Title: | Market Efficiency and Investment Strategies, a case study of Hong Kong racetrack betting Market |
Speaker: | Prof. Gu, Ming-Gao , Department of Statistics , The Chinese University of Hong Kong, HKSAR, China |
Time/Place: | 11:30 - 12:30 NAB209, Dr. Wu Lee Sun Lecture Theatre, Lam Woo International Conference Centre, |
Abstract: | We review the definitions of efficient market hypothesis and the basics of horse racing betting markets. Different ranking data models have been used for predictions in horse racing. Problems involved here are partially ranked data, model selections, variable selections and predictions. For computation, MCMC techniques can be applied. Constant rebalanced portfolio investment strategies can be used in actual investment. Hong Kong Jockey Club horse racing data were used to show that the horse racing betting markets are weakly efficient but not strongly efficient. |
Title: | Institute for Computational Mathematics (ICM) Lecture Series: Matrices, Moments and Quadrature (Lecture1) |
Speaker: | Prof. Gerard Meurant, Commissariat a l`Energie Atomique, CEA/DIF, France |
Time/Place: | 14:00 - 15:30 FSC1217, Fong Shu Chuen Library, HSH Campus, Hong Kong Baptist University |
Abstract: | The aim of this series of lectures is to describe and explain the beautiful mathematical relationships between matrices, moments, orthogonal polynomials, quadrature rules and the Lanczos and conjugate gradient algorithms. The main topic is to obtain numerical methods to estimate or in some cases to bound quantities like I[f] = uT f (A)v where u and v are given vectors, A is a symmetric nonsingular matrix and f is a smooth function. There are many instances in which one would like to compute bilinear forms like uT f (A)v. A first application is the computation of some elements of the matrix f (A) when it is not desired or feasible to compute all of f (A). Computation of quadratic forms rTA−ir for i = 1, 2 is interesting to obtain estimates of error norms when one has an approximate solution of a linear system Ax = b and r is the residual vector b − Ax. Bilinear or quadratic forms arise naturally for the computation of parameters in problems like least squares, total least squares and regularization methods for solving ill–posed problems. We will describe the algorithms and give some examples of applications. The contents of the lectures are the following. 1. Orthogonal polynomials and properties of tridiagonal matrices. 2. The Lanczos and conjugate gradient (CG) algorithms and computation of Jacobi matrices 3. Gauss quadrature and bounds for bilinear forms uT f (A)v 4. Applications: Bounds for elements of f (A), Estimates of error norms in CG, Least squares and total least squares, Discrete ill–posed problems. |
Title: | Institute for Computational Mathematics (ICM) Lecture Series: Matrices, Moments and Quadrature (Lecture 2) |
Speaker: | Prof. Gerard Meurant, Commissariat a l`Energie Atomique, CEA/DIF, France |
Time/Place: | 14:00 - 15:30 FSC1217, Fong Shu Chuen Library, HSH Campus, Hong Kong Baptist University |
Abstract: | The aim of this series of lectures is to describe and explain the beautiful mathematical relationships between matrices, moments, orthogonal polynomials, quadrature rules and the Lanczos and conjugate gradient algorithms. The main topic is to obtain numerical methods to estimate or in some cases to bound quantities like I[f] = uT f (A)v where u and v are given vectors, A is a symmetric nonsingular matrix and f is a smooth function. There are many instances in which one would like to compute bilinear forms like uT f (A)v. A first application is the computation of some elements of the matrix f (A) when it is not desired or feasible to compute all of f (A). Computation of quadratic forms rTA−ir for i = 1, 2 is interesting to obtain estimates of error norms when one has an approximate solution of a linear system Ax = b and r is the residual vector b − Ax. Bilinear or quadratic forms arise naturally for the computation of parameters in problems like least squares, total least squares and regularization methods for solving ill–posed problems. We will describe the algorithms and give some examples of applications. The contents of the lectures are the following. 1. Orthogonal polynomials and properties of tridiagonal matrices. 2. The Lanczos and conjugate gradient (CG) algorithms and computation of Jacobi matrices 3. Gauss quadrature and bounds for bilinear forms uT f (A)v 4. Applications: Bounds for elements of f (A), Estimates of error norms in CG, Least squares and total least squares, Discrete ill–posed problems. |
Title: | Bayesian Data Integration for Periodicity Detection on Cell Cycle Gene Expression Data |
Speaker: | Dr. Fan Xiaodan, Statistics Department, The Chinese University of Hong Kong, Hong Kong |
Time/Place: | 11:30 - 12:30 FSC1217, Fong Shu Chuen Library, HSH Campus, |
