Theory and Methods
Buch, Englisch, 304 Seiten, Format (B × H): 165 mm x 238 mm, Gewicht: 549 g
ISBN: 978-0-470-11402-5
Verlag: Wiley
A self-contained, contemporary treatment of the analysis of long-range dependent data
Long-Memory Time Series: Theory and Methods provides an overview of the theory and methods developed to deal with long-range dependent data and describes the applications of these methodologies to real-life time series. Systematically organized, it begins with the foundational essentials, proceeds to the analysis of methodological aspects (Estimation Methods, Asymptotic Theory, Heteroskedastic Models, Transformations, Bayesian Methods, and Prediction), and then extends these techniques to more complex data structures.
To facilitate understanding, the book:
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Assumes a basic knowledge of calculus and linear algebra and explains the more advanced statistical and mathematical concepts
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Features numerous examples that accelerate understanding and illustrate various consequences of the theoretical results
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Proves all theoretical results (theorems, lemmas, corollaries, etc.) or refers readers to resources with further demonstration
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Includes detailed analyses of computational aspects related to the implementation of the methodologies described, including algorithm efficiency, arithmetic complexity, CPU times, and more
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Includes proposed problems at the end of each chapter to help readers solidify their understanding and practice their skills
A valuable real-world reference for researchers and practitioners in time series analysis, economerics, finance, and related fields, this book is also excellent for a beginning graduate-level course in long-memory processes or as a supplemental textbook for those studying advanced statistics, mathematics, economics, finance, engineering, or physics. A companion Web site is available for readers to access the S-Plus and R data sets used within the text.
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Preface xiii
Acronyms xvii
1 Stationary Precedes 1
1.1 Fundamental concepts 2
1.1.1 Stationarity 4
1.1.2 Singularity and Regularity 5
1.1.3 Wold Decomposition Theorem 5
1.1.4 Causality 7
1.1.5 Invertibility 7
1.1.6 Best Linear Predictor 8
1.1.7 Szego-Kolmogorov Formula 8
1.1.8 Ergodicity 9
1.1.9 Martingales 11
1.1.10 Cumulants 12
1.1.11 Fractional Brownian Motion 12
1.1.12 Wavelets 14
1.2 Bibliographic Notes 15
Problems 16
2 State Space Systems 21
2.1 Introduction 22
2.1.1 Stability 22
2.1.2 Hankel Operator 22
2.1.3 Observability 23
2.1.4 Controllability 23
2.1.5 Minimality 24
2.2 Representations of Linear Processes 24
2.2.1 State Space Form to Wold Decomposition 24
2.2.2 Wold Decomposition to State Form 25
2.2.3 Hankel Operator to State Space Form 25
2.3 Estimation of the State 26
2.3.1 State Predictor 27
2.3.2 State Filter 27
2.3.3 State Smoother 27
2.3.4 Missing Observation 28
2.3.5 Steady State System 28
2.3.6 Prediction of Future Observations 30
2.4 Extensions 32
2.5 Bibliographic Notes 32
Problems 33
3 Long-Memory/Processes 39
3.1 Defining Long Memory 40
3.1.1 Alternative Definitions 41
3.1.2 Extensions 43
3.2 ARFIMA Processes 43
3.2.1 Stationarity, Causality, and Invertibility 44
3.2.2 Infinite AR and MA Expansions 46
3.2.3 Spectral Density 47
3.2.4 Autocovariance Function 47
3.2.5 Sample Mean 48
3.2.6 Partial Autocorrelations 49
3.2.7 Illustrations 49
3.2.8 Approximation of Long-Memory Processes 55
3.3 Fractional Gaussian Noise 56
3.3.1 Sample Mean 56
3.4 Technical Lemmas 57
3.5 Bibliographic Notes 58
Problems 59
4 Estimation Methods 65
