Calculus of Real and Complex Variables

6.10 Some Important Convergence Theorems

Chapter 1 Basic Notions

1.1 Sets And Set Notation

1.2 The Schroder Bernstein Theorem

1.3 Equivalence Relations

1.4 Well Ordering And Induction

1.5 The Complex Numbers And Fields

1.6 Polar Form Of Complex Numbers

1.7 Roots Of Complex Numbers

1.8 The Quadratic Formula

1.9 The Complex Exponential

1.10 The Cauchy Schwarz Inequality

1.11 Polynomials

1.12 The Fundamental Theorem Of Algebra

1.13 Some Topics From Analysis

1.14 lim sup and lim inf

1.15 Exercises

Chapter 2 Basic Topological and Algebraic Considerations

2.1 Closed and Open Sets

2.2 Compactness

2.2.1 Continuous Functions

2.2.2 Convergent Sequences

2.2.3 Continuity and the Limit of a Sequence

2.2.4 The Extreme Value Theorem and Uniform Continuity

2.2.5 Convergence of Functions

2.2.6 Multiplication of Series

2.2.7 The Distance to a Set

2.3 Tietze Extension Theorem

2.4 Root Test

2.5 Equivalence Of Norms

2.6 Norms On Linear Maps

2.7 Connected Sets

2.8 Stone Weierstrass Approximation Theorem

2.8.1 The Bernstein Polynomials

2.8.2 The Case Of Compact Sets

2.8.3 The Case Of A Closed Set in ℝn

2.8.4 The Case Of Complex Valued Functions

2.9 The Jordan Curve Theorem∗

2.10 Brouwer Fixed Point Theorem∗

2.10.1 Simplices And Triangulations

2.10.2 Labeling Vertices

2.10.3 The Brouwer Fixed Point Theorem

2.11 Exercises

Part II Real Analysis

Chapter 3 The Derivative, A Linear Transformation

3.1 Basic Definitions

3.2 The Chain Rule

3.3 The Matrix Of The Derivative

3.4 Existence Of The Derivative, C1 Functions

3.5 Mixed Partial Derivatives

3.6 Implicit Function Theorem

3.7 Invariance Of Domain∗

3.8 Exercises

Chapter 4 Line Integrals

4.1 Existence and Definition

4.1.1 Change of Parameter

4.1.2 Existence

4.1.3 The Riemann Integral

4.2 Estimates and Approximations

4.2.1 Finding the Length of a C1 Curve

4.2.2 Curves Defined in Pieces

4.2.3 A Physical Application, Work

4.3 Conservative Vector Fields

4.4 Orientation

4.5 Exercises

Chapter 5 Measures And Measurable Functions

5.1 Measurable Functions

5.2 Measures And Their Properties

5.3 Dynkin’s Lemma

5.4 Measures And Regularity

5.5 Measures And Outer Measures

5.6 Exercises

5.7 An Outer Measure On P (ℝ)

5.8 Measures From Outer Measures

5.9 When Is A Measure A Borel Measure?

5.10 One Dimensional Lebesgue Measure

5.11 Exercises

Chapter 6 The Abstract Lebesgue Integral

6.1 Definition For Nonnegative Measurable Functions

6.1.1 Riemann Integrals For Decreasing Functions

6.1.2 The Lebesgue Integral For Nonnegative Functions

6.2 The Lebesgue Integral For Nonnegative Simple Functions

6.3 The Monotone Convergence Theorem

6.4 Other Definitions

6.5 Fatou’s Lemma

6.6 The Integral’s Righteous Algebraic Desires

6.7 The Lebesgue Integral, L1

6.8 The Dominated Convergence Theorem

6.9 Product Measures

6.10 Some Important Convergence Theorems

6.10.1 Eggoroff’s Theorem

6.10.2 The Vitali Convergence Theorem

6.11 Exercises

Chapter 7 Basic Function Spaces

7.1 Bounded Continuous Functions

7.2 Compactness in C (K, ℝn)

7.3 The Lp Spaces

7.4 Approximation Theorems

7.5 A Useful Inequality

7.6 Uniform Convexity Of Lp

7.7 Exercises

Chapter 8 The Lebesgue Integral In ℝp

8.1 p Dimensional Lebesgue Measure And Integrals

8.2 Lebesgue Measure And Linear Transformations

8.3 Change of Variables for Nonlinear Maps

8.4 Mappings Which Are Not One To One

8.5 Spherical Coordinates In p Dimensions

8.6 Approximation with Smooth Functions

8.7 Continuity Of Translation

8.8 Separability

8.9 Exercises

Chapter 9 Differentiation

9.1 The Besicovitch Covering Theorem

9.2 Fundamental Theorem Of Calculus For Radon Measures

9.3 Vitali Coverings

9.4 Differentiation Of Radon Measures

9.5 The Radon Nikodym Theorem For Radon Measures

9.6 Change of Variables Again

