Difference between revisions of "MAT3633"

Section 0.2: Loss of significant digits

• Loss of Significant Digits
• Nested Multiplication

• Binary Number System
• Taylor's Theorem

• Nested Multiplication for Evaluating Polynomials
• Machine Representation of Real Numbers
• Loss of Significant Digits in Numerical Computing
• Review of Taylor's Theorem

Section 1.1: Fixed-Point Iteration

• Bisection Method

• Intermediate Value Theorem

• Bisection Method and Implementation
• Brief Introduction to Matlab

Section 1.2: Fixed-Point Iteration

• Fixed-Point Iteration
• Order of Convergence of Iterative Methods

• Limit of Sequences
• Solution Multiplicity of Equations

• Geometric Interpretation of Fixed-Point Iteration
• Convergence of Fixed Point Iterations
• Order of Convergence of Iterative Methods

Section 1.3: Limits of Accuracy: Conditioning of Problems

• Wilkinson Polynomial

• Limit of Sequences
• Solution Multiplicity of Equations

• Sensitivity Analysis of Root-Finding
• Error Magnification Factor for Solution of Equations

Section 1.4: Newton's Method

• Newton's Method
• Error Analysis for Newton's Method
• Modified Newton's Method

• Root-Finding Without Derivatives
• Secant Method and its Convergence
• Method of False Position, Muller's Method
• Stopping Criteria for Iterative Methods

• Remainder of Taylor's Series
• Intermediate Value Theorem
• Fixed-Point Iteration

• Algebraic and Geometric Interpretation of Newton's method
• Error Analysis for Newton's Method Based on Taylor's Theorem
• Newton's Method as a Fixed Point Iteration
• Modified Newton's Method and its Rate of Convergence

Section 1.5 Root-Finding Without Derivatives

• Secant Method
• Method of False Position
• Muller's Method
• Stopping Criteria

• Remainder of Taylor's Series
• Intermediate Value Theorem

• Secant Method and its Convergence
• Stopping Criteria for Iterative Methods

Section 2.1 Solve Systems of Linear Equations: Gaussian Elimination

• Gaussian Elimination

• Elementary Row Operations

• Gaussian Elimination and its Operation Counts
• Gaussian Elimination with Pivoting
• Implementation of Gauss Elimination

Section 2.2 Solve Systems of Linear Equations: LU Decomposition

• LU Decomposition

• Matrix-Matrix Products
• Matrix-Vector Products
• Inverse Matrix
• Elementary Row Operations

• Matrices for Elementary Row Operations
• Gauss Elimination as Matrix Products
• Advantages of Solutions by LU Decomposition

Section 2.3 Error Analysis for Solution of Ax=b

• Norms
• Error Analysis for Solution of Ax=b
• Error Magnification Factor and Condition Number of Matrix

• Length of Vectors
• Eigenvalues of a Matrix
• Eigenvectors of a Matrix

• Various Norms for Vectors and Matrices: Compatibility of Vector and Matrix Norms
• Error Analysis for Solution of Ax=b
• Error Magnification Factor and Condition Number of Matrix

Section 2.5: Iterative Methods for Solving Ax=b

• Iterative Methods
• Jacobi Method
• Gauss-Seidel Method
• Successive-Over-Relaxation (SOR) Method
• Convergence of Iterative Methods
• Spectral Radius of Matrix
• Sparse Matrix

• Length of Vectors
• Eigenvalues of a Matrix
• Eigenvectors of a Matrix

• Convergence of General Iterative Method for Solving System of Linear Equations
• Comparison of Gauss Elimination and Iterative Methods

Section 2.6: Conjugate Gradient (CG) Method

• Conjugate Gradient Method
• Symmetric Positive Definite Matrix
• CG Method

• Scalar Product of Vectors
• Determinant of a Matrix
• Eigenvalues of a Matrix
• Quadratic Polynomials of n-variables
• Partial Derivatives
• Gradients
• Chain Rule for Partial Derivatives

• Symmetric Positive Definite Matrix and Properties
• Construction of Conjugate Gradient (CG) Method
• Properties of CG Method
• Preconditioning for CG Method

Section 2.7: Nonlinear System of Equations

• Nonlinear System of Equations
• Taylor's Theorem for Multi-Variate Vector Valued Functions
• Newton's Method
• Broyden's Method

• Scalar Product of Vectors
• Determinant of a Matrix
• Eigenvalues of a Matrix
• Quadratic Polynomials of n-variables
• Partial Derivatives
• Gradients
• Chain Rule for Partial Derivatives

• (TBD)

Sections 3.1: Data and Interpolating Functions

• Lagrange Basis Functions
• Newton's Divided Differences
• Properties of Newton's Divided Differences

• Fundamental Theorem of Algebra
• Rolle's Theorem

• Properties of Lagrange Basis Functions
• Lagrange Form of the Interpolation Polynomials
• Properties of Newton's Divided Differences
• Newton's Form of the Interpolation Polynomials

Section 3.2: Interpolation Error and Runge Phenomenon

• Interpolation Error
• Interpolation Error Analysis
• Runge Phenomenon
• Chebyshev Polynomial
• Error Estimates for Chebyshev Interpolation

• Fundamental Theorem of Algebra
• Rolle's Theorem

• (TBD)

Section 3.4: Cubic Splines

• Cubic Splines

• One-Sided Limits
• Continuity of Functions
• Indefinite Integrals
• Extremum Values of Multivariate Quadratic Functions

• Construction of Cubic Splines for Interpolation
• End Conditions
• Properties of Cubic Spline Interpolation