4.1 Maximum-Likelihood Estimation 66
4.1.1 Cholesky Decomposition Method 66
4.1.2 Durbin-Levinson Algorithm 66
4.1.3 Computation of Autocovariances 67
4.1.4 State Space Approach 69
4.2 Autoregressive Approximations 71
4.2.1 Haslett-Raftery Method72
4.2.2 Beran Approach 73
4.2.3 A State Space Method 74
4.3 Moving-Average Approximation 75
4.4 Whittle Estimation 78
4.4.1 Other versions 80
4.4.2 Non-Gaussian Data 80
4.4.3 Semiparametric Methods 81
4.5 Other Methods 81
4.5.1 A Regression Method 82
4.5.2 Rescale Range Method 83
4.5.3 Variance Plots 85
4.5.4 Detrended Fluctuation Analysis 87
4.5.5 A Wavelet-Based Method 91
4.6 Numerical Experiments 92
4.7 Bibliographic Notes 93
Problems 94
5 Asymptotic Theory 97
5.1 Notation and Definitions 98
5.2 Theorems 99
5.2.1 Consistency 99
5.2.2 Central Limit Theorem 101
5.2.3 Efficiency 104
5.3 Examples 104
5.4 Illustration 108
5.5 Technical Lemmas 109
5.6 Bibliographic Notes 109
Problems 109
6 Heteroskedastic Models 115
6.1 Introduction 116
6.2 ARFIMA-GARCH Model 117
6.2.1 Estimation 119
6.3 Other Models 119
6.3.1 Estimation 121
6.4 Stochastic Volatility 121
6.4.1 Estimation 122
6.5 Numerical Experiments 122
6.6 Application 123
6.6.1 Model without Leverage 123
6.6.2 Model with Leverage 124
6.6.3 Model Comparison 124
6.7 Bibliographic Notes 125
Problems 126
7 Transformations 131
7.1 Transformation of Gaussian Processes 132
7.2 Autocorrelation of Squares 134
7.3 Asymptotic behavior 136
7.4 Illustrations 138
7.5 Bibliographic Notes 142
Problems 143
8 Bayesian Methods 147
8.1 Bayesian Modeling 148
8.2 Markov Chain Monte Carlo Methods 149
8.2.1 Metropolis-Hastings Algorithm 149
8.2.2 Gibbs Sampler 150
8.2.3 Overdispersed Distributions 152
8.3 Monitoring Convergence 153
8.4 A Simulated Example 155
8.5 Data Application 158
8.6 Bibliographic Notes 162
Problems 162
9 Prediction 167
9.1 One-Step Ahead Predictors 168
9.1.1 Infinite Past 168
9.1.2 Finite Past 168
9.1.3 An Approximate Predictor 172
9.2 Multistep Ahead Predictors 173
9.2.1 Infinite Past 173
9.2.2 Finite Past 174
9.3 Heteroskedastic Models 175
9.3.1 Prediction of Volatility 176
9.4 Illustration 178
9.5 Rational Approximations 180
9.5.1 Illustration 182
9.6 Bibliographic Notes Problems 184
10 Regression 187
10.1 Linear Regression Model 188
10.1.1 Grenander conditions 188
10.2 Properties of the LSE 191
10.2.1 Consistency 192
10.2.2 Asymptotic Variance 193
10.2.3 Asymptotic Normality 193
10.3 Properties of the BLUE 194
10.3.1 Efficiency of the LSE Relative to the BLUE 195
10.4 Estimation of the Mean 198
10.4.1 Consistency 198
10.4.2 Asymptotic Variance 199
10.4.3 Normality 200
10.4.4 Relative Efficiency 200
10.5 Polynomial Trend 202
10.5.1 Consistency 203
10.5.2 Asymptotic Variance 203
10.5.3 Normality 204
10.5.4 Relative Efficiency 204
10.6 Harmonic Regression 205
10.6.1 Consistency 205
10.6.2 Asymptotic Variance 205
10.6.3 Normality 205
10.6.4 Efficiency 206
10.7 Illustration: Air Pollution Data 207
10.8 Bibliographic Notes 210
Problems 211
11 Missing Data 215
11.1 Motivation 216
11.2 Likelihood Function with Incomplete Data 217
11.2.1 Integration 217
11.2.2 Maximization 218
11.2.3 Calculation of the Likelihood Function 219
11.2.4 Kalman Filter with Missing Observations 219
11.3 Effects of Missing Values on ML Estimates 221
11.3.1 Monte Carlo Experiments 222
11.4 Effects of Missing Values on Prediction 223
11.5 Illustrations 227
11.6 Interpolation of Missing Data 229
11.6.1 Bayesian Imputation 234
11.6.2 A Simulated Example 235
11.7 Bibliographic Notes 239
Problems 239
12 Seasonality 245
12.1 A Long-Memory Seasonal Model 246
12.2 Calculation of the Asymptotic Variance 250
12.3 Autocovariance Function 252
12.4 Monte Carlo Studies 254
12.5 Illustration 258
12.6 Bibliographic Notes 260
Problems 261
References 265
Topic Index 279
Author Index 283
