最优化导论（英文版）_顺盈平台官方指定注册站

最优化导论（英文版）

信息来源：网络时间：2024-04-29 03:38

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最优化是在20世纪得到快速发展的一门学科。本书介绍了最优化理论及其在经济学和相关学科中的应用，全书共分三个部分。第一部分研究了Rn中最优化问题的解的存在性以及如何确定这些解，第二部分探讨了最优化问题的解如何随着基本参数的变化而变化，最后一部分描述了有限维和无限维的动态规划。另外，还给出基础知识准备一章和三个附录，使得本书自成体系。

本书适合于高等院校经济学、工商管理、保险学、精算学等专业高年级本科生和研究生参考。^[1]

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Contents

1　Mathematical Preliminaries　1

1.1　Notation and Preliminary Definitions　2

1.1.1　Integers, Rationals, Reals, Rn　2

1.1.2　Inner Product, Norm, Metric　4

1.2　Sets and Sequences in Rn　7

1.2.1　Sequences and Limits　7

1.2.2　Subsequences and Limit Points　10

1.2.3　Cauchy Sequences and Completeness　11

1.2.4　Suprema, Infima, Maxima, Minima　14

1.2.5　Monotone Sequences in R　17

1.2.6　The Lim Sup and Lira Inf　18

1.2.7　Open Balls, Open Sets, Closed Sets　22

1.2.8　Bounded Sets and Compact Sets　23

1.2.9　Convex Combinations and Convex Sets　23

1.2.10　Unions, Intersections, and Other Binary Operations　24

1.3　Matrices　30

1.3.1　Sum, Product, Transpose　30

1.3.2　Some Important Classes of Matrices　32

1.3.3　Rank of a Matrix　33

1.3.4　The Determinant　35

1.3.5　The Inverse　38

1.3.6　Calculating the Determinant　39

1.4　Functions　41

1.4.1　Continuous Functions　41

1.4.2　Differentiable and Continuously Differentiable Functions　43

1.4.3　Partial Derivatives and Differentiability　46

1.4.4　Directional Derivatives and Differentiability　48

1.4.5　Higher Order Derivatives　49

1.5　Quadratic Forms: Definite and Semidefinite Matrices　50

1.5.1　Quadratic Forms and Definiteness　50

1.5.2　Identifying Definiteness and Semidefiniteness　53

1.6　Some Important Results　55

1.6.1　Separation Theorems　56

1.6.2　The Intermediate and Mean Value Theorems　60

1.6.3　The Inverse and Implicit Function Theorems　65

1.7　Exercises　66

2　Optimization in Rn　74

2.1　Optimization Problems in Rn　74

2.2　Optimization Problems in Parametric Form　77

2.3　Optimization Problems: Some Examples　78

2.3.1　Utility Maximization　78

2.3.2　Expenditure Minimization　79

2.3.3　Profit Maximization　80

2.3.4　Cost Minimization　80

2.3.5　Consumption-Leisure Choice　81

2.3.6　Portfolio Choice　81

2.3.7　Identifying Pareto Optima　82

2.3.8　Optimal Provision of Public Goods　83

2.3.9　Optimal Commodity Taxation　84

2.4　Objectives of Optimization Theory　85

2.5　A Roadmap　86

2.6　Exercises　88

3　Existence of Solutions: The Weierstrass Theorem　90

3.1　The Weierstrass Theorem　90

3.2　The Weierstrass Theorem in Applications　92

3.3　A Proof of the Weierstrass Theorem　96

3.4　Exercises　97

4　Unconstrained Optima　100

4.1　 ""Unconstrained"" Optima　100

4.2　First-Order Conditions　101

4.3　Second-Order Conditions　103

4.4　Using the First- and Second-Order Conditions　104

4.5　A Proof of the First-Order Conditions　106

4.6　A Proof of the Second-Order Conditions　108

4.7　Exercises　110

5　Equality Constraints and the Theorem of Lagrange　112

5.1　Constrained Optimization Problems　112

5.2　Equality Constraints and the Theorem of Lagrange　113

5.2.1　Statement of the Theorem　114

5.2.2　The Constraint Qualification　115

5.2.3　The Lagrangean Multipliers　116

5.3　Second-Order Conditions　117

5.4　Using the Theorem of Lagrange　121

5.4.1　A ""Cookbook"" Procedure　121

5.4.2　Why the Procedure Usually Works　122

5.4.3　When It Could Fail　123

5.4.4　A Numerical Example　127

5.5　Two Examples from Economics　128

5.5.1　An Illustration from Consumer Theory　128

5.5.2　An Illustration from Producer Theory　130

5.5.3　Remarks　132

5.6　A Proof of the Theorem of Lagrange　135

5.7　A Proof of the Second-Order Conditions　137

5.8　Exercises　142

6　Inequality Constraints and the Theorem of Kuhn and Tucker　145

6.1　The Theorem of Kuhn and Tucker　145

6.1.1　Statement of the Theorem　145

6.1.2　The Constraint Qualification　147

6.1.3　The Kuhn-Tucker Multipliers　148

6.2　Using the Theorem of Kuhn and Tucker　150

6.2.1　A Cookbook' Procedure　150

6.2.2　Why the Procedure Usually Works　151

6.2.3　When It Could Fail　152

6.2.4　A Numerical Example　155

6.3　Illustrations from Economics　157

6.3.1　An Illustration from Consumer Theory　158

6.3.2　An Illustration from Producer Theory　161

6.4　The General Case: Mixed Constraints　164

6.5　A Proof of the Theorem of Kuhn and Tucker　165

6.6　Exercises　168

7　Convex Structures in Optimization Theory　172

7.1　Convexity Defined　173

7.1.1　Concave and Convex Functions　174

