Presentation is loading. Please wait.

Presentation is loading. Please wait.

§3.3. 1 Separation of Cartesian variables: Orthogonal functions Christopher Crawford PHY 311 2014-02-24.

Published byGerard Hampton Modified over 8 years ago

Similar presentations

Presentation on theme: "§3.3. 1 Separation of Cartesian variables: Orthogonal functions Christopher Crawford PHY 311 2014-02-24."— Presentation transcript:

1 §3.3. 1 Separation of Cartesian variables: Orthogonal functions Christopher Crawford PHY 311 2014-02-24

2 Outline Analogies from Chapter 1 Inner, outer products Projections, eigenstuff Example boundary value problem – square box Separation of variables Solution of boundary conditions Discrete vs. continuous linear spaces Basis, components; index notation Inner product; orthogonal projection; rotations Eigenvalues – Sturm-Liouville theorem 2

3 Analogies from Chapter 1 Inner vs. outer product – projections & components Linear operators – stretches & rotations 3

4 Separation of variables technique Goal: solve Laplace’s equation (PDE) by converting it into one ODE per variable Method: separate the equation into separate terms in x, y, z start with factored solution V(x,y,z) = X(x) Y(y) Z(z) Trick: if f (x) = g (y) then they both must be constant Endgame: form the most general solution possible as a linear combination of single-variable solutions. Solve for coefficients using the boundary conditions. Trick 2: use orthogonal functions to project out coefficients Analogy: the set of all solutions forms a vector space the basis vectors are independent individual solutions 4

5 Example: rectangular box Boundary value problem: Laplace equation 5

6 Example: rectangular box 6 Boundary value problem: Boundary conditions 6

7 Example: rectangular box Boundary value problem: Laplace equation 7

8 Example: rectangular box 8 Boundary value problem: Boundary conditions 8

9 Vectors vs. Functions 9

10 10

11 Vectors vs. Functions 11

12 Sturm-Liouville Theorem Laplacian (self-adjoint) has orthogonal eigenfunctions – This is true in any orthogonal coordinate system! Sturm-Liouville operator – eigenvalue problem 12

Download ppt "§3.3. 1 Separation of Cartesian variables: Orthogonal functions Christopher Crawford PHY 311 2014-02-24."

Similar presentations

Quantum One: Lecture 5a. Normalization Conditions for Free Particle Eigenstates.

Quantum One: Lecture 5a. Normalization Conditions for Free Particle Eigenstates.
EEE340Lecture 171 The E-field and surface charge density are And (4.15)

EEE340Lecture 171 The E-field and surface charge density are And (4.15)
Chapter 2 Section 2 Solving a System of Linear Equations II.

Chapter 2 Section 2 Solving a System of Linear Equations II.
Chapter 3 Determinants and Matrices

Chapter 3 Determinants and Matrices
Math for CSLecture 131 Contents Partial Differential Equations Sturm-Liuville Problem Laplace Equation for 3D sphere Legandre Polynomials Lecture/Tutorial13.

Math for CSLecture 131 Contents Partial Differential Equations Sturm-Liuville Problem Laplace Equation for 3D sphere Legandre Polynomials Lecture/Tutorial13.
Boyce/DiPrima 9th ed, Ch 11.2: Sturm-Liouville Boundary Value Problems Elementary Differential Equations and Boundary Value Problems, 9th edition, by.

Boyce/DiPrima 9th ed, Ch 11.2: Sturm-Liouville Boundary Value Problems Elementary Differential Equations and Boundary Value Problems, 9th edition, by.
Introduction: We are going to study a standard second order ODE called the Sturm-Liouville ODE. The solution of this ODE form a function space, or Hilbert.

Introduction: We are going to study a standard second order ODE called the Sturm-Liouville ODE. The solution of this ODE form a function space, or Hilbert.
Linear Algebra, Principal Component Analysis and their Chemometrics Applications.

Linear Algebra, Principal Component Analysis and their Chemometrics Applications.
PHYS 218 sec. 517-520 Review Chap. 1. Caution This presentation is to help you understand the contents of the textbook. Do not rely on this review for.

PHYS 218 sec Review Chap. 1. Caution This presentation is to help you understand the contents of the textbook. Do not rely on this review for.
1Chapter 2. 2 Example 3Chapter 2 4 EXAMPLE 5Chapter 2.

1Chapter 2. 2 Example 3Chapter 2 4 EXAMPLE 5Chapter 2.
Copy and complete using a review term from the list below.

Copy and complete using a review term from the list below.
Solving quadratic equations Factorisation Type 1: No constant term Solve x 2 – 6x = 0 x (x – 6) = 0 x = 0 or x – 6 = 0 Solutions: x = 0 or x = 6 Graph.

Solving quadratic equations Factorisation Type 1: No constant term Solve x 2 – 6x = 0 x (x – 6) = 0 x = 0 or x – 6 = 0 Solutions: x = 0 or x = 6 Graph.
Differential Equations Brannan Copyright © 2010 by John Wiley & Sons, Inc. All rights reserved. Chapter 10: Boundary Value Problems and Sturm– Liouville.

Differential Equations Brannan Copyright © 2010 by John Wiley & Sons, Inc. All rights reserved. Chapter 10: Boundary Value Problems and Sturm– Liouville.
Lecture 9 Particle in a rectangular well (c) So Hirata, Department of Chemistry, University of Illinois at Urbana-Champaign. This material has been developed.

Lecture 9 Particle in a rectangular well (c) So Hirata, Department of Chemistry, University of Illinois at Urbana-Champaign. This material has been developed.
Chemistry 330 The Mathematics Behind Quantum Mechanics.

Chemistry 330 The Mathematics Behind Quantum Mechanics.
§3.3. 2 Separation of spherical variables: zonal harmonics Christopher Crawford PHY 416 2014-10-29.

§ Separation of spherical variables: zonal harmonics Christopher Crawford PHY
Boyce/DiPrima 9 th ed, Ch 11.5: Further Remarks on Separation of Variables: A Bessel Series Expansion Elementary Differential Equations and Boundary Value.

Boyce/DiPrima 9 th ed, Ch 11.5: Further Remarks on Separation of Variables: A Bessel Series Expansion Elementary Differential Equations and Boundary Value.
CHAPTER 3 TWO-DIMENSIONAL STEADY STATE CONDUCTION

CHAPTER 3 TWO-DIMENSIONAL STEADY STATE CONDUCTION
Chapter 8 Partial Differential Equation. 8.1 Introduction Independent variables Formulation Boundary conditions Compounding & Method of Image Separation.

Chapter 8 Partial Differential Equation. 8.1 Introduction Independent variables Formulation Boundary conditions Compounding & Method of Image Separation.
1. Inverse of A 2. Inverse of a 2x2 Matrix 3. Matrix With No Inverse 4. Solving a Matrix Equation 1.

1. Inverse of A 2. Inverse of a 2x2 Matrix 3. Matrix With No Inverse 4. Solving a Matrix Equation 1.

Similar presentations

Ads by Google