Section 3.5: Bezier Curves

• Bezier Curves

• One-Sided Limits
• Continuity of Functions
• Indefinite Integrals
• Extremum Values of Multivariate Quadratic Functions

• Bezier Curve and Fonts

Section 4.1: Least Square Method

• Least Square Method

• One-Sided Limits
• Continuity of Functions
• Indefinite Integrals
• Extremum Values of Multivariate Quadratic Functions

• Least Square Method for Solving Inconsistent System of Linear Equations]
• Basic Properties of Least Square Solutions

Section 4.2: Mathematical Models and Data Fitting

• Curve Fitting
• Statistical Modeling

• Linear Spaces
• Basis Functions
• Product Rule for Vector Valued Multivariate Functions
• Chain Rule for Vector Valued Multivariate Functions

• Least square method for curve fitting and statistical modeling
• Survey of Models: linear model, periodic model, exponential models, logistic model, etc

Section 4.5: Nonlinear Least Square Fitting

• Taylor's Theorem for Vector Valued Multivariate Functions
• Gauss-Newton Method
• Levenberg-Marquardt Method

• Linear Spaces
• Basis Functions
• Product Rule for Vector Valued Multivariate Functions
• Chain Rule for Vector Valued Multivariate Functions

• (TBD)

Section 5.1: Numerical Differentiation

• Numerical Differentiation
• Finite Difference (FD)
• Undetermined Coefficient Method
• Extrapolation Technique

• Taylor's Theorem
• Interpolation Error Estimates
• Properties of Definite Integrals

• Finite Difference (FD) Approximations of 1st order Derivative and Their Error Analysis
• FD approximations of 2nd order Derivatives and Their Error Analysis
• Undetermined Coefficient Method for FD Approximation
• Extrapolation Technique for Improving the Order of Approximation

Section 5.2: Numerical Integration: Newton-Cotes Formulas

• Newton-Cotes
• Midpoint rule
• Trapezoid rule
• Simpson's rule
• Error Analysis based on Interpolation Errors
• Quadrature Rules
• Composite Quadrature Rules

• Taylor's Theorem
• Interpolation Error Estimates
• Properties of Definite Integrals

• Error Analysis based on Taylor's Theorem
• Error Analysis based on Interpolation Errors
• Degree of Precision of Quadrature Rules

Section 5.3: Numerical Integration: Romberg's Technique

• Romberg's Technique

• Taylor's Theorem
• Interpolation Error Estimates
• Properties of Definite Integrals

• Motivation, construction and implementation of Romberg's Technique.

Section 5.4: Adaptive Numerical Integration

• Adaptive Numerical Integration
• Implementation of Adaptive Numerical Integration Techniques

• Long Divisions
• Substitution Methods for definite integrals

• How to estimate the error on a sub interval
• How to mark sub intervals to be further refinement?

Section 5.5: Gauss Quadrature Formulas

• Gauss Quadrature Formulas
• Orthogonal Polynomials
• Legendre polynomials
• Gauss Quadrature Rule

• Long Divisions
• Substitution Methods for definite integrals

• Motivation and difficulties with straightforward approach
• Legendre polynomials and their basic properties
• Gauss Quadrature rule based on Legendre polynomials
• Degree of precision of Gauss Quadrature
• Gauss quadrature formula on general interval and composite Gauss rules

Section 10.1: Discrete Fourier Transform and Fast Fourier Transform (FTT)

• Fourier Series
• Discrete Fourier Transform (DFT)
• Inverse Discrete Fourier Transform
• Fast Fourier Transform (FFT)

• Complex Numbers
• Complex Variables
• Integration by Parts
• Convergence of Sequences
• Convergence of Series

• Matrix Form of Discrete Fourier Transform
• DFT and Trigonometric Interpolation

Section 11.1: Discrete Cosine Transform (optional)

• Discrete Cosine Transform
• Discrete Cosine Transform(DCT)

• Complex Numbers
• Complex Variables
• Integration by Parts
• Convergence of Sequences
• Convergence of Series

• DCT and Interpolation by Cosine Functions
• Relation between DFT and DCT
• Fourier Transform of 2-Dimensional Functions
• DCT of 2-Dimensional Functions
• Interpolation Theorem for 2-Dimensional DCT

Section 11.2: Image Compression (optional)

• [[Image Compression]
• Quantization
• Image Compression
• Image Decompression

• Complex Numbers
• Complex Variables
• Integration by Parts
• Convergence of Sequences
• Convergence of Series

• Digital Gray scale images and color color images
• RGB format
• YCbCr (or YUV) format
• Convertion between RGB and YUV formats

Section 12.1: Power Iteration Methods

• Power Iteration Methods
• Inverse Power Iteration
• Inverse Power Iteration with Shift
• Rayleigh Quotient Iteration

• Eigenvalues
• Eigenvectors
• Orthonormal Bases and the Gram-Schmidt Process

• Convergence of Power Iteration Methods

Section 12.2: QR Algorithm for Computing Eigenvalues

• Orthogonal Matrices
• QR-Factorization
• Normalized Simultaneous Iteration(NSI)
• Unshifted QR Algorithm
• Shifted QR Algorithm

• Eigenvalues
• Eigenvectors
• Orthonormal Bases and the Gram-Schmidt Process

• Definition and basic properties of orthogonal matrices
• QR-Factorization based on Gram-Schmidt Orthogonalization

Section 12.2: QR Algorithm for Computing Eigenvalues

• Upper Hessenberg Form (UHF)
• Householder Reflector

• Matrices for Orthogonal Projection
• Matrices for Reflection
• Block Matrices
• Similar Matrices

• Convert a matrix into UHF by Householder reflectors