7.1.2　Strictly Concave and Strictly Convex Functions　176

7.2　Implications of Convexity　177

7.2.1　Convexity and Continuity　177

7.2.2　Convexity and Differentiability　179

7.2.3　Convexity and the Properties of the Derivative　183

7.3　Convexity and Optimization　185

7.3.1　Some General Observations　185

7.3.2　Convexity and Unconstrained Optimization　187

7.3.3　Convexity and the Theorem of Kuhn and Tucker　187

7.4　Using Convexity in Optimization　189

7.5 A　Proof of the First-Derivative Characterization of Convexity　190

7.6 A　Proof of the Second-Derivative Characterization of Convexity　191

7.7 A　Proof of the Theorem of Kuhn and Tucker under Convexity　194

7.8　Exercises　198

8　Quasi-Convexity and Optimization　203

8.1　Quasi-Concave and Quasi-Convex Functions　204

8.2　Quasi-Convexity as a Generalization of Convexity　205

8.3　Implications of Quasi-Convexity　209

8.4　Quasi-Convexity and Optimization　213

8.5　Using Quasi-Convexity in Optimization Problems　215

8.6　A Proof of the First-Derivative Characterization of Quasi-Convexity　216

8.7　A Proof of the Second-Derivative Characterization of Quasi-Convexity　217

8.8　A Proof of the Theorem of Kuhn and Tucker under Quasi-Convexity　220

8.9　Exercises　221

9　Parametric Continuity: The Maximum Theorem　224

9.1　Correspondences　225

9.1.1　Upper- and Lower-Semicontinuous Correspondences　225

9.1.2　Additional Definitions　228

9.1.3　A Characterization of Semicontinuous Correspondences　229

9.1.4　Semicontinuous Functions and Semicontinuous Correspondences　233

9.2　Parametric Continuity: The Maximum Theorem　235

9.2.1　The Maximum Theorem　235

9.2.2　The Maximum Theorem under Convexity　237

9.3　An Application to Consumer Theory　240

9.3.1　Continuity of the Budget Correspondence　240

9.3.2　The Indirect Utility Function and Demand Correspondence　242

9.4　An Application to Nash Equilibrium　243

9.4.1　Normal-Form Games　243

9.4.2　The Brouwer/Kakutani Fixed Point Theorem　244

9.4.3　Existence of Nash Equilibrium　246

9.5　Exercises　247

10　Supermodularity and Parametric Monotonicity　253

10.1　Lattices and Supermodularity　254

10.1.1　Lattices　254

10.1.2　Supermodularity and Increasing Differences　255

10.2　Parametric Monotonicity　258

10.3　An Application to Supermodular Games　262

10.3.1　Supermodular Games　262

10.3.2　The Tarski Fixed Point Theorem　263

10.3.3　Existence of Nash Equilibrium　263

10.4　A Proof of the Second-Derivative Characterization of Supermodularity　264

10.5　Exercises　266

11　Finite-Horizon Dynamic Programming　268

11.1　Dynamic Programming Problems　268

11.2　Finite-Horizon Dynamic Programming　268

11.3　Histories, Strategies, and the Value Function　269

11.4　Markovian Strategies　271

11.5　Existence of an Optimal Strategy　272

11.6　An Example: The Consumption-Savings Problem　276

11.7　Exercises　278

12　Stationary Discounted Dynamic Programming　281

12.1　Description of the Framework　281

12.2　Histories, Strategies, and the Value Function　282

12.3　The Bellman Equation　283

12.4　A Technical Digression　286

12.4.1　Complete Metric Spaces and Cauchy Sequences　286

12.4.2　Contraction Mappings　287

12.4.3　Uniform Convergence　289

12.5　Existence of an Optimal Strategy　291

12.5.1　A Preliminary Result　292

12.5.2　Stationary Strategies　294

12.5.3　Existence of an Optimal Strategy　295

12.6　An Example: The Optimal Growth Model　298

12.6.1　The Model　299

12.6.2　Existence of Optimal Strategies　300

12.6.3　Characterization of Optimal Strategies　301

12.7　Exercises　309

Appendix A　Set Theory and Logic: An Introduction　315

A.1　Sets, Unions, Intersections　315

A.2　Propositions: Contrapositives and Converses　316

A.3　Quantifiers and Negation　318

A.4　Necessary and Sufficient Conditions　320

Appendix B　The Real Line　323

B.1　Construction of the Real Line　323

B.2　Properties of the Real Line　326

Appendix C　Structures on Vector Spaces　330

C.1　Vector Spaces　330

C.2　Inner Product Spaces　332

C.3　Normed Spaces　333

C.4　Metric Spaces　336

C.4.1　Definitions　336

C.4.2　Sets and Sequences in Metric Spaces　337

C.4.3　Continuous Functions on Metric Spaces　339

C.4.4　Separable Metric Spaces　340

C.4.5　Subspaces　341

C.5　Topological Spaces　342

C.5.1　Definitions　342

C.5.2　Sets and Sequences in Topological Spaces　343

C.5.3　Continuous Functions on Topological Spaces　343

C.5.4　Bases　343

C.6　Exercises　345

Bibliography　349

Index　351