Fasshauer, Greg - Department of Applied Mathematics, Illinois Institute of Technology

• MATH 590: Meshfree Methods Chapter 14: The Power Function and Native Space Error Estimates
• MATH 461: Fourier Series and Boundary Value Chapter IV: Vibrating Strings and Membranes
• RBF Collocation Methods and Pseudospectral Methods G. E. Fasshauer
• Math 478/578: Computer Assignment 3 --due Thursday, March 22, 2007 1. Consider the IVP
• MATH 590: Meshfree Methods Chapter 8: Examples of Conditionally Positive Definite Functions
• 9 Boundary Value Problems: Collocation We now present a different type of numerical method that will yield the approximate
• 14 Arnoldi Iteration and GMRES 14.1 Arnoldi Iteration
• MATH 461 Fourier Series and Boundary-Value Problems Time and Location: 3:15pm--4:30pm MW, Location E1 121
• MATH 590: Meshfree Methods Chapter 9: Conditionally Positive Definite Radial Functions
• Math 472: Assignment 1 --due Wednesday, Sept. 14, 2005 1. Show that the function f(t, x) = x2e-t2
• MATH 461: Fourier Series and Boundary Value Chapter I: The Heat Equation
• MATH 350: Introduction to Computational Mathematics
• MATH 590: Meshfree Methods Chapter 12: Interpolation with Compactly Supported RBFs in
• Math 100 --Matlab Assignment 1, due at the end of class on Sept.2, 2010 In order to save both your commands and their output while working in the Command window
• Some Books Relevant to Multivariate Meshfree Approximation 1. S. N. Atluri and S. Shen, The Meshless Local Petrov-Galerkin (MLPG) Method, Tech
• MATH 590: Meshfree Methods Chapter 36: Generalized Hermite Interpolation
• MATH 590: Meshfree Methods Chapter 3: Positive Definite Functions
• Math 590 --Computer Assignment 3 --due Thursday, Nov. 18, 2010 1. In the maximum likelihood estimation (MLE) approach to finding an "optimal" shape parameter
• Approximate Moving Least-Squares Approximation with Compactly Supported
• MATH 590: Meshfree Methods Chapter 1: Introduction, Scattered Data Interpolation in Rs and
• MATH 590: Meshfree Methods Chapter 8: Examples of Conditionally Positive Definite Functions
• MATH 461: Fourier Series and Boundary Value Chapter III: Fourier Series
• MATH 461: Fourier Series and Boundary Value Chapter V: Sturm-Liouville Eigenvalue Problems
• MATH 350: Introduction to Computational Mathematics
• MATH 590: Meshfree Methods Chapter 43: RBF-PS Methods in MATLAB
• Math 350 --(Optional) Group Project for Presentation on April 29, 2010 Newton's Method for Square Roots
• 1 Ordinary Differential Equations 1.0 Mathematical Background
• MATH 590: Meshfree Methods Chapter 3: Positive Definite Functions
• 6 Nonlinear Algebraic Systems We saw earlier that the implementation of implicit IVP solvers often requires the so-
• Some Issues Related to Practical Implementations
• Applications 9.1 Solving Partial Differential Equations via Collocation
• Recent Results for Moving Least Squares Approximation
• MATH 590: Meshfree Methods Chapter 16: Stability and Trade-Off Principles
• 10 Gaussian Quadrature So far we have encountered the Newton-Cotes formulas
• Math 578 Computational Mathematics II Time and Location: 1:50--3:05 TR, Location E1 244
• 16 Preconditioning The general idea underlying any preconditioning procedure for iterative solvers is to
• 4 QR Factorization 4.1 Reduced vs. Full QR
• MATH 590: Meshfree Methods Chapter 38: Solving Elliptic Partial Differential Equations via RBF
• Math 477/577 --Computer Assignment 3, due Oct.12, 2006 1. Write a Matlab function [Q,R] = mgs(A) (see the discussion in the classnotes of stability of
• 11 Pseudospectral Methods for Two-Point BVPs Another class of very accurate numerical methods for BVPs (as well as many time-
• Some Books Relevant to Computational Mathematics Numerical Differential Equations
• Math 350 --Computer Assignment 3, due February 24, 2011 1. Do Exercise 3.2 in NCM.
