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Handbook of Modeling High-Frequency Data in Finance Wiley Handbooks in Financial Engineering and Econometrics Series

Langue : Anglais

Auteurs :

Couverture de l’ouvrage Handbook of Modeling High-Frequency Data in Finance
CUTTING-EDGE DEVELOPMENTS IN HIGH-FREQUENCY FINANCIAL ECONOMETRICS

In recent years, the availability of high-frequency data and advances in computing have allowed financial practitioners to design systems that can handle and analyze this information. Handbook of Modeling High-Frequency Data in Finance addresses the many theoretical and practical questions raised by the nature and intrinsic properties of this data.

A one-stop compilation of empirical and analytical research, this handbook explores data sampled with high-frequency finance in financial engineering, statistics, and the modern financial business arena. Every chapter uses real-world examples to present new, original, and relevant topics that relate to newly evolving discoveries in high-frequency finance, such as:

  • Designing new methodology to discover elasticity and plasticity of price evolution

  • Constructing microstructure simulation models

  • Calculation of option prices in the presence of jumps and transaction costs

  • Using boosting for financial analysis and trading

The handbook motivates practitioners to apply high-frequency finance to real-world situations by including exclusive topics such as risk measurement and management, UHF data, microstructure, dynamic multi-period optimization, mortgage data models, hybrid Monte Carlo, retirement, trading systems and forecasting, pricing, and boosting. The diverse topics and viewpoints presented in each chapter ensure that readers are supplied with a wide treatment of practical methods.

Handbook of Modeling High-Frequency Data in Finance is an essential reference for academics and practitioners in finance, business, and econometrics who work with high-frequency data in their everyday work. It also serves as a supplement for risk management and high-frequency finance courses at the upper-undergraduate and graduate levels.

Preface xi

Contributors xiii

Part One Analysis of Empirical Data 1

1 Estimation of NIG and VG Models for High Frequency Financial Data 3
José E. Figueroa-López Steven R. Lancette Kiseop Lee and Yanhui mi

1.1 Introduction 3

1.2 The Statistical Models 6

1.3 Parametric Estimation Methods 9

1.4 Finite-Sample Performance via Simulations 14

1.5 Empirical Results 18

1.6 Conclusion 22

References 24

2 A Study of Persistence of Price Movement using High Frequency Financial Data 27
Dragos Bozdog Ionuţ Florescu Khaldoun Khashanah and Jim Wang

2.1 Introduction 27

2.2 Methodology 29

2.3 Results 35

2.4 Rare Events Distribution 41

2.5 Conclusions 44

References 45

3 Using Boosting for Financial Analysis and Trading 47
Germán Creamer

3.1 Introduction 47

3.2 Methods 48

3.3 Performance Evaluation 53

3.4 Earnings Prediction and Algorithmic Trading 60

3.5 Final Comments and Conclusions 66

References 69

4 Impact of Correlation Fluctuations on Securitized structures 75
Eric Hillebrand Ambar N. Sengupta and Junyue Xu

4.1 Introduction 75

4.2 Description of the Products and Models 77

4.3 Impact of Dynamics of Default Correlation on Low-Frequency Tranches 79

4.4 Impact of Dynamics of Default Correlation on High-Frequency Tranches 87

4.5 Conclusion 92

References 94

5 Construction of Volatility Indices Using A Multinomial Tree Approximation Method 97
Dragos Bozdog Ionuţ Florescu Khaldoun Khashanah and Hongwei Qiu

5.1 Introduction 97

5.2 New Methodology 99

5.3 Results and Discussions 101

5.4 Summary and Conclusion 110

References 115

Part Two Long Range Dependence Models 117

6 Long Correlations Applied to the Study of Memory Effects in High Frequency (TICK) Data the Dow Jones Index and International Indices 119
Ernest Barany and Maria Pia Beccar Varela

