Description

Book Synopsis
New statistical methods and future directions of research in time series A Course in Time Series Analysis demonstrates how to build time series models for univariate and multivariate time series data.

Trade Review
"This text demonstrate how to build time series models forunivariate and multivariate time series data." (SciTech Book News,Vol. 25, No. 2, June 2001)

"...material is thoroughly and carefully presented...a veryuseful addition to any collection both for learning and reference."(Short Book Reviews, Vol. 21, No. 2, August 2001)

"From the preface: ?The book can be used as a principal text ora complementary text for courses in time series.?" (MathematicalReviews, Issue 2001k)

"...an excellent complement...for a first graduate course intime series analysis...a nice addition to anyone?s time serieslibrary." (Technometrics, Vol. 43, No. 4, November 2001)

"If you are familiar with the basics...and need a compass tonavigate the vast world of time series literature, then this bookis certainly what you need to have around...presents seamlessly andcoherently overviews of the current status of time series researchand applications." (The American Statistician, Vol. 56, No. 1,February 2002)

"...an excellent source of introductory surveys of severaltimely topics in time series analysis..." (Statistical Papers, July2002)

"...a nice compendium covering a lot of relevant material..."(Statistics & Decisions, Vol.20, No.4, 2002)

Table of Contents

1. Introduction 1
D. Pena and G. C. Tiao

1.1. Examples of time series problems, 1

1.1.1. Stationary series, 2

1.1.2. Nonstationary series, 3

1.1.3. Seasonal series, 5

1.1.4. Level shifts and outliers in time series, 7

1.1.5. Variance changes, 7

1.1.6. Asymmetric time series, 7

1.1.7. Unidirectional-feedback relation between series, 9

1.1.8. Comovement and cointegration, 10

1.2. Overview of the book, 10

1.3. Further reading, 19

PART I BASIC CONCEPTS IN UNIVARIATE TIME SERIES

2. Univariate Time Series: Autocorrelation, Linear Prediction, Spectrum, and State-Space Model 25
G. T. Wilson

2.1. Linear time series models, 25

2.2. The autocorrelation function, 28

2.3. Lagged prediction and the partial autocorrelation function, 33

2.4. Transformations to stationarity, 35

2.5. Cycles and the periodogram, 37

2.6. The spectrum, 42

2.7. Further interpretation of time series acf, pacf, and spectrum, 46

2.8. State-space models and the Kalman Filter, 48

3. Univariate Autoregressive Moving-Average Models 53
G. C. Tiao

3.1. Introduction, 53

3.1.1. Univariate ARMA models, 54

3.1.2. Outline of the chapter, 55

3.2. Some basic properties of univariate ARMA models, 55

3.2.1. The ø and TT weights, 56

3.2.2. Stationarity condition and autocovariance structure o f z „ 58

3.2.3. The autocorrelation function, 59

3.2.4. The partial autocorrelation function, 60

3.2.5. The extended autocorrelaton function, 61

3.3. Model specification strategy, 63

3.3.1. Tentative specification, 63

3.3.2. Tentative model specification via SEACF, 67

3.4. Examples, 68

4. Model Fitting and Checking, and the Kalman Filter 86
G. T. Wilson

4.1. Prediction error and the estimation criterion, 86