• 12 Galerkin and Ritz Methods for Elliptic PDEs 12.1 Galerkin Method
• MATH 350: Introduction to Computational Mathematics
• Matrix-free Multilevel Moving Least-Squares Methods
• Iterated Approximate Moving Least Squares Approximation
• Noname manuscript No. (will be inserted by the editor)
• Scattered Data Approximation of Noisy Data via Iterated Moving Least Squares
• Meshfree Methods G. E. Fasshauer
• Toward Approximate Moving Least Squares Approximation with Irregularly Spaced
• Approximate Moving Least-Squares Approximation: A Fast and Accurate
• Math 350 Introduction to Computational Mathematics Time and Location: 11:25-12:40 TR, Location LS 240
• Math 477 Numerical Linear Algebra Time and Location: 1:50--3:05 TR, Location E1 242
• Math 577 Computational Mathematics I Time and Location: 1:50--3:05 TR, Location E1 242
• Math 100 --Matlab Assignment 2, due via email Sept.9, 2010 1. Write a function [p r] = longdivision(m,n) that performs the long division of two given
• Math 100 --Matlab Assignment 2, due Sept.30, 2008 1. Solve the following system of equations using Matlab's backslash operator (see help mldivide
• MATH 100 Introduction to the Profession Introduction to MATLAB
• Math 350 --Computer Assignment 4, due March 10, 2011 1. Do Exercise 4.2 in NCM.
• Math 350 --Computer Assignment 6, due April 14, 2011 General remark: If you are using the Matlab function quad to solve any of the following problems,
• MATH 350: Introduction to Computational Mathematics
• MATH 350: Introduction to Computational Mathematics
• MATH 350: Introduction to Computational Mathematics
• MATH 350: Introduction to Computational Mathematics
• MATH 350: Introduction to Computational Mathematics
• MATH 461: Fourier Series and Boundary Value Chapter I: The Heat Equation
• MATH 461: Fourier Series and Boundary Value Chapter II: Separation of Variables
• MATH 461: Fourier Series and Boundary Value Chapter IV: Vibrating Strings and Membranes
• MATH 461: Fourier Series and Boundary Value Chapter VII: Higher-Dimensional PDEs
• MATH 461: Fourier Series and Boundary Value Chapter VII: Higher-Dimensional PDEs
• Math 472: Computer Assignment 1 --due Monday, Oct. 3, 2005 1. Consider the following system of second-order initial-value problems
• Math 472: Computer Assignment 2 --due Monday, Oct.24, 2005 1. In the 1968 Olympic games in Mexico City, Bob Beamon established a world record with a
• Additional Literature for Numerical Linear Algebra 1. Demmel, J. W., Applied Numerical Linear Algebra, SIAM, 1997.
• Math 477/577 --Computer Assignment 5, due Nov.9, 2006 1. Let A be a 1010 random matrix with entries from the standard normal distribution, minus twice
• 5 Least Squares Problems Consider the solution of Ax = b, where A Cmn with m > n. In general, this system
• 6 Conditioning and Stability A computing problem is well-posed if
• 7 Gaussian Elimination and LU Factorization In this final section on matrix factorization methods for solving Ax = b we want to
• 8 Eigenvalue Problems 8.1 Motivation and Definition
• 9 Overview of Eigenvalue Algorithms As already mentioned earlier, any eigenvalue algorithm needs to be an iterative one.
