Sharp, Philip - Department of Mathematics, University of Auckland

• Stars, Galaxies and Cosmology 2. Star clusters
• 445.370SC: Advanced Numerical Methods 1.1 Show that H = I -2ww is a reflection in the plane orthogonal to real n 1 vector w.
• MATHS 370SC: Advanced Numerical Methods Assignment 4
• Comparisons of integrators on a diverse collection of restricted three-body test problems
• MATHS 270FC: Numerical Computation Assignment 4
• MATHS370SC 30th July 03 Hessenberg form & QR with shift Put matrix a (eigenvalues 2, 1, -1) in upper Hessenberg form.
• Stars, Galaxies and Cosmology Nebulae such as the Horsehead and Crab nebulae
• 445.370SC: Advanced Numerical Methods Assignment 1
• MATHS 270FC: Numerical Computation The two lists below are intended for students who want to do well on the final exam and who
• MATHS 370: Advanced Numerical Methods Answers to tutorial 10
• Real and Complex Calculus Sample questions for the mid-semester test
• Real and Complex Calculus The Earth's Mass
• 445.370SC: Advanced Numerical Methods Assignment 2 Answers
• MATHS 270FC: Numerical Computation Study questions for the final exam
• MATHS 270FC: Numerical Computation Problem class
• A collection of restricted three-body test problems Department of Mathematics, University of Auckland, Private Bag 92019,
• MATHS 270FC: Numerical Computation Assignment 4
• MATHS 370: Advanced Numerical Methods 1. The stability function for the two-stage implicit Runge-Kutta method is
• MATHS 270FC: Numerical Computation Problem class
• MATHS370FC: Numerical Computation Assignment three
• Curves and line integrals Definition: Let
• MATHS 340: Real and Complex Calculus Assignment two
• The error growth of some symplectic explicit Runge-Kutta Nystrom methods on long N-body
• 445.370SC: Advanced Numerical Methods 1. The first few Chebyshev polynomials are 1, x, 2x2
• MATHS 370: Advanced Numerical Methods 2. Solving linear systems using QR factors
• MATHS 270FC: Numerical Computation Problem class
• MATHS 270FC: Numerical Computation Mid-semester test
• N-body simulations: the performance of eleven integtrators
• MATHS 270FC: Numerical Computation Assignment 2
• Directional derivative and arclength Let C be a curve in three-dimensional space with points R(s) defined as (x(s), y(s), z(s)) where s is the
• MATHS 370: Advanced Numerical Methods Sample questions: outline of answers
• MATHS 370: Advanced Numerical Methods Sample questions
• Comparisons of high order Stormer and explicit Runge-Kutta Nystrom methods for N-body
• MATHS 340: Real and Complex Calculus Assignment one
• MATHS 340: Real and Complex Calculus Assignment one
• MATHS 370SC: Advanced Numerical Methods TEST RESULTS
• MATHS 370: Advanced Numerical Methods Adaptive quadrature
• MATHS 270FC: Numerical Computation Assignment 3
• MATHS270FC: Numerical Computation Matlab review
• MATH 270S1C: Numerical Computation Assignment one
• Stars, Galaxies and Cosmology 4. Galaxies
• 445.370SC: Advanced Numerical Methods Assignment 1
• Department of Mathematics 370SC Chebyshev polynomials
• Double integrals 1 Introduction
• Stars, Galaxies and Cosmology 5. Clusters of galaxies
• MATH 270S1C: Numerical Computation Assignment one
• Vector products 1 Cross product
• Comparisons of integrators on a diverse collection of restricted three-body test problems
• Stars, Galaxies and Cosmology 7. Hyperclusters
• N-body simulations: the performance of eleven integtrators
• MATHS 340: Real and Complex Calculus Assignment one
• Long simulations of the Solar System: Brouwer's Law and Chaos
• Brouwer's Law: Optimal Multistep Integrators for Celestial Mechanics
• Real and Complex Calculus Study guide
• MATHS 370SC Advanced Numerical Methods Study guide
• MATHS370SC 23rd July 03 Least Squares QR in matlab Scriptfile: sunsetscript.m
• MATHS 370SC Advanced Numerical Methods 1. The amount of time is takes to compute QR factors is proportional to the number of
• MATHS 370SC Advanced Numerical Methods 1. Use the QR method (version II) to find the eigenvalues of the matrix
• 445.370: Advanced Numerical Methods Lab 4 Answers
• MATHS 370: Advanced Numerical Methods This lab gives practice at using matlab to solve initial-value ordinary differential equations.
• MATHS 370: Advanced Numerical Methods This lab deals with the adaptive Simpson's Rule.
• 445.370SC: Advanced Numerical Methods 1. The product Hx between a Householder matrix H = I -2wwT
• 445.370SC: Advanced Numerical Methods Tutorial 3 Answers
• MATHS 370SC: Advanced Numerical Methods Assignment 4
• MATHS 370SC: Advanced Numerical Methods TEST SAMPLE ANSWERS
• MATHS 270FC: Numerical Computation Introduction to vector and matrix norms
• MATHS 270FC: Numerical Computation Linear algebraic equations: direct methods
• MATHS 270FC: Numerical Computation Initial value ordinary differential equations
• MATHS 270FC: Numerical Computation Assignment 2
• MATHS 270FC: Numerical Computation Assignment 3
• MATHS 270FC: Numerical Computation Problem class
• MATHS 270FC: Numerical Computation Problem class
• MATHS 270FC: Numerical Computation Problem class
• MATHS 270FC: Numerical Computation Problem Class
• MATHS 270FC: Numerical Computation Problem Class
• MATHS 270FC: Numerical Computation Study questions for the mid-semester test
• Taylors formula: one and two variables 1 One variable
• Differentiation of a vector Let u be a vector whoses components depend on . For example, u might be
• Triple integrals Example (Example 3, page 728). Evaluate
• Volumes and volume integrals In this section of the course we are interested in evaluating
• Grad, div and curl 1 Scalar and vector fields
• MATHS 340: Real and Complex Calculus Assignment one
• MATHS 340: Real and Complex Analysis Assignment two
• MATHS 340: Real and Complex Calculus Assignment two
• MATHS 340: Real and Complex Calculus Assignment two
• MATHS 340: Real and Complex Calculus Assignment two
• Real and Complex Calculus Textbook chapters and sections
• Stars, Galaxies and Cosmology I begin with an introduction to the different types
• Stars, Galaxies and Cosmology 6. Superclusters of galaxies
• 445.370: Advanced Numerical Methods This lab deals with cubic splines and cubic Lagrange interpolation.
• MATHS370FC: Numerical Computation Assignment three
• Surfaces and surface integrals R(u, v) = x(u, v)i + y(u, v)j + z(u, v)k
• MATHS 370SC Advanced Numerical Methods 1. Use the QR method (version II) to find the eigenvalues of the matrix
• Non-cartesian coordinates 1 Introduction
• 445.370SC: Advanced Numerical Methods Assignment 2
• MATHS 340: Real and Complex Calculus Assignment one
• MATHS 370: Advanced Numerical Methods Partial differential equations
• Long initial value test problems from simulations of the Solar System
• Revision answers: easy, medium, difficult In this section I review material that will be used MATHS 340 and that you should have covered in