4.2. The likelihood of ARMA models, 90

4.3. Likelihoods calculated using orthogonal errors, 94

4.4. Properties of estimates and problems in estimation, 98

4.5. Checking the fitted model, 101

4.6. Estimation by fitting to the sample spectrum, 104

4.7. Estimation of structural models by the Kalman filter, 105

5. Prediction and Model Selection 111
D. Pefia

5.1. Introduction, 111

5.2. Properties of minimum mean-square error prediction, 112

5.2.1. Prediction by the conditional expectation, 112

5.2.2. Linear predictions, 113

5.3. The computation of ARIMA forecasts, 114

5.4. Interpreting the forecasts from ARIMA models, 116

5.4.1. Nonseasonal models, 116

5.4.2. Seasonal models, 120

5.5. Prediction confidence intervals, 123

5.5.1. Known parameter values, 123

5.5.2. Unknown parameter values, 124

5.6. Forecast updating, 125

5.6.1. Computing updated forecasts, 125

5.6.2. Testing model stability, 125

5.7. The combination of forecasts, 129

5.8. Model selection criteria, 131

5.8.1. The FPE and AIC criteria, 131

5.8.2. The Schwarz criterion, 133

5.9. Conclusions, 133

6. Outliers, Influential Observations, and Missing Data 136
D. Pena

6.1. Introduction, 136

6.2. Types of outliers in time series, 138

6.2.1. Additive outliers, 138

6.2.2. Innovative outliers, 141

6.2.3. Level shifts, 143

6.2.4. Outliers and intervention analysis, 146

6.3. Procedures for outlier identification and estimation, 147

6.3.1. Estimation of outlier effects, 148

6.3.2. Testing for outliers, 149

6.4. Influential observations, 152

6.4.1. Influence on time series, 152

6.4.2. Influential observations and outliers, 153

6.5. Multiple outliers, 154

6.5.1. Masking effects, 154

6.5.2. Procedures for multiple outlier identification, 156

6.6. Missing-value estimation, 160

6.6.1. Optimal interpolation and inverse autocorrelation function, 160

6.6.2. Estimation of missing values, 162

6.7. Forecasting with outliers, 164

6.8. Other approaches, 166

6.9. Appendix, 166

7. Automatic Modeling Methods for Univariate Series 171
V. Gomez and A. Maravall

7.1. Classical model identification methods, 171

7.1.1. Subjectivity of the classical methods, 172

7.1.2. The difficulties with mixed ARMA models, 173

7.2. Automatic model identification methods, 173

7.2.1. Unit root testing, 174

7.2.2. Penalty function methods, 174

7.2.3. Pattern identification methods, 175

7.2.4. Uniqueness of the solution and the purpose of modeling, 176

7.3. Tools for automatic model identification, 177

7.3.1. Test for the log-level specification, 177

7.3.2. Regression techniques for estimating unit roots, 178

7.3.3. The Hannan-Rissanen method, 181

7.3.4. Liu's filtering method, 185

7.4. Automatic modeling methods in the presence of outliers, 186

7.4.1. Algorithms for automatic outlier detection and correction, 186

7.4.2. Estimation and filtering techniques to speed up the algorithms, 190

7.4.3. The need to robustify automatic modeling methods, 191

7.4.4. An algorithm for automatic model identification in the presence of outliers, 191

7.5. An automatic procedure for the general regression-ARIMA model in the presence of outlierw, special effects, and, possibly, missing observations, 192