• 10 The Rayleigh Quotient and Inverse Iteration From now on we will restrict the discussion to real symmetric matrices A Rmm whose
• 11 The QR Algorithm 11.1 QR Algorithm without Shifts
• 12 How to Compute the SVD We saw earlier that the nonzero singular values of A are given by the square roots of
• 15 Conjugate Gradients This method for symmetric positive definite matrices is considered to be the "original"
• Math 478/578: Computer Assignment 1 --due Tuesday, Feb. 13, 2007 1. Consider the following system of second-order initial-value problems
• Math 478/578: Computer Assignment 2 --due Tuesday, Feb. 27, 2007 1. Using various values of , such as 5, -5, or -10, numerically solve the following initial value
• 3 Runge-Kutta Methods In contrast to the multistep methods of the previous section, Runge-Kutta methods
• 5 Error Control 5.1 The Milne Device and Predictor-Corrector Methods
• 7 Boundary Value Problems for ODEs Boundary value problems for ODEs are not covered in the textbook. We discuss this
• MATH 590: Meshfree Methods Chapter 2: Radial Basis Function Interpolation in MATLAB
• MATH 590: Meshfree Methods Chapter 6: Scattered Data Interpolation with Polynomial Precision
• MATH 590: Meshfree Methods Chapter 7: Conditionally Positive Definite Functions
• MATH 590: Meshfree Methods Chapter 7: Conditionally Positive Definite Functions
• MATH 590: Meshfree Methods Chapter 9: Conditionally Positive Definite Radial Functions
• MATH 590: Meshfree Methods Chapter 10: Other Norms
• MATH 590: Meshfree Methods Chapter 11: Compactly Supported Radial Basis Functions
• MATH 590: Meshfree Methods Chapter 11: Compactly Supported Radial Basis Functions
• MATH 590: Meshfree Methods Chapter 14: The Power Function and Native Space Error Estimates
• MATH 590: Meshfree Methods Chapter 18: The Optimality of RBF Interpolation
• MATH 590: Meshfree Methods Chapter 33: Adaptive Iteration
• MATH 590: Meshfree Methods Chapter 34: Improving the Condition Number of the Interpolation
• MATH 590: Meshfree Methods Chapter 36: Generalized Hermite Interpolation
• MATH 590: Meshfree Methods Chapter 37: RBF Hermite Interpolation in MATLAB
• MATH 590: Meshfree Methods Chapter 38: Solving Elliptic Partial Differential Equations via RBF
• MATH 590: Meshfree Methods Chapter 40: Symmetric RBF Collocation in MATLAB
• MATH 590: Meshfree Methods Chapter 42: Using Radial Basis Functions in Pseudospectral Mode
• MATH 590: Meshfree Methods Chapter 43: RBF-PS Methods in MATLAB
• Scattered Data Interpolation with Polynomial Precision and
• Least Squares Approximation As we saw in Chapter 5 we can interpret radial basis function interpolation as a con-
• Green's Functions: Taking Another Look at Kernel Approximation, Radial Basis Functions
• Preconditioning of Radial Basis Function Interpolation Systems via Accelerated Iterated
• MATH 590: Meshfree Methods Chapter 10: Other Norms
• 2 Singular Value Decomposition The singular value decomposition (SVD) allows us to transform a matrix A Cmn to
• MATH 590: Meshfree Methods Chapter 16: Stability and Trade-Off Principles
• 13 Fast Fourier Transform (FFT) The fast Fourier transform (FFT) is an algorithm for the efficient implementation of
• MATH 590: Meshfree Methods Chapter 17: Numerical Evidence for Approximation Order Results
• Math 590 Meshfree Methods Time and Location: 1:50--3:05 TR, Location E1 034
• Math 590 --Computer Assignment 1 --due Thursday, Sept. 9, 2010 1. Compare the three different versions of DistanceMatrix given in the slides for memory and
• MATH 461: Fourier Series and Boundary Value Chapter II: Separation of Variables
• MATH 590: Meshfree Methods Chapter 20: Theory for Least Squares Approximation
• Introduction 1.1 History and Outline
• Math 350 --Computer Assignment 1, due Jan. 27, 2011 1. Modify the programs Skydive.m and SkydiveDemo.m to simulate the solution of Problem #3
• Math 152 ---Practice Test 3 1. (a) Plot the point (1:5; 3=2) given in polar coordinates.