Abstract: | Periodicity detection is important for cell cycle study, which is the key to understanding some serious diseases such as cancer. A lot of experimental effort has been devoted to improve the discrimination power of periodicity detection, but the computational side still needs improvement to fully explore the discrimination power provided by these data sets. I will present a Bayesian data integration approach for combining multiple microarray time-course data sets to detect periodically expressed genes. The result is striking for the cell-cycle research community. It also shows that the power and potential of model-based Bayesian meta-analysis is appealing. The main focus will put on probabilistic modeling of the cell cycle data and Bayesian computation of the whole system. Little biology background is needed for understanding the key point of the talk. |
Title: | Institute for Computational Mathematics (ICM) Lecture Series: Matrices, Moments and Quadrature (Lecture 3) |
Speaker: | Prof. Gerard Meurant, Commissariat a l`Energie Atomique, CEA/DIF, France |
Time/Place: | 14:00 - 15:30 FSC1217, Fong Shu Chuen Library, HSH Campus, Hong Kong Baptist University |
Abstract: | The aim of this series of lectures is to describe and explain the beautiful mathematical relationships between matrices, moments, orthogonal polynomials, quadrature rules and the Lanczos and conjugate gradient algorithms. The main topic is to obtain numerical methods to estimate or in some cases to bound quantities like I[f] = uT f (A)v where u and v are given vectors, A is a symmetric nonsingular matrix and f is a smooth function. There are many instances in which one would like to compute bilinear forms like uT f (A)v. A first application is the computation of some elements of the matrix f (A) when it is not desired or feasible to compute all of f (A). Computation of quadratic forms rTA−ir for i = 1, 2 is interesting to obtain estimates of error norms when one has an approximate solution of a linear system Ax = b and r is the residual vector b − Ax. Bilinear or quadratic forms arise naturally for the computation of parameters in problems like least squares, total least squares and regularization methods for solving ill–posed problems. We will describe the algorithms and give some examples of applications. The contents of the lectures are the following. 1. Orthogonal polynomials and properties of tridiagonal matrices. 2. The Lanczos and conjugate gradient (CG) algorithms and computation of Jacobi matrices 3. Gauss quadrature and bounds for bilinear forms uT f (A)v 4. Applications: Bounds for elements of f (A), Estimates of error norms in CG, Least squares and total least squares, Discrete ill–posed problems. |
Title: | Institute for Computational Mathematics (ICM) Lecture Series: Matrices, Moments and Quadrature (Lecture 4) |
Speaker: | Prof. Gerard Meurant, Commissariat a l`Energie Atomique, CEA/DIF, France |
Time/Place: | 14:00 - 15:30 FSC1217, Fong Shu Chuen Library, HSH Campus, Hong Kong Baptist University |
Abstract: | The aim of this series of lectures is to describe and explain the beautiful mathematical relationships between matrices, moments, orthogonal polynomials, quadrature rules and the Lanczos and conjugate gradient algorithms. The main topic is to obtain numerical methods to estimate or in some cases to bound quantities like I[f] = uT f (A)v where u and v are given vectors, A is a symmetric nonsingular matrix and f is a smooth function. There are many instances in which one would like to compute bilinear forms like uT f (A)v. A first application is the computation of some elements of the matrix f (A) when it is not desired or feasible to compute all of f (A). Computation of quadratic forms rTA−ir for i = 1, 2 is interesting to obtain estimates of error norms when one has an approximate solution of a linear system Ax = b and r is the residual vector b − Ax. Bilinear or quadratic forms arise naturally for the computation of parameters in problems like least squares, total least squares and regularization methods for solving ill–posed problems. We will describe the algorithms and give some examples of applications. The contents of the lectures are the following. 1. Orthogonal polynomials and properties of tridiagonal matrices. 2. The Lanczos and conjugate gradient (CG) algorithms and computation of Jacobi matrices 3. Gauss quadrature and bounds for bilinear forms uT f (A)v 4. Applications: Bounds for elements of f (A), Estimates of error norms in CG, Least squares and total least squares, Discrete ill–posed problems. |
We organize conferences and workshops every year. Hope we can see you in future.
Learn MoreProf. M. Cheng, Dr. Y. S. Hon, Dr. K. F. Lam, Prof. L. Ling, Dr. T. Tong and Prof. L. Zhu have been awarded research grants by Hong Kong Research Grant Council (RGC) — congratulations!
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