Kees Vuik (TU Delft)