7.5.1. Missing observations, 192

7.5.2. Trading day and Easter effects, 193

7.5.3. Intervention and regression effects, 194

7.6. Examples, 194

7.7. Tabular summary, 196

8. Seasonal Adjustment and Signal Extraction Time Series 202
V. Gomez and A. Maravall

8.1. Introduction, 202

8.2. Some remarks on the evolution of seasonal adjustment methods, 204

8.2.1. Evolution of the methodologic approach, 204

8.2.2. The situation at present, 207

8.3. The need for preadjustment, 209

8.4. Model specification, 210

8.5. Estimation of the components, 213

8.5.1. Stationary case, 215

8.5.2. Nonstationary series, 217

8.6 Historical or final estimator, 218

8.6.1. Properties of final estimator, 218

8.6.2. Component versus estimator, 219

8.6.3. Covariance between estimators, 221

8.7. Estimators for recent periods, 221

8.8. Revisions in the estimator, 223

8.8.1. Structure of the revision, 223

8.8.2. Optimality of the revisions, 224

8.9. Inference, 225

8.9.1. Optical Forecasts of the Components, 225

8.9.2. Estimation error, 225

8.9.3. Growth rate precision, 226

8.9.4. The gain from concurrent adjustment, 227

8.9.5. Innovations in the components (pseudoinnovations), 228

8.10. An example, 228

8.11. Relation with fixed filters, 235

8.12. Short-versus long-term trends; measuring economic cycles, 236

PART II ADVANCED TOPICS IN UNIVARIATE TIME SERIES

9. Heteroscedastic Models
R. S. Tsay

9.1. The ARCH model, 250

9.1.1. Some simple properties of ARCH models, 252

9.1.2. Weaknesses of ARCH models, 254

9.1.3. Building ARCH models, 254

9.1.4. An illustrative example, 255

9.2. The GARCH Model, 256

9.2.1. An illustrative example, 257

9.2.2. Remarks, 259

9.3. The exponential GARCH model, 260

9.3.1. An illustrative example, 261

9.4. The CHARMA model, 262

9.5. Random coefficient autoregressive (RCA) model, 263

9.6. Stochastic volatility model, 264

9.7. Long-memory stochastic volatility model, 265

10. Nonlinear Time Series Models: Testing and Applications 267
R. S. Tsay

10.1. Introduction, 267

10.2. Nonlinearity tests, 268

10.2.1. The test, 268

10.2.2. Comparison and application, 270

10.3. The Tar model, 274

10.3.1. U.S. real GNP, 275

10.3.2. Postsample forecasts and discussion, 279

10.4. Concluding remarks, 282

11. Bayesian Time Series Analysis 286
R. S. Tsay

11.1. Introduction, 286

11.2. A general univariate time series model, 288

11.3. Estimation, 289

11.3.1. Gibbs sampling, 291

11.3.2. Griddy Gibbs, 292

11.3.3. An illustrative example, 292

11.4. Model discrimination, 294

11.4.1. A mixed model with switching, 295

11.4.2. Implementation, 296

11.5. Examples, 297

12 Nonparametric Time Series Analysis: Nonparametric Regression, Locally Weighted Regression, Autoregression, and Quantile Regression 308
S. Heiler

