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The world of quantitative finance (QF) is one of the fastest growing areas of research and its practical applications to derivatives pricing problem. Since the discovery of the famous Black-Scholes equation in the 1970's we have seen a surge in the number of models for a wide range of products such as plain and exotic options, interest rate derivatives, real options and many others. Gone are the days when it was possible to price these derivatives analytically. For most problems we must resort to some kind of approximate method. In this book we employ partial differential equations (PDE) to…mehr
The world of quantitative finance (QF) is one of the fastest growing areas of research and its practical applications to derivatives pricing problem. Since the discovery of the famous Black-Scholes equation in the 1970's we have seen a surge in the number of models for a wide range of products such as plain and exotic options, interest rate derivatives, real options and many others. Gone are the days when it was possible to price these derivatives analytically. For most problems we must resort to some kind of approximate method. In this book we employ partial differential equations (PDE) to describe a range of one-factor and multi-factor derivatives products such as plain European and American options, multi-asset options, Asian options, interest rate options and real options. PDE techniques allow us to create a framework for modeling complex and interesting derivatives products. Having defined the PDE problem we then approximate it using the Finite Difference Method (FDM). This method has been used for many application areas such as fluid dynamics, heat transfer, semiconductor simulation and astrophysics, to name just a few. In this book we apply the same techniques to pricing real-life derivative products. We use both traditional (or well-known) methods as well as a number of advanced schemes that are making their way into the QF literature: * Crank-Nicolson, exponentially fitted and higher-order schemes for one-factor and multi-factor options * Early exercise features and approximation using front-fixing, penalty and variational methods * Modelling stochastic volatility models using Splitting methods * Critique of ADI and Crank-Nicolson schemes; when they work and when they don't work * Modelling jumps using Partial Integro Differential Equations (PIDE) * Free and moving boundary value problems in QF Included with the book is a CD containing information on how to set up FDM algorithms, how to map these algorithms to C++ as well as several working programs for one-factor and two-factor models. We also provide source code so that you can customize the applications to suit your own needs.
Daniel Duffy is a numerical analyst who has been working in the IT business since 1979. He has been involved in the analysis, design and implementation of systems using object-oriented, component and (more recently) intelligent agent technologies to large industrial and financial applications. As early as 1993 he was involved in C++ projects for risk management and options applications with a large Dutch bank. His main interest is in finding robust and scalable numerical schemes that approximate the partial differential equations that model financial derivatives products. He has an M.Sc. in the Finite Element Method first-order hyperbolic systems and a Ph.D. in robust finite difference methods for convection-diffusion partial differential equations. Both degrees are from Trinity College, Dublin, Ireland. Daniel Duffy is founder of Datasim Education and Datasim Component Technology, two companies involved in training, consultancy and software development.
Inhaltsangabe