• Math 100 --MATLAB Project 1. For this project you will need a text file (such as the file gettysburg.txt of Lincoln's Gettysburg
• MATH 590: Meshfree Methods Chapter 40: Symmetric RBF Collocation in MATLAB
• MATH 590: Meshfree Methods Chapter 2: Radial Basis Function Interpolation in MATLAB
• MATH 590: Meshfree Methods Chapter 4: Examples of Strictly Positive Definite Radial Functions
• MATH 350: Introduction to Computational Mathematics
• RATE OF CONVERGENCE AND TRACTABILITY OF THE RADIAL FUNCTION APPROXIMATION PROBLEM
• MATH 590: Meshfree Methods Chapter 13: Reproducing Kernel Hilbert Spaces and Native Spaces
• Compactly Supported Radial Basis Functions
• 1 Ordinary Differential Equations 1.0 Mathematical Background
• On Smoothing for Multilevel Approximation with Radial Basis Functions
• MATH 590: Meshfree Methods Chapter 5: Completely Monotone and Multiply Monotone Functions
• MATH 350: Introduction to Computational Mathematics
• MATH 590: Meshfree Methods Chapter 17: Numerical Evidence for Approximation Order Results
• 1 Fundamentals 1.0 Preliminaries
• Math 472: Computer Assignment 3 --due Monday, Nov.7, 2005 1. Consider the IVP
• MATH 590: Meshfree Methods Chapter 15: Refined and Improved Error Bounds
• Moving Least Squares Approximation
• MATH 590: Meshfree Methods Chapter 6: Scattered Data Interpolation with Polynomial Precision
• MATH 478 Numerical Methods for Differential Equations Time and Location: 1:50--3:05 TR, Location E1 244
• MATH 350: Introduction to Computational Mathematics
• Numerical Algorithms manuscript No. (will be inserted by the editor)
• MATH 590: Meshfree Methods Chapter 33: Adaptive Iteration
• Introduction 1.1 History and Outline
• Math 477/577 --Computer Assignment 6, due Nov.28, 2006 1. This five-part problem asks you to put together a MATLAB program that finds all the eigenvalues
• MATH 590: Meshfree Methods Chapter 19: Least Squares RBF Approximation with MATLAB
• Numerical Algorithms 0 (2000) 1--15 1 Newton Iteration for Partial Differential Equations
• MATH 590: Meshfree Methods Chapter 42: Using Radial Basis Functions in Pseudospectral Mode
• 17 Solution of Nonlinear Systems We now discuss the solution of systems of nonlinear equations. An important ingredient
• Math 590 --Computer Assignment 2 --due Thursday, October. 14, 2010 1. Consider RBF interpolation on S2, the unit sphere in R3. The simplest approach to solving this
• 8 Boundary Value Problems for PDEs Before we specialize to boundary value problems for PDEs --which only make sense
• MATH 590: Meshfree Methods Chapter 39: Non-Symmetric RBF Collocation in MATLAB
• MATH 350: Introduction to Computational Mathematics
• Error Bounds and the Variational Approach
• Algorithms Defined by Nash Iteration: Some Implementations via Multilevel Collocation and
• 3 Projectors If P Cmm is a square matrix such that P2 = P then P is called a projector. A
• MATH 590: Meshfree Methods Chapter 12: Interpolation with Compactly Supported RBFs in
• Math 477/577 --Computer Assignment 4, due Oct.26, 2006 1. Take m = 50, n = 12. Using MATLAB's linspace, define t to be the m-vector corresponding
• 13 Classical Iterative Methods for the Solution of Linear 13.1 Why Iterative Methods?