12.1 Introduction, 308

12.2 Nonparametric regression, 309

12.3 Kernel estimation in time series, 314

12.4 Problems of simple kernel estimation and restricted approaches, 319

12.5 Locally weighted regression, 321

12.6 Applications of locally weighted regression to time series, 329

12.7 Parameter selection, 330

12.8 Time series decomposition with locally weighted regression, 336

13. Neural Network Models 348
K. Hornik and F. Leisch

13.1. Introduction, 348

13.2. The multilayer perceptron, 349

13.3. Autoregressive neural network models, 354

13.3.1. Example: Sunspot series, 355

13.4. The recurrent perceptron, 356

13.4.1. Examples of recurrent neural network models, 357

13.4.2. A unifying view, 359

PART III MULTIVARIATE TIME SERIES

14. Vector ARMA Models 365
G. C. Tiao

14.1. Introduction, 365

14.2. Transfer function or unidirectional models, 366

14.3. The vector ARMA model, 368

14.3.1. Some simple examples, 368

14.3.2. Relationship to transfer function model, 371

14.3.3. Cross-covariance and correlation matrices, 371

14.3.4. The partial autoregression matrices, 372

14.4. Model building strategy for multiple time series, 373

14.4.1. Tentative specification, 373

14.4.2. Estimation, 378

14.4.3. Diagnostic checking, 379

14.5. Analyses of three examples, 380

14.5.1. The SCC data, 380

14.5.2. The gas furnace data, 383

14.5.3. The census housing data, 387

14.6. Structural analysis of multivariate time series, 392

14.6.1. A canonical analysis of multiple time series, 395

14.7. Scalar component models in multiple time series, 396

14.7.1. Scalar component models, 398

14.7.2. Exchangeable models and overparameterization, 400

14.7.3. Model specification via canonical correlation analysis, 402

14.7.4. An illustrative example, 403

14.7.5. Some further remarks, 404

15. Cointegration in the VAR Model 408
5. Johansen

15.1. Introduction, 408

15.1.1. Basic definitions, 409

15.2. Solving autoregressive equations, 412

15.2.1. Some examples, 412

15.2.2. An inversion theorem for matrix polynomials, 414

15.2.3. Granger's representation, 417

15.2.4. Prediction, 419

15.3. The statistical model for / ( l ) variables, 420

15.3.1. Hypotheses on cointegrating relations, 421

15.3.2. Estimation of cointegrating vectors and calculation of test statistics, 422

15.3.3. Estimation of â under restrictions, 426

15.4. Asymptotic theory, 426

15.4.1. Asymptotic results, 427

15.4.2. Test for cointegrating rank, 427

15.4.3. Asymptotic distribution of â and test for restrictions on â, 429

15.5. Various applications of the cointegration model, 432

15.5.1. Rational expectations, 432

15.5.2. Arbitrage pricing theory, 433

15.5.3. Seasonal cointegration, 433

16. Identification of Linear Dynamic Multiinput/Multioutput Systems 436
M. Deistler

16.1. Introduction and problem statement, 436

16.2. Representations of linear systems, 438

16.2.1. Input/output representations, 438

16.2.2. Solutions of linear vector difference equations (VDEs), 440

16.2.3. ARMA and state-space representations, 441

16.3. The structure of state-space systems, 443

16.4. The structure of ARMA systems, 444

16.5. The realization of state-space systems, 445

16.5.1. General structure, 445

16.5.2. Echelon forms, 447

16.6. The realization of ARMA systems, 448

16.7. Parametrization, 449

16.8. Estimation of real-valued parameters, 452

16.9. Dynamic specification, 454

INDEX 457

A Course in Time Series Analysis

    Product form

    £178.16

    Includes FREE delivery

    RRP £197.95 – you save £19.79 (9%)

    Order before 4pm tomorrow for delivery by Mon 22 Jun 2026.

    A Hardback by Daniel Pena, George C. Tiao, Ruey S. Tsay


      View other formats and editions of A Course in Time Series Analysis by Daniel Pena

      Publisher: Wiley
      Publication Date: 29/12/2000
      ISBN13: 9780471361640, 978-0471361640
      ISBN10:

      Description

      Book Synopsis
      New statistical methods and future directions of research in time series A Course in Time Series Analysis demonstrates how to build time series models for univariate and multivariate time series data.

      Trade Review
      "This text demonstrate how to build time series models forunivariate and multivariate time series data." (SciTech Book News,Vol. 25, No. 2, June 2001)

      "...material is thoroughly and carefully presented...a veryuseful addition to any collection both for learning and reference."(Short Book Reviews, Vol. 21, No. 2, August 2001)

      "From the preface: ?The book can be used as a principal text ora complementary text for courses in time series.?" (MathematicalReviews, Issue 2001k)

      "...an excellent complement...for a first graduate course intime series analysis...a nice addition to anyone?s time serieslibrary." (Technometrics, Vol. 43, No. 4, November 2001)

      "If you are familiar with the basics...and need a compass tonavigate the vast world of time series literature, then this bookis certainly what you need to have around...presents seamlessly andcoherently overviews of the current status of time series researchand applications." (The American Statistician, Vol. 56, No. 1,February 2002)

      "...an excellent source of introductory surveys of severaltimely topics in time series analysis..." (Statistical Papers, July2002)

      "...a nice compendium covering a lot of relevant material..."(Statistics & Decisions, Vol.20, No.4, 2002)