6.1 Introduction 119

6.2 Methods Used for Data Analysis 122

6.3 Data 128

6.4 Results and Discussions 132

6.5 Conclusion 150

References 160

7 Risk Forecasting with GARCH Skewed t Distributions and Multiple Timescales 163
Alec N. Kercheval and Yang Liu

7.1 Introduction 163

7.2 The Skewed t Distributions 165

7.3 Risk Forecasts on a Fixed Timescale 176

7.4 Multiple Timescale Forecasts 185

7.5 Backtesting 188

7.6 Further Analysis: Long-Term GARCH and Comparisons using Simulated Data 203

7.7 Conclusion 216

References 217

8 Parameter Estimation and Calibration for Long-Memory Stochastic Volatility Models 219
Alexandra Chronopoulou

8.1 Introduction 219

8.2 Statistical Inference Under the LMSV Model 222

8.3 Simulation Results 227

8.4 Application to the S&P Index 228

8.5 Conclusion 229

References 230

Part Three Analytical Results 233

9 A Market Microstructure Model of Ultra High Frequency Trading 235
Carlos A. Ulibarri and Peter C. Anselmo

9.1 Introduction 235

9.2 Microstructural Model 237

9.3 Static Comparisons 239

9.4 Questions for Future Research 241

References 242

10 Multivariate Volatility Estimation with High Frequency Data Using Fourier Method 243
MariaElviraMancinoandSimonaSanfelici

10.1 Introduction 243

10.2 Fourier Estimator of Multivariate Spot Volatility 246

10.3 Fourier Estimator of Integrated Volatility in the Presence of Microstructure Noise 252

10.4 Fourier Estimator of Integrated Covariance in the Presence of Microstructure Noise 263

10.5 Forecasting Properties of Fourier Estimator 272

10.6 Application: Asset Allocation 286

References 290

11 The ‘‘Retirement’’ Problem 295
Cristian Pasarica

11.1 Introduction 295

11.2 The Market Model 296

11.3 Portfolio and Wealth Processes 297

11.4 Utility Function 299

11.5 The Optimization Problem in the Case π (τT ] ≡ 0 299

11.6 Duality Approach 300

11.7 Infinite Horizon Case 305

References 324

12 Stochastic Differential Equations and Levy Models with Applications to High Frequency Data 327
Ernest Barany and Maria Pia Beccar Varela

12.1 Solutions to Stochastic Differential Equations 327

12.2 Stable Distributions 334

12.3 The Levy Flight Models 336

12.4 Numerical Simulations and Levy Models: Applications to Models Arising in Financial Indices and High Frequency Data 340

12.5 Discussion and Conclusions 345

References 346

13 Solutions to Integro-Differential Parabolic Problem Arising on Financial Mathematics 347
Maria C. Mariani Marc Salas and Indranil SenGupta

13.1 Introduction 347

13.2 Method of Upper and Lower Solutions 351

13.3 Another Iterative Method 364

13.4 Integro-Differential Equations in a Lévy Market 375

References 380

14 Existence of Solutions for Financial Models with Transaction Costs and Stochastic Volatility 383
Maria C. Mariani Emmanuel K. Ncheuguim and Indranil SenGupta

14.1 Model with Transaction Costs 383

14.2 Review of Functional Analysis 386

14.3 Solution of the Problem (14.2) and (14.3) in Sobolev Spaces 391

14.4 Model with Transaction Costs and Stochastic Volatility 400

14.5 The Analysis of the Resulting Partial Differential Equation 408

References 418

Index 421 

Frederi G. Viens, PhD, is Director and Coordinator of the Computational Finance Program at Purdue University, where he also serves as Professor of Statistics and Mathematics. He has published extensively in the areas of mathematical finance, probability theory, and stochastic processes. Dr. Viens is co-organizer of the annual Conference on Modeling High-Frequency Data in Finance.

Maria C. Mariani, PhD, is Pro-fessor and Chair in the Department of Mathematical Sciences at The University of Texas at El Paso. She currently focuses her research on mathematical finance, applied mathematics, and numerical methods. Dr. Mariani is co-organizer of the annual Conference on Modeling High-Frequency Data in Finance.

Ionut Florescu, PhD, is Assistant Professor of Mathematics at Stevens Institute of Technology. He has published in research areas including stochastic volatility, stochastic partial differential equations, Monte Carlo methods, and numerical methods for stochastic processes. Dr. Florescu is lead organizer of the annual Conference on Modeling High-Frequency Data in Finance.

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