Presentation is loading. Please wait.

Presentation is loading. Please wait.

MAT 3237 Differential Equations Section 18.4 Series Solutions Part I

Published byStephany Lynch Modified over 8 years ago

Similar presentations

Presentation on theme: "MAT 3237 Differential Equations Section 18.4 Series Solutions Part I"— Presentation transcript:

1 MAT 3237 Differential Equations Section 18.4 Series Solutions Part I http://myhome.spu.edu/lauw

2 HW No WebAssign Do18.4 #1 Do not turn in

3 Why Power Series Solutions? Many DE cannot be solved explicitly in terms of finite combinations of elementary functions.

4 Example Quantum Mechanics

5 Example Quantum Mechanics

6 Extract Information (e.g. from Approximation) Quantum Mechanics

7 Review Power Series Differentiate Power Series

8 Recall: Index Shifting Rules

9 decrease the index by 1 increase the i in the summation by 1

10 Recall: Index Shifting Rules increase the index by 1 decrease the i in the summation by 1

11 Example

12 Definition A Power Series is of the form

13

14 Theorem (Identity Property)

15 Theorem

16

17

18 Example 1 Solve the following DE by power series

19 Example 1 Solve the following DE by power series

20 Expectation

21 Summary To combine the summations, we need same power of x and same index ranges Use different representations of the derivative index shifting Find the relationship between the coefficients and look for patterns do not “collapse” numbers The lowest coefficient(s) remains (fix by I.C.)

Download ppt "MAT 3237 Differential Equations Section 18.4 Series Solutions Part I"

Similar presentations

THE DERIVATIVE AND THE TANGENT LINE PROBLEM

THE DERIVATIVE AND THE TANGENT LINE PROBLEM
Ch 3.6: Variation of Parameters

Ch 3.6: Variation of Parameters
Ch 5.5: Series Solutions Near a Regular Singular Point, Part I We now consider solving the general second order linear equation in the neighborhood of.

Ch 5.5: Series Solutions Near a Regular Singular Point, Part I We now consider solving the general second order linear equation in the neighborhood of.
Ch 5.1: Review of Power Series Finding the general solution of a linear differential equation depends on determining a fundamental set of solutions of.

Ch 5.1: Review of Power Series Finding the general solution of a linear differential equation depends on determining a fundamental set of solutions of.
Bogazici University Dept. Of ME. Laplace Transforms Very useful in the analysis and design of LTI systems. Operations of differentiation and integration.

Bogazici University Dept. Of ME. Laplace Transforms Very useful in the analysis and design of LTI systems. Operations of differentiation and integration.
EXPONENTIAL FUNCTIONS: DIFFERENTIATION AND INTEGRATION Section 5.4.

EXPONENTIAL FUNCTIONS: DIFFERENTIATION AND INTEGRATION Section 5.4.
Section 6.1: Euler’s Method. Local Linearity and Differential Equations Slope at (2,0): Tangent line at (2,0): Not a good approximation. Consider smaller.

Section 6.1: Euler’s Method. Local Linearity and Differential Equations Slope at (2,0): Tangent line at (2,0): Not a good approximation. Consider smaller.
MAT 1236 Calculus III Section 14.5 The Chain Rule

MAT 1236 Calculus III Section 14.5 The Chain Rule
(MTH 250) Lecture 24 Calculus. Previous Lecture’s Summary Multivariable functions Limits along smooth curves Limits of multivariable functions Continuity.

(MTH 250) Lecture 24 Calculus. Previous Lecture’s Summary Multivariable functions Limits along smooth curves Limits of multivariable functions Continuity.
Chapter 3: The Laplace Transform

Chapter 3: The Laplace Transform
The Natural Logarithmic Function

The Natural Logarithmic Function
Arithmetic Sequences and Series

Arithmetic Sequences and Series
NONLINEAR SYSTEMS, CONIC SECTIONS, SEQUENCES, AND SERIES College Algebra.

NONLINEAR SYSTEMS, CONIC SECTIONS, SEQUENCES, AND SERIES College Algebra.
Additional Topics in Differential Equations

Additional Topics in Differential Equations
SECOND-ORDER DIFFERENTIAL EQUATIONS 17. 17.4 Series Solutions SECOND-ORDER DIFFERENTIAL EQUATIONS In this section, we will learn how to solve: Certain.

SECOND-ORDER DIFFERENTIAL EQUATIONS Series Solutions SECOND-ORDER DIFFERENTIAL EQUATIONS In this section, we will learn how to solve: Certain.
Section 5.3 – The Definite Integral

Section 5.3 – The Definite Integral
Copyright © Cengage Learning. All rights reserved. 17 Second-Order Differential Equations.

Copyright © Cengage Learning. All rights reserved. 17 Second-Order Differential Equations.
Sequences Definition - A function whose domain is the set of all positive integers. Finite Sequence - finite number of values or elements Infinite Sequence.

Sequences Definition - A function whose domain is the set of all positive integers. Finite Sequence - finite number of values or elements Infinite Sequence.
Copyright © 2007 Pearson Education, Inc. Publishing as Pearson Prentice Hall Antiderivatives and Slope Fields Section 6.1.

Copyright © 2007 Pearson Education, Inc. Publishing as Pearson Prentice Hall Antiderivatives and Slope Fields Section 6.1.
MAT 1236 Calculus III Appendix E Sigma Notations + Maple Lab

MAT 1236 Calculus III Appendix E Sigma Notations + Maple Lab

Similar presentations

Ads by Google