      Table of Contents

      1. Introduction 1
      D. Pena and G. C. Tiao

      1.1. Examples of time series problems, 1

      1.1.1. Stationary series, 2

      1.1.2. Nonstationary series, 3

      1.1.3. Seasonal series, 5

      1.1.4. Level shifts and outliers in time series, 7

      1.1.5. Variance changes, 7

      1.1.6. Asymmetric time series, 7

      1.1.7. Unidirectional-feedback relation between series, 9

      1.1.8. Comovement and cointegration, 10

      1.2. Overview of the book, 10

      1.3. Further reading, 19

      PART I BASIC CONCEPTS IN UNIVARIATE TIME SERIES

      2. Univariate Time Series: Autocorrelation, Linear Prediction, Spectrum, and State-Space Model 25
      G. T. Wilson

      2.1. Linear time series models, 25

      2.2. The autocorrelation function, 28

      2.3. Lagged prediction and the partial autocorrelation function, 33

      2.4. Transformations to stationarity, 35

      2.5. Cycles and the periodogram, 37

      2.6. The spectrum, 42

      2.7. Further interpretation of time series acf, pacf, and spectrum, 46

      2.8. State-space models and the Kalman Filter, 48

      3. Univariate Autoregressive Moving-Average Models 53
      G. C. Tiao

      3.1. Introduction, 53

      3.1.1. Univariate ARMA models, 54

      3.1.2. Outline of the chapter, 55

      3.2. Some basic properties of univariate ARMA models, 55

      3.2.1. The ø and TT weights, 56

      3.2.2. Stationarity condition and autocovariance structure o f z „ 58

      3.2.3. The autocorrelation function, 59

      3.2.4. The partial autocorrelation function, 60

      3.2.5. The extended autocorrelaton function, 61

      3.3. Model specification strategy, 63

      3.3.1. Tentative specification, 63

      3.3.2. Tentative model specification via SEACF, 67

      3.4. Examples, 68

      4. Model Fitting and Checking, and the Kalman Filter 86
      G. T. Wilson

      4.1. Prediction error and the estimation criterion, 86

      4.2. The likelihood of ARMA models, 90

      4.3. Likelihoods calculated using orthogonal errors, 94

      4.4. Properties of estimates and problems in estimation, 98

      4.5. Checking the fitted model, 101

      4.6. Estimation by fitting to the sample spectrum, 104

      4.7. Estimation of structural models by the Kalman filter, 105

      5. Prediction and Model Selection 111
      D. Pefia

      5.1. Introduction, 111

      5.2. Properties of minimum mean-square error prediction, 112

      5.2.1. Prediction by the conditional expectation, 112

      5.2.2. Linear predictions, 113

      5.3. The computation of ARIMA forecasts, 114

      5.4. Interpreting the forecasts from ARIMA models, 116

      5.4.1. Nonseasonal models, 116

      5.4.2. Seasonal models, 120

      5.5. Prediction confidence intervals, 123

      5.5.1. Known parameter values, 123

      5.5.2. Unknown parameter values, 124

      5.6. Forecast updating, 125

      5.6.1. Computing updated forecasts, 125

      5.6.2. Testing model stability, 125

      5.7. The combination of forecasts, 129

      5.8. Model selection criteria, 131

      5.8.1. The FPE and AIC criteria, 131

      5.8.2. The Schwarz criterion, 133

      5.9. Conclusions, 133

      6. Outliers, Influential Observations, and Missing Data 136
      D. Pena

      6.1. Introduction, 136

      6.2. Types of outliers in time series, 138

      6.2.1. Additive outliers, 138

      6.2.2. Innovative outliers, 141

      6.2.3. Level shifts, 143

      6.2.4. Outliers and intervention analysis, 146

      6.3. Procedures for outlier identification and estimation, 147

      6.3.1. Estimation of outlier effects, 148

      6.3.2. Testing for outliers, 149

      6.4. Influential observations, 152

      6.4.1. Influence on time series, 152

      6.4.2. Influential observations and outliers, 153

      6.5. Multiple outliers, 154

      6.5.1. Masking effects, 154

      6.5.2. Procedures for multiple outlier identification, 156

      6.6. Missing-value estimation, 160

      6.6.1. Optimal interpolation and inverse autocorrelation function, 160

      6.6.2. Estimation of missing values, 162

      6.7. Forecasting with outliers, 164

      6.8. Other approaches, 166

      6.9. Appendix, 166

      7. Automatic Modeling Methods for Univariate Series 171
      V. Gomez and A. Maravall

      7.1. Classical model identification methods, 171

      7.1.1. Subjectivity of the classical methods, 172

      7.1.2. The difficulties with mixed ARMA models, 173

      7.2. Automatic model identification methods, 173

      7.2.1. Unit root testing, 174

      7.2.2. Penalty function methods, 174

      7.2.3. Pattern identification methods, 175

      7.2.4. Uniqueness of the solution and the purpose of modeling, 176

      7.3. Tools for automatic model identification, 177

      7.3.1. Test for the log-level specification, 177

      7.3.2. Regression techniques for estimating unit roots, 178

      7.3.3. The Hannan-Rissanen method, 181

      7.3.4. Liu's filtering method, 185

      7.4. Automatic modeling methods in the presence of outliers, 186

      7.4.1. Algorithms for automatic outlier detection and correction, 186

      7.4.2. Estimation and filtering techniques to speed up the algorithms, 190

      7.4.3. The need to robustify automatic modeling methods, 191

      7.4.4. An algorithm for automatic model identification in the presence of outliers, 191

      7.5. An automatic procedure for the general regression-ARIMA model in the presence of outlierw, special effects, and, possibly, missing observations, 192

