11210 工程數學一

# Required Courses # Undergraduate Program

7 Lectures / 54 Sections / 29h 55m 56s

Lecture 1：Course Introduction

Section 1

35:43

Lecture 2：First-Order Ordinary Differential Equations (ODEs)

Section 1

Separable Ordinary Differential Equation

27:59

Section 2

Separable Ordinary Differential Equation (continued)

33:28

Section 3

Exact Differential Equation, Integrating Factor

49:49

Section 4

Integrating Factors

39:48

Section 5

Linear ODEs, Hormone Level

43:30

Section 6

Bernoulli Equation

10:15

Section 7

Existence Theorem

29:15

Section 8

Uniqueness Theorem

10:01

Lecture 3：Second-Order Linear ODEs

Section 1

Homogeneous Linear ODEs of Second Order, Foundamental Theorem, Initial/Boundary Value Problem18

30:07

Section 2

Initial Value Problem and Basis General Solution

41:48

Section 3

Solve Homogeneous Linear ODEs with Constant Coeff. by Algebra

48:04

Section 4

Solve Homogeneous Linear ODEs with Constant Coeff. by Algebra (continued), Introduction of Euler Formula

33:16

Section 5

Form of Euler-Cauchy Equations

11:03

Section 6

Roots of Euler-Cauchy Equations

35:55

Section 7

Existence & Uniqueness of Solutions

17:27

Section 8

Form of Nonhomogeneous ODEs of 2nd Order, Methods of Undetermined Coefficients (Basic rule)

43:54

Section 9

Methods of Undetermined Coefficients (Modification Rule and Sum rule)

39:07

Section 10

Solution by Variation of Parameters (by Lagrange's), Definition of Wronskian

10:08

Section 11

An Example of Variation of Parameters

07:31

Lecture 4：Higher Order ODEs

Section 1

Homogeneous Linear ODEs

37:50

Section 2

Homogeneous Linear ODEs (continued)

19:29

Section 3

Nonhomogeneous Linear ODEs

24:47

Lecture 5：Systems of ODE

Section 1

Theory of Systems of Linear 1st order Differential Equations

01:27:34

Section 2

Introduction of Eigenvalues and Eigenvectors

41:09

Section 3

Solutions of X'=AX when A is constant

46:56

Section 4

Method of Finding Eigenvalues and Eigenvectors

13:34

Section 5

Solutions of X'=AX when A has complex eigenvalues

40:57

Section 6

Solutions of X'=AX when A does not have n linearly independent Eigenvectors

58:52

Section 7

Solutions of X'=AX+G

38:25

Section 8

Solution of X'=AX by Diagonalizing A

47:24

Section 9

Solution of X'=AX+G by Diagonalizing A

36:18

Lecture 6：Laplace Transform

Section 1

16:41

Section 2

Laplace Transform (Linearity, 1st Shifting Theorem)

38:12

Section 3

Laplace Transform (Linearity, 1st Shifting Theorem) (continued)

17:13

Section 4

Laplace Transform of Derivatives and Integrals

29:20

Section 5

Solve the Differential Equations, IVP

44:31

Section 6

Solve the Differential Equations, IVP (continued)

21:19

Section 7

Unit Step Function (Heaviside Function), Second Shifting Theorem

29:49

Section 8

Second Shifting Theorem (continued)

19:13

Section 9

Short Impulses, Dirac's Delta Function

16:58

Section 10

11:54

Section 11

Convolution (continued)

27:07

Lecture 7：Series Solution of ODEs

Section 1

Power Series Method

28:12

Section 2

Power Series Method (continued)

53:51

Section 3

Power Series Method (continued)

14:17

Section 4

Legendre's Equation, Legendre Polynomials

32:26

Section 5

Legendre's Equation, Legendre Polynomials (continued)

43:09

Section 6

Extended Power Series Method: Frobenius Method

45:22

Section 7

Extended Power Series Method: Frobenius Method (continued)

47:18

Section 8

Extended Power Series Method: Frobenius Method (continued)

40:38

Section 9

Bessel's Equation, Bessel's Functions

46:18

Section 10

Bessel's Equation, Bessel's Functions (continued)

48:25

Section 11

Bessel's Equation (General Solution & Linear Independence)

32:20

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Introduction

Duration｜ 29h 55m 56s

Total Lectures｜ 7 Lectures 54 Sections

Brief course descriptions

Engineering Mathematics is a required course for the Department of Chemical Engineering, taught over two semesters. It covers the mathematical foundations necessary for specialized chemical engineering subjects, such as Transport Phenomena, Reaction Engineering, and Process Control. Topics include Ordinary Differential Equations (ODE), Linear Algebra, Vector Calculus, Fourier Analysis, and Partial Differential Equations (PDE), with examples drawn from chemical engineering applications whenever possible. The content of Engineering Mathematics (I) includes first-order, second-order, and higher-order ODEs and their solutions; systems of first-order ODEs; Laplace Transforms and their applications; Power Series Solutions; and Sturm-Liouville problems.