• A Practical Introduction to Matlab (Updated for Matlab 5)
• MATH 590: Meshfree Methods Chapter 1: Introduction, Scattered Data Interpolation in Rs and
• MATH 590: Meshfree Methods Chapter 4: Examples of Strictly Positive Definite Radial Functions
• MATH 590: Meshfree Methods Chapter 13: Reproducing Kernel Hilbert Spaces and Native Spaces
• MATH 590: Meshfree Methods Chapter 18: The Optimality of RBF Interpolation
• MATH 590: Meshfree Methods Chapter 37: RBF Hermite Interpolation in MATLAB
• MATH 590: Meshfree Methods Chapter 39: Non-Symmetric RBF Collocation in MATLAB
• MATH 461: Fourier Series and Boundary Value Chapter III: Fourier Series
• Approximate Moving Least-Squares Approximation with Compactly Supported
• Nonsymmetric Multilevel RBF Collocation within an Operator Newton Framework for Nonlinear PDEs
• Solving Partial Differential Equations by Collocation with Radial Basis Functions
• Scattered Data Fitting on the Sphere Gregory E. Fasshauer and Larry L. Schumaker
• Solving Differential Equations with Radial Basis Functions
• MATH 350: Introduction to Computational Mathematics
• Approximate Moving LeastSquares Approximation: A Fast and Accurate
• 2 Multistep Methods Up to now, all methods we studied were single step methods, i.e., the value yn+1 was
• MATH 590: Meshfree Methods Chapter 34: Improving the Condition Number of the Interpolation
• MATH 461: Fourier Series and Boundary Value Chapter V: Sturm-Liouville Eigenvalue Problems
• MATH 590: Meshfree Methods Chapter 5: Completely Monotone and Multiply Monotone Functions
• Positive Definite and Completely Monotone Functions
• 4 Stiffness and Stability In addition to having a stable problem, i.e., a problem for which small changes in the
• Using Meshfree Approximation for Multi-Asset American Option Problems
• Solving Differential Equations with Radial Basis Functions
• Hermite Interpolation with
• Numerical Algorithms 0 (2000) 1-15 * Newton Iteration for Partial Differential Equations
• Matrix-free Multilevel Moving Least-Squares Methods
• Newton Iteration with Multiquadrics for the Solution of Nonlinear PDEs
• On Smoothing for Multilevel Approximation with Radial Basis Functions
• Multistep Approximation Algorithms: Improved Convergence Rates through
• On the numerical solution of differential equations with radial basis functions
• Minimal Energy Surfaces using Parametric Splines
• Approximate Moving Least-Squares Approximation: A Fast and Accurate
• MATH 100 Introduction to the Profession Applied Mathematicians Who are we, and what do we do?
• MATH 100 Introduction to the Profession Introduction to MATLAB
• Positive Definite Kernels: Past, Present and Future Gregory E. Fasshauer
• Math 100 Menger Sponge Project1 Background
• Approximation of Stochastic Partial Differential Equations by a Kernel-based Collocation Method
• Illinois Institute of Technology Department of Applied Mathematics
• MATH 100 Introduction to the Profession Time and Location: 11:25pm--12:15pm TR, Location E1 034 or E1 029
• 20 NOVEMBER 2010 MATH HORIZONS WWW.MAA.ORG/MATHHORIZONS bout six years ago I was a
• MATH 100 Introduction to the Profession Applied Mathematicians Who are we, and what do we do?
• Math 100 Project: Estimate Travel Times on Faculty Adviser: Xiaofan Li
• MATH 100 Introduction to the Profession Linear Equations in MATLAB
• MATH 100 Introduction to the Profession Vectors, Functions and Dates in MATLAB
• MATH 100 Introduction to the Profession Greg Fasshauer
• MATH 100 Introduction to the Profession Greg Fasshauer
• MATH 100 Introduction to the Profession Random Affine Transformations and Fractals in MATLAB
• MATH 100 Introduction to the Profession The Need for Approximation
• MATH 100 Introduction to the Profession Differential Equations in MATLAB
• MATH 100 Introduction to the Profession Random Affine Transformations and Fractals in MATLAB
• MATH 100 Introduction to the Profession Differential Equations in MATLAB
• Math 461 --Practice Problems (from old exams) --November 1, 2011 1. (a) Show that the functions 1(x) = 1 and 2(x) = x are orthogonal on the interval [-1, 1]
• MATH 100 Introduction to the Profession Greg Fasshauer
• MATH 100 Introduction to the Profession Modeling and the Exponential Function in MATLAB
• MATH 100 Introduction to the Profession Modeling and the Exponential Function in MATLAB
• MATH 100 Introduction to the Profession Greg Fasshauer
• MATH 100 Introduction to the Profession Matrices and Linear Transformations in MATLAB
• ON DIMENSION-INDEPENDENT RATES OF CONVERGENCE FOR FUNCTION APPROXIMATION WITH GAUSSIAN KERNELS
• MATH 100 Introduction to the Profession The Need for Approximation
• MATH 100 Introduction to the Profession Linear Equations in MATLAB