Raffi Hovasapian

n-Vector

Slide Duration:

Table of Contents

Section 1: Linear Equations and Matrices

Linear Systems

39m 3s

Intro

0:00

Linear Systems

1:20

Introduction to Linear Systems

1:21

Examples

10:35

Example 1

10:36

Example 2

13:44

Example 3

16:12

Example 4

23:48

Example 5

28:23

Example 6

32:32

Number of Solutions

35:08

One Solution, No Solution, Infinitely Many Solutions

35:09

Method of Elimination

36:57

Method of Elimination

36:58

Matrices

30m 34s

Intro

0:00

Matrices

0:47

Definition and Example of Matrices

0:48

Square Matrix

7:55

Diagonal Matrix

9:31

Operations with Matrices

10:35

Matrix Addition

10:36

Scalar Multiplication

15:01

Transpose of a Matrix

17:51

Matrix Types

23:17

Regular: m x n Matrix of m Rows and n Column

23:18

Square: n x n Matrix With an Equal Number of Rows and Columns

23:44

Diagonal: A Square Matrix Where All Entries OFF the Main Diagonal are '0'

24:07

Matrix Operations

24:37

Matrix Operations

24:38

Example

25:55

Example

25:56

Dot Product & Matrix Multiplication

41m 42s

Intro

0:00

Dot Product

1:04

Example of Dot Product

1:05

Matrix Multiplication

7:05

Definition

7:06

Example 1

12:26

Example 2

17:38

Matrices and Linear Systems

21:24

Matrices and Linear Systems

21:25

Example 1

29:56

Example 2

32:30

Summary

33:56

Dot Product of Two Vectors and Matrix Multiplication

33:57

Summary, cont.

35:06

Matrix Representations of Linear Systems

35:07

Examples

35:34

Examples

35:35

Properties of Matrix Operation

43m 17s

Intro

0:00

Properties of Addition

1:11

Properties of Addition: A

1:12

Properties of Addition: B

2:30

Properties of Addition: C

2:57

Properties of Addition: D

4:20

Properties of Addition

5:22

Properties of Addition

5:23

Properties of Multiplication

6:47

Properties of Multiplication: A

7:46

Properties of Multiplication: B

8:13

Properties of Multiplication: C

9:18

Example: Properties of Multiplication

9:35

Definitions and Properties (Multiplication)

14:02

Identity Matrix: n x n matrix

14:03

Let A Be a Matrix of m x n

15:23

Definitions and Properties (Multiplication)

18:36

Definitions and Properties (Multiplication)

18:37

Properties of Scalar Multiplication

22:54

Properties of Scalar Multiplication: A

23:39

Properties of Scalar Multiplication: B

24:04

Properties of Scalar Multiplication: C

24:29

Properties of Scalar Multiplication: D

24:48

Properties of the Transpose

25:30

Properties of the Transpose

25:31

Properties of the Transpose

30:28

Example

30:29

Properties of Matrix Addition

33:25

Let A, B, C, and D Be m x n Matrices

33:26

There is a Unique m x n Matrix, 0, Such That…

33:48

Unique Matrix D

34:17

Properties of Matrix Multiplication

34:58

Let A, B, and C Be Matrices of the Appropriate Size

34:59

Let A Be Square Matrix (n x n)

35:44

Properties of Scalar Multiplication

36:35

Let r and s Be Real Numbers, and A and B Matrices

36:36

Properties of the Transpose

37:10

Let r Be a Scalar, and A and B Matrices

37:12

Example

37:58

Example

37:59

Solutions of Linear Systems, Part 1

38m 14s

Intro

0:00

Reduced Row Echelon Form

0:29

An m x n Matrix is in Reduced Row Echelon Form If:

0:30

Reduced Row Echelon Form

2:58

Example: Reduced Row Echelon Form

2:59

Theorem

8:30

Every m x n Matrix is Row-Equivalent to a UNIQUE Matrix in Reduced Row Echelon Form