9.7 Exercises

Chapter 10 Some Fundamental Functions and Transforms

10.1 Gamma Function

10.2 Laplace Transform

10.3 Fourier Transform

10.4 Fourier Transforms in ℝn

10.5 Fourier Transforms Of Just About Anything

10.5.1 Fourier Transforms in G∗

10.5.2 Fourier Transforms of Functions In L1 (ℝn)

10.5.3 Fourier Transforms of Functions In L2 (ℝn)

10.5.4 The Schwartz Class

10.5.5 Convolution

10.6 Exercises

Chapter 11 Degree Theory, An Introduction

11.1 Sard’s Lemma and Approximation

11.2 An Identity and Surprising Implications

11.3 Definitions And Elementary Properties

11.4 Borsuk’s Theorem

11.5 Applications

11.6 The Product Formula and Jordan Separation Theorem

11.7 Jordan Curve Theorem

11.8 Exercises

Chapter 12 Green’s Theorem

12.1 An Elementary Form of Green’s Theorem

12.2 Stoke’s Theorem

12.3 A General Green’s Theorem

12.4 Green’s Theorem for a Rectifiable Jordan Curve∗

12.5 Orientation of a Jordan Curve

Part III Abstract Analysis

Chapter 13 Banach Spaces

13.1 Theorems Based On Baire Category

13.1.1 Baire Category Theorem

13.1.2 Uniform Boundedness Theorem

13.1.3 Open Mapping Theorem

13.1.4 Closed Graph Theorem

13.2 Basic Theory of Hilbert Spaces

13.3 Hahn Banach Theorem

13.3.1 Partially Ordered Sets

13.3.2 Gauge Functions And Hahn Banach Theorem

13.3.3 The Complex Version Of The Hahn Banach Theorem

13.3.4 The Dual Space And Adjoint Operators

13.4 Exercises

Chapter 14 Representation Theorems

14.1 The Lebesgue Decomposition

14.2 Vector Measures

14.3 The Dual Space of Lp (Ω)

14.4 The Dual Space Of L∞(Ω)

14.5 Representations for Positive Linear Functionals on Cc (ℝp)

14.6 Representing a Radon Measure by Slicing

14.7 The Dual Space Of C0 (ℝp)

14.8 Exercises

Part IV Complex Analysis

Chapter 15 Fundamentals

15.1 Banach Spaces

15.2 The Cauchy Riemann Equations

15.3 Contour Integrals

15.4 Primitives and Cauchy Goursat Theorem

15.5 Functions Differentiable on a Disk, Zeros

15.6 The General Cauchy Integral Formula

15.7 Riemann sphere

15.8 Exercises

Chapter 16 Isolated Singularities and Analytic Functions

16.1 Open Mapping Theorem for Complex Valued Functions

16.2 Functions Analytic on an Annulus

16.3 The Complex Exponential and Winding Number

16.4 Cauchy Integral Formula for a Cycle

16.5 An Example of a Cycle

16.6 Isolated Singularities

16.7 The Residue Theorem

16.8 Evaluation of Improper Integrals

16.9 The Inversion of Laplace Transforms

16.10 Exercises

Chapter 17 Mapping Theorems

17.1 Meromorphic Functions

17.2 Meromorphic on Extended Complex Plane

17.3 Rouche’s Theorem

17.4 Fractional Linear Transformations

17.5 Some Examples

17.6 Riemann Mapping Theorem

17.6.1 Montel’s Theorem

17.6.2 Regions with Square Root Property

17.7 Exercises

Chapter 18 Spectral Theory of Linear Maps

18.1 The Resolvent and Spectral Radius

18.2 Functions of Linear Transformations

18.3 Invariant Subspaces

A.1 Systems of Equations

A.2 Matrices

A.3 Subspaces and Spans

A.4 Application to Matrices

A.5 Mathematical Theory of Determinants

A.5.1 The Function sgn

A.5.2 Determinants

A.5.3 Definition of Determinants

A.5.4 Permuting Rows or Columns

A.5.5 A Symmetric Definition

A.5.6 Alternating Property of the Determinant

A.5.7 Linear Combinations and Determinants

A.5.8 Determinant of a Product

A.5.9 Cofactor Expansions

A.5.10 Formula for the Inverse

A.5.11 Cramer’s Rule

A.5.12 Upper Triangular Matrices

A.6 Cayley-Hamilton Theorem

A.7 Eigenvalues and Eigenvectors of a Matrix

A.7.1 Definition of Eigenvectors and Eigenvalues

A.7.2 Triangular Matrices

A.7.3 Defective and Nondefective Matrices

A.7.4 Diagonalization

A.8 Schur’s Theorem

A.9 Hermitian Matrices

A.10 Right Polar Factorization

A.11 Direct Sums

A.12 Block Diagonal Matrices

B.1 The Hamel Basis

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