0 Goals of this Book and Global Overview 1 PART I THE CONTINUOUS THEORY OF PARTIAL DIFFERENTIAL EQUATIONS 5 1 An Introduction to Ordinary Differential Equations 7 2 An Introduction to Partial Differential Equations 13 3 Second-Order Parabolic Differential Equations 25 4 An Introduction to the Heat Equation in One Dimension 37 5 An Introduction to the Method of Characteristics 47 PART II FINITE DIFFERENCE METHODS: THE FUNDAMENTALS 61 6 An Introduction to the Finite Difference Method 63 7 An Introduction to the Method of Lines 79 8 General Theory of the Finite Difference Method 91 9 Finite Difference Schemes for First-Order Partial Differential Equations 103 10 FDM for the One-Dimensional Convection-Diffusion Equation 117 11 Exponentially Fitted Finite Difference Schemes 123 PART III APPLYING FDM TO ONE-FACTOR INSTRUMENT PRICING 135 12 Exact Solutions and Explicit Finite Difference Method for One-Factor Models 137 13 An Introduction to the Trinomial Method 147 14 Exponentially Fitted Difference Schemes for Barrier Options 153 15 Advanced Issues in Barrier and Lookback Option Modelling 165 16 The Meshless (Meshfree) Method in Financial Engineering 175 17 Extending the Black-Scholes Model: Jump Processes 183 PART IV FDM FOR MULTIDIMENSIONAL PROBLEMS 193 18 Finite Difference Schemes for Multidimensional Problems 195 19 An Introduction to Alternating Direction Implicit and Splitting Methods 209 20 Advanced Operator Splitting Methods: Fractional Steps 223 21 Modern Splitting Methods 229 PART V APPLYING FDM TO MULTI-FACTOR INSTRUMENT PRICING 237 22 Options with Stochastic Volatility: The Heston Model 239 23 Finite Difference Methods for Asian Options and Other 'Mixed' Problems 249 24 Multi-Asset Options 257 25 Finite Difference Methods for Fixed-Income Problems 273 PART VI FREE AND MOVING BOUNDARY VALUE PROBLEMS 285 26 Background to Free and Moving Boundary Value Problems 287 27 Numerical Methods for Free Boundary Value Problems: Front-Fixing Methods 295 28 Viscosity Solutions and Penalty Methods for American Option Problems 307 29 Variational Formulation of American Option Problems 315 PART VII DESIGN AND IMPLEMENTATION IN C++ 325 30 Finding the Appropriate Finite Difference Schemes for your Financial Engineering Problem 327 31 Design and Implementation of First-Order Problems 337 32 Moving to Black-Scholes 353 33 C++ Class Hierarchies for One-Factor and Two-Factor Payoffs 363 33.1 Introduction and objectives 363 Appendices 375 A1 An introduction to integral and partial integro-differential equations 375 A2 An introduction to the finite element method 393 Bibliography 409 Index 417
0 Goals of this Book and Global Overview. PART I THE CONTINUOUS THEORY OF PARTIAL DIFFERENTIAL EQUATIONS. 1 An Introduction to Ordinary Differential Equations. 2 An Introduction to Partial Differential Equations. 3 Second-Order Parabolic Differential Equations. 4 An Introduction to the Heat Equation in One Dimension. 5 An Introduction to the Method of Characteristics. PART II FINITE DIFFERENCE METHODS: THE FUNDAMENTALS. 6 AnIntroduction to the Finite Difference Method. 7 An Introduction to the Method of Lines. 8 General Theory of the Finite Difference Method. 9 Finite Difference Schemes for First-Order Partial Differential Equations. 10 FDM for the One-Dimensional Convection-Diffusion Equation. 11 Exponentially Fitted Finite Difference Schemes. PART III APPLYING FDM TO ONE-FACTOR INSTRUMENT PRICING. 12 Exact Solutions and Explicit Finite Difference Method for One-Factor Models. 13 An Introduction to the Trinomial Method. 14 Exponentially Fitted Difference Schemes for Barrier Options. 15 Advanced Issues in Barrier and Lookback Option Modelling. 16 The Meshless (Meshfree) Method in Financial Engineering. 17 Extending the Black-Scholes Model: Jump Processes. PART IV FDM FOR MULTIDIMENSIONAL PROBLEMS. 18 Finite Difference Schemes for Multidimensional Problems. 19 An Introduction to Alternating Direction Implicit and Splitting Methods. 20 Advanced Operator Splitting Methods: Fractional Steps. 21 Modern Splitting Methods. PART V APPLYING FDM TO MULTI-FACTOR INSTRUMENT PRICING. 22 Options with Stochastic Volatility: The Heston Model. 23 Finite Difference Methods for Asian Options and Other 'Mixed' Problems. 24 Multi-Asset Options. 25 Finite Difference Methods for Fixed-Income Problems. PART VI FREE AND MOVING BOUNDARY VALUE PROBLEMS. 26 Background to Free and Moving Boundary Value Problems. 27 Numerical Methods for Free Boundary Value Problems: Front-Fixing Methods. 28 Viscosity Solutions and Penalty Methods for American Option Problems. 29 Variational Formulation of American Option Problems. PART VII DESIGN AND IMPLEMENTATION IN C++. 30 Finding the Appropriate Finite Difference Schemes for your Financial Engineering Problem. 31 Design and Implementation of First-Order Problems. 32 Moving to Black-Scholes. 33 C++ Class Hierarchies for One-Factor and Two-Factor Payoffs. Appendices. A1 An introduction to integral and partial integro-differential equations. A2 An introduction to the finite element method. Bibliography. Index.