8:31

Systematic and Careful Example

10:02

Step 1

10:54

Step 2

11:33

Step 3

12:50

Step 4

14:02

Step 5

15:31

Step 6

17:28

Example

30:39

Find the Reduced Row Echelon Form of a Given m x n Matrix

30:40

Solutions of Linear Systems, Part II

28m 54s

Intro

0:00

Solutions of Linear Systems

0:11

Solutions of Linear Systems

0:13

Example I

3:25

Solve the Linear System 1

3:26

Solve the Linear System 2

14:31

Example II

17:41

Solve the Linear System 3

17:42

Solve the Linear System 4

20:17

Homogeneous Systems

21:54

Homogeneous Systems Overview

21:55

Theorem and Example

24:01

Inverse of a Matrix

40m 10s

Intro

0:00

Finding the Inverse of a Matrix

0:41

Finding the Inverse of a Matrix

0:42

Properties of Non-Singular Matrices

6:38

Practical Procedure

9:15

Step1

9:16

Step 2

10:10

Step 3

10:46

Example: Finding Inverse

12:50

Linear Systems and Inverses

17:01

Linear Systems and Inverses

17:02

Theorem and Example

21:15

Theorem

26:32

Theorem

26:33

List of Non-Singular Equivalences

28:37

Example: Does the Following System Have a Non-trivial Solution?

30:13

Example: Inverse of a Matrix

36:16

Section 2: Determinants

Determinants

21m 25s

Intro

0:00

Determinants

0:37

Introduction to Determinants

0:38

Example

6:12

Properties

9:00

Properties 1-5

9:01

Example

10:14

Properties, cont.

12:28

Properties 6 & 7

12:29

Example

14:14

Properties, cont.

18:34

Properties 8 & 9

18:35

Example

19:21

Cofactor Expansions

59m 31s

Intro

0:00

Cofactor Expansions and Their Application

0:42

Cofactor Expansions and Their Application

0:43

Example 1

3:52

Example 2

7:08

Evaluation of Determinants by Cofactor

9:38

Theorem

9:40

Example 1

11:41

Inverse of a Matrix by Cofactor

22:42

Inverse of a Matrix by Cofactor and Example

22:43

More Example

36:22

List of Non-Singular Equivalences

43:07

List of Non-Singular Equivalences

43:08

Example

44:38

Cramer's Rule

52:22

Introduction to Cramer's Rule and Example

52:23

Section 3: Vectors in Rn

Vectors in the Plane

46m 54s

Intro

0:00

Vectors in the Plane

0:38

Vectors in the Plane

0:39

Example 1

8:25

Example 2

15:23

Vector Addition and Scalar Multiplication

19:33

Vector Addition

19:34

Scalar Multiplication

24:08

Example

26:25

The Angle Between Two Vectors

29:33

The Angle Between Two Vectors

29:34

Example

33:54

Properties of the Dot Product and Unit Vectors

38:17

Properties of the Dot Product and Unit Vectors

38:18

Defining Unit Vectors

40:01

2 Very Important Unit Vectors

41:56

n-Vector

52m 44s

Intro

0:00

n-Vectors

0:58

4-Vector

0:59

7-Vector

1:50

Vector Addition

2:43

Scalar Multiplication

3:37

Theorem: Part 1

4:24

Theorem: Part 2

11:38

Right and Left Handed Coordinate System

14:19

Projection of a Point Onto a Coordinate Line/Plane

17:20

Example

21:27

Cauchy-Schwarz Inequality

24:56

Triangle Inequality

36:29

Unit Vector

40:34

Vectors and Dot Products

44:23

Orthogonal Vectors

44:24

Cauchy-Schwarz Inequality

45:04

Triangle Inequality

45:21

Example 1

45:40

Example 2

48:16

Linear Transformation

48m 53s

Intro

0:00

Introduction to Linear Transformations

0:44

Introduction to Linear Transformations

0:45

Example 1

9:01

Example 2

11:33

Definition of Linear Mapping

14:13

Example 3

22:31

Example 4

26:07

Example 5

30:36

Examples

36:12

Projection Mapping

36:13

Images, Range, and Linear Mapping

38:33

Example of Linear Transformation

42:02

Linear Transformations, Part II

34m 8s

Intro

0:00

Linear Transformations

1:29

Linear Transformations

1:30

Theorem 1

7:15

Theorem 2

9:20

Example 1: Find L (-3, 4, 2)

11:17

Example 2: Is It Linear?