Course keywords

工程數學(Engineering Mathematics), 常微分方程式(Ordinary Differential Equation), 拉普拉斯轉換(Laplace Transform), 冪級數解(Power Series Solution), 斯圖姆-劉維爾問題(Sturm-Liouville Problem)

Textbook

Advanced Engineering Mathematics, E. Kreyszig, 10th edition Update (2018).

Course Topics

Topic 1 (Ch1) – First-Order Ordinary Differential Equations (ODEs)
Topic 2 (Ch2) – Second-Order Linear ODEs
Topic 3 (Ch3) – Higher-Order Linear ODEs
Topic 4 (Ch4) – Systems of ODEs, Phase Plane, Qualitative Methods
Topic 5 (Ch6) – Laplace Transforms
Topic 6 (Ch5) – Series Solutions of ODEs, Special Functions

Lectures

Lecture 1：Course Introduction

Section 1 - Overall View

35:43

Lecture 2：First-Order Ordinary Differential Equations (ODEs)

Section 1 - Separable Ordinary Differential Equation

27:59

Section 2 - Separable Ordinary Differential Equation (continued)

33:28

Section 3 - Exact Differential Equation, Integrating Factor

49:49

Section 4 - Integrating Factors

39:48

Section 5 - Linear ODEs, Hormone Level

43:30

Section 6 - Bernoulli Equation

10:15

Section 7 - Existence Theorem

29:15

Section 8 - Uniqueness Theorem

10:01

Lecture 3：Second-Order Linear ODEs

Section 1 - Homogeneous Linear ODEs of Second Order, Foundamental Theorem, Initial/Boundary Value Problem18

30:07

Section 2 - Initial Value Problem and Basis General Solution

41:48

Section 3 - Solve Homogeneous Linear ODEs with Constant Coeff. by Algebra

48:04

Section 4 - Solve Homogeneous Linear ODEs with Constant Coeff. by Algebra (continued), Introduction of Euler Formula

33:16

Section 5 - Form of Euler-Cauchy Equations

11:03

Section 6 - Roots of Euler-Cauchy Equations

35:55

Section 7 - Existence & Uniqueness of Solutions

17:27

Section 8 - Form of Nonhomogeneous ODEs of 2nd Order, Methods of Undetermined Coefficients (Basic rule)

43:54

Section 9 - Methods of Undetermined Coefficients (Modification Rule and Sum rule)

39:07

Section 10 - Solution by Variation of Parameters (by Lagrange's), Definition of Wronskian

10:08

Section 11 - An Example of Variation of Parameters

07:31

Lecture 4：Higher Order ODEs

Section 1 - Homogeneous Linear ODEs

37:50

Section 2 - Homogeneous Linear ODEs (continued)

19:29

Section 3 - Nonhomogeneous Linear ODEs

24:47

Lecture 5：Systems of ODE

Section 1 - Theory of Systems of Linear 1st order Differential Equations

01:27:34

Section 2 - Introduction of Eigenvalues and Eigenvectors

41:09

Section 3 - Solutions of X'=AX when A is constant

46:56

Section 4 - Method of Finding Eigenvalues and Eigenvectors

13:34

Section 5 - Solutions of X'=AX when A has complex eigenvalues

40:57

Section 6 - Solutions of X'=AX when A does not have n linearly independent Eigenvectors

58:52

Section 7 - Solutions of X'=AX+G

38:25

Section 8 - Solution of X'=AX by Diagonalizing A

47:24

Section 9 - Solution of X'=AX+G by Diagonalizing A

36:18

Lecture 6：Laplace Transform

Section 1 - Introduction

16:41

Section 2 - Laplace Transform (Linearity, 1st Shifting Theorem)

38:12

Section 3 - Laplace Transform (Linearity, 1st Shifting Theorem) (continued)

17:13

Section 4 - Laplace Transform of Derivatives and Integrals

29:20

Section 5 - Solve the Differential Equations, IVP

44:31

Section 6 - Solve the Differential Equations, IVP (continued)

21:19

Section 7 - Unit Step Function (Heaviside Function), Second Shifting Theorem

29:49

Section 8 - Second Shifting Theorem (continued)

19:13

Section 9 - Short Impulses, Dirac's Delta Function

16:58

Section 10 - Convolution

11:54

Section 11 - Convolution (continued)

27:07

Lecture 7：Series Solution of ODEs

Section 1 - Power Series Method

28:12

Section 2 - Power Series Method (continued)

53:51

Section 3 - Power Series Method (continued)

14:17

Section 4 - Legendre's Equation, Legendre Polynomials

32:26

Section 5 - Legendre's Equation, Legendre Polynomials (continued)

43:09

Section 6 - Extended Power Series Method: Frobenius Method

45:22

Section 7 - Extended Power Series Method: Frobenius Method (continued)

47:18

Section 8 - Extended Power Series Method: Frobenius Method (continued)

40:38

Section 9 - Bessel's Equation, Bessel's Functions

46:18

Section 10 - Bessel's Equation, Bessel's Functions (continued)

48:25

Section 11 - Bessel's Equation (General Solution & Linear Independence)

32:20

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Prof. Pan Yung-Tin (Frank)

Dept. Chemical Engineering

Research Field

Fuel Cell Electrode Catalyst, Gas Phase Electrochemical Reactions and its Catalyst, In-Situ Operando Study of Energy Materials

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