0 Goals of this Book and Global Overview 1 PART I THE CONTINUOUS THEORY OF PARTIAL DIFFERENTIAL EQUATIONS 5 1 An Introduction to Ordinary Differential Equations 7 2 An Introduction to Partial Differential Equations 13 3 Second-Order Parabolic Differential Equations 25 4 An Introduction to the Heat Equation in One Dimension 37 5 An Introduction to the Method of Characteristics 47 PART II FINITE DIFFERENCE METHODS: THE FUNDAMENTALS 61 6 An Introduction to the Finite Difference Method 63 7 An Introduction to the Method of Lines 79 8 General Theory of the Finite Difference Method 91 9 Finite Difference Schemes for First-Order Partial Differential Equations 103 10 FDM for the One-Dimensional Convection-Diffusion Equation 117 11 Exponentially Fitted Finite Difference Schemes 123 PART III APPLYING FDM TO ONE-FACTOR INSTRUMENT PRICING 135 12 Exact Solutions and Explicit Finite Difference Method for One-Factor Models 137 13 An Introduction to the Trinomial Method 147 14 Exponentially Fitted Difference Schemes for Barrier Options 153 15 Advanced Issues in Barrier and Lookback Option Modelling 165 16 The Meshless (Meshfree) Method in Financial Engineering 175 17 Extending the Black-Scholes Model: Jump Processes 183 PART IV FDM FOR MULTIDIMENSIONAL PROBLEMS 193 18 Finite Difference Schemes for Multidimensional Problems 195 19 An Introduction to Alternating Direction Implicit and Splitting Methods 209 20 Advanced Operator Splitting Methods: Fractional Steps 223 21 Modern Splitting Methods 229 PART V APPLYING FDM TO MULTI-FACTOR INSTRUMENT PRICING 237 22 Options with Stochastic Volatility: The Heston Model 239 23 Finite Difference Methods for Asian Options and Other 'Mixed' Problems 249 24 Multi-Asset Options 257 25 Finite Difference Methods for Fixed-Income Problems 273 PART VI FREE AND MOVING BOUNDARY VALUE PROBLEMS 285 26 Background to Free and Moving Boundary Value Problems 287 27 Numerical Methods for Free Boundary Value Problems: Front-Fixing Methods 295 28 Viscosity Solutions and Penalty Methods for American Option Problems 307 29 Variational Formulation of American Option Problems 315 PART VII DESIGN AND IMPLEMENTATION IN C++ 325 30 Finding the Appropriate Finite Difference Schemes for your Financial Engineering Problem 327 31 Design and Implementation of First-Order Problems 337 32 Moving to Black-Scholes 353 33 C++ Class Hierarchies for One-Factor and Two-Factor Payoffs 363 33.1 Introduction and objectives 363 Appendices 375 A1 An introduction to integral and partial integro-differential equations 375 A2 An introduction to the finite element method 393 Bibliography 409 Index 417
0 Goals of this Book and Global Overview. PART I THE CONTINUOUS THEORY OF PARTIAL DIFFERENTIAL EQUATIONS. 1 An Introduction to Ordinary Differential Equations. 2 An Introduction to Partial Differential Equations. 3 Second-Order Parabolic Differential Equations. 4 An Introduction to the Heat Equation in One Dimension. 5 An Introduction to the Method of Characteristics. PART II FINITE DIFFERENCE METHODS: THE FUNDAMENTALS. 6 AnIntroduction to the Finite Difference Method. 7 An Introduction to the Method of Lines. 8 General Theory of the Finite Difference Method. 9 Finite Difference Schemes for First-Order Partial Differential Equations. 10 FDM for the One-Dimensional Convection-Diffusion Equation. 11 Exponentially Fitted Finite Difference Schemes. PART III APPLYING FDM TO ONE-FACTOR INSTRUMENT PRICING. 12 Exact Solutions and Explicit Finite Difference Method for One-Factor Models. 13 An Introduction to the Trinomial Method. 14 Exponentially Fitted Difference Schemes for Barrier Options. 15 Advanced Issues in Barrier and Lookback Option Modelling. 16 The Meshless (Meshfree) Method in Financial Engineering. 17 Extending the Black-Scholes Model: Jump Processes. PART IV FDM FOR MULTIDIMENSIONAL PROBLEMS. 18 Finite Difference Schemes for Multidimensional Problems. 19 An Introduction to Alternating Direction Implicit and Splitting Methods. 20 Advanced Operator Splitting Methods: Fractional Steps. 21 Modern Splitting Methods. PART V APPLYING FDM TO MULTI-FACTOR INSTRUMENT PRICING. 22 Options with Stochastic Volatility: The Heston Model. 23 Finite Difference Methods for Asian Options and Other 'Mixed' Problems. 24 Multi-Asset Options. 25 Finite Difference Methods for Fixed-Income Problems. PART VI FREE AND MOVING BOUNDARY VALUE PROBLEMS. 26 Background to Free and Moving Boundary Value Problems. 27 Numerical Methods for Free Boundary Value Problems: Front-Fixing Methods. 28 Viscosity Solutions and Penalty Methods for American Option Problems. 29 Variational Formulation of American Option Problems. PART VII DESIGN AND IMPLEMENTATION IN C++. 30 Finding the Appropriate Finite Difference Schemes for your Financial Engineering Problem. 31 Design and Implementation of First-Order Problems. 32 Moving to Black-Scholes. 33 C++ Class Hierarchies for One-Factor and Two-Factor Payoffs. Appendices. A1 An introduction to integral and partial integro-differential equations. A2 An introduction to the finite element method. Bibliography. Index.
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