17:11

Theorem 3

25:57

Example 3: Finding the Standard Matrix

29:09

Lines and Planes

37m 54s

Intro

0:00

Lines and Plane

0:36

Example 1

0:37

Example 2

7:07

Lines in IR3

9:53

Parametric Equations

14:58

Example 3

17:26

Example 4

20:11

Planes in IR3

25:19

Example 5

31:12

Example 6

34:18

Section 4: Real Vector Spaces

Vector Spaces

42m 19s

Intro

0:00

Vector Spaces

3:43

Definition of Vector Spaces

3:44

Vector Spaces 1

5:19

Vector Spaces 2

9:34

Real Vector Space and Complex Vector Space

14:01

Example 1

15:59

Example 2

18:42

Examples

26:22

More Examples

26:23

Properties of Vector Spaces

32:53

Properties of Vector Spaces Overview

32:54

Property A

34:31

Property B

36:09

Property C

36:38

Property D

37:54

Property F

39:00

Subspaces

43m 37s

Intro

0:00

Subspaces

0:47

Defining Subspaces

0:48

Example 1

3:08

Example 2

3:49

Theorem

7:26

Example 3

9:11

Example 4

12:30

Example 5

16:05

Linear Combinations

23:27

Definition 1

23:28

Example 1

25:24

Definition 2

29:49

Example 2

31:34

Theorem

32:42

Example 3

34:00

Spanning Set for a Vector Space

33m 15s

Intro

0:00

A Spanning Set for a Vector Space

1:10

A Spanning Set for a Vector Space

1:11

Procedure to Check if a Set of Vectors Spans a Vector Space

3:38

Example 1

6:50

Example 2

14:28

Example 3

21:06

Example 4

22:15

Linear Independence

17m 20s

Intro

0:00

Linear Independence

0:32

Definition

0:39

Meaning

3:00

Procedure for Determining if a Given List of Vectors is Linear Independence or Linear Dependence

5:00

Example 1

7:21

Example 2

10:20

Basis & Dimension

31m 20s

Intro

0:00

Basis and Dimension

0:23

Definition

0:24

Example 1

3:30

Example 2: Part A

4:00

Example 2: Part B

6:53

Theorem 1

9:40

Theorem 2

11:32

Procedure for Finding a Subset of S that is a Basis for Span S

14:20

Example 3

16:38

Theorem 3

21:08

Example 4

25:27

Homogeneous Systems

24m 45s

Intro

0:00

Homogeneous Systems

0:51

Homogeneous Systems

0:52

Procedure for Finding a Basis for the Null Space of Ax = 0

2:56

Example 1

7:39

Example 2

18:03

Relationship Between Homogeneous and Non-Homogeneous Systems

19:47

Rank of a Matrix, Part I

35m 3s

Intro

0:00

Rank of a Matrix

1:47

Definition

1:48

Theorem 1

8:14

Example 1

9:38

Defining Row and Column Rank

16:53

If We Want a Basis for Span S Consisting of Vectors From S

22:00

If We want a Basis for Span S Consisting of Vectors Not Necessarily in S

24:07

Example 2: Part A

26:44

Example 2: Part B

32:10

Rank of a Matrix, Part II

29m 26s

Intro

0:00

Rank of a Matrix

0:17

Example 1: Part A

0:18

Example 1: Part B

5:58

Rank of a Matrix Review: Rows, Columns, and Row Rank

8:22

Procedure for Computing the Rank of a Matrix

14:36

Theorem 1: Rank + Nullity = n

16:19

Example 2

17:48

Rank & Singularity

20:09

Example 3

21:08

Theorem 2

23:25

List of Non-Singular Equivalences

24:24

List of Non-Singular Equivalences

24:25

Coordinates of a Vector

27m 3s

Intro

0:00

Coordinates of a Vector

1:07

Coordinates of a Vector

1:08

Example 1

8:35

Example 2

15:28

Example 3: Part A

19:15

Example 3: Part B

22:26

Change of Basis & Transition Matrices

33m 47s

Intro

0:00

Change of Basis & Transition Matrices

0:56

Change of Basis & Transition Matrices

0:57

Example 1

10:44

Example 2

20:44

Theorem

23:37

Example 3: Part A

26:21

Example 3: Part B

32:05

Orthonormal Bases in n-Space

32m 53s

Intro

0:00

Orthonormal Bases in n-Space

1:02

Orthonormal Bases in n-Space: Definition

1:03

Example 1

4:31

Theorem 1

6:55

Theorem 2

8:00

Theorem 3

9:04

Example 2

10:07

Theorem 2

13:54

Procedure for Constructing an O/N Basis

16:11

Example 3

21:42

Orthogonal Complements, Part I

21m 27s

Intro

0:00

Orthogonal Complements

0:19

Definition

0:20

Theorem 1

5:36

Example 1

6:58

Theorem 2

13:26

Theorem 3

15:06

Example 2

18:20

Orthogonal Complements, Part II

33m 49s

Intro

0:00

Relations Among the Four Fundamental Vector Spaces Associated with a Matrix A

2:16

Four Spaces Associated With A (If A is m x n)

2:17

Theorem

4:49

Example 1

7:17

Null Space and Column Space

10:48

Projections and Applications

16:50

Projections and Applications

16:51

Projection Illustration

21:00

Example 1

23:51

Projection Illustration Review

30:15

Section 5: Eigenvalues and Eigenvectors

Eigenvalues and Eigenvectors

38m 11s

Intro

0:00

Eigenvalues and Eigenvectors

0:38

Eigenvalues and Eigenvectors

0:39

Definition 1

3:30

Example 1

7:20

Example 2

10:19

Definition 2

21:15

Example 3

23:41

Theorem 1

26:32

Theorem 2

27:56

Example 4

29:14

Review

34:32

Similar Matrices & Diagonalization

29m 55s

Intro

0:00

Similar Matrices and Diagonalization

0:25

Definition 1

0:26

Example 1

2:00

Properties

3:38

Definition 2

4:57

Theorem 1

6:12

Example 3

9:37

Theorem 2

12:40

Example 4

19:12

Example 5

20:55

Procedure for Diagonalizing Matrix A: Step 1

24:21

Procedure for Diagonalizing Matrix A: Step 2

25:04

Procedure for Diagonalizing Matrix A: Step 3

25:38

Procedure for Diagonalizing Matrix A: Step 4

27:02

Diagonalization of Symmetric Matrices

30m 14s

Intro

0:00

Diagonalization of Symmetric Matrices

1:15

Diagonalization of Symmetric Matrices

1:16

Theorem 1

2:24

Theorem 2

3:27

Example 1

4:47

Definition 1

6:44

Example 2

8:15

Theorem 3

10:28

Theorem 4

12:31

Example 3

18:00

Section 6: Linear Transformations

Linear Mappings Revisited

24m 5s

Intro

0:00

Linear Mappings

2:08

Definition

2:09

Linear Operator

7:36

Projection

8:48

Dilation

9:40

Contraction

10:07

Reflection

10:26

Rotation

11:06

Example 1

13:00

Theorem 1

18:16

Theorem 2

19:20

Kernel and Range of a Linear Map, Part I

26m 38s

Intro

0:00

Kernel and Range of a Linear Map

0:28

Definition 1

0:29

Example 1

4:36

Example 2

8:12

Definition 2

10:34

Example 3

13:34

Theorem 1

16:01

Theorem 2

18:26

Definition 3

21:11

Theorem 3

24:28

Kernel and Range of a Linear Map, Part II

25m 54s

Intro

0:00

Kernel and Range of a Linear Map

1:39

Theorem 1

1:40

Example 1: Part A

2:32

Example 1: Part B

8:12

Example 1: Part C

13:11

Example 1: Part D

14:55

Theorem 2

16:50

Theorem 3

23:00

Matrix of a Linear Map

33m 21s

Intro

0:00

Matrix of a Linear Map

0:11

Theorem 1

1:24

Procedure for Computing to Matrix: Step 1

7:10

Procedure for Computing to Matrix: Step 2

8:58

Procedure for Computing to Matrix: Step 3

9:50

Matrix of a Linear Map: Property

10:41

Example 1

14:07

Example 2

18:12

Example 3

24:31