      7.5.1. Missing observations, 192

      7.5.2. Trading day and Easter effects, 193

      7.5.3. Intervention and regression effects, 194

      7.6. Examples, 194

      7.7. Tabular summary, 196

      8. Seasonal Adjustment and Signal Extraction Time Series 202
      V. Gomez and A. Maravall

      8.1. Introduction, 202

      8.2. Some remarks on the evolution of seasonal adjustment methods, 204

      8.2.1. Evolution of the methodologic approach, 204

      8.2.2. The situation at present, 207

      8.3. The need for preadjustment, 209

      8.4. Model specification, 210

      8.5. Estimation of the components, 213

      8.5.1. Stationary case, 215

      8.5.2. Nonstationary series, 217

      8.6 Historical or final estimator, 218

      8.6.1. Properties of final estimator, 218

      8.6.2. Component versus estimator, 219

      8.6.3. Covariance between estimators, 221

      8.7. Estimators for recent periods, 221

      8.8. Revisions in the estimator, 223

      8.8.1. Structure of the revision, 223

      8.8.2. Optimality of the revisions, 224

      8.9. Inference, 225

      8.9.1. Optical Forecasts of the Components, 225

      8.9.2. Estimation error, 225

      8.9.3. Growth rate precision, 226

      8.9.4. The gain from concurrent adjustment, 227

      8.9.5. Innovations in the components (pseudoinnovations), 228

      8.10. An example, 228

      8.11. Relation with fixed filters, 235

      8.12. Short-versus long-term trends; measuring economic cycles, 236

      PART II ADVANCED TOPICS IN UNIVARIATE TIME SERIES

      9. Heteroscedastic Models
      R. S. Tsay

      9.1. The ARCH model, 250

      9.1.1. Some simple properties of ARCH models, 252

      9.1.2. Weaknesses of ARCH models, 254

      9.1.3. Building ARCH models, 254

      9.1.4. An illustrative example, 255

      9.2. The GARCH Model, 256

      9.2.1. An illustrative example, 257

      9.2.2. Remarks, 259

      9.3. The exponential GARCH model, 260

      9.3.1. An illustrative example, 261

      9.4. The CHARMA model, 262

      9.5. Random coefficient autoregressive (RCA) model, 263

      9.6. Stochastic volatility model, 264

      9.7. Long-memory stochastic volatility model, 265

      10. Nonlinear Time Series Models: Testing and Applications 267
      R. S. Tsay

      10.1. Introduction, 267

      10.2. Nonlinearity tests, 268

      10.2.1. The test, 268

      10.2.2. Comparison and application, 270

      10.3. The Tar model, 274

      10.3.1. U.S. real GNP, 275

      10.3.2. Postsample forecasts and discussion, 279

      10.4. Concluding remarks, 282

      11. Bayesian Time Series Analysis 286
      R. S. Tsay

      11.1. Introduction, 286

      11.2. A general univariate time series model, 288

      11.3. Estimation, 289

      11.3.1. Gibbs sampling, 291

      11.3.2. Griddy Gibbs, 292

      11.3.3. An illustrative example, 292

      11.4. Model discrimination, 294

      11.4.1. A mixed model with switching, 295

      11.4.2. Implementation, 296

      11.5. Examples, 297

      12 Nonparametric Time Series Analysis: Nonparametric Regression, Locally Weighted Regression, Autoregression, and Quantile Regression 308
      S. Heiler

      12.1 Introduction, 308

      12.2 Nonparametric regression, 309

      12.3 Kernel estimation in time series, 314

      12.4 Problems of simple kernel estimation and restricted approaches, 319

      12.5 Locally weighted regression, 321

      12.6 Applications of locally weighted regression to time series, 329

      12.7 Parameter selection, 330

      12.8 Time series decomposition with locally weighted regression, 336

      13. Neural Network Models 348
      K. Hornik and F. Leisch

      13.1. Introduction, 348

      13.2. The multilayer perceptron, 349

      13.3. Autoregressive neural network models, 354

      13.3.1. Example: Sunspot series, 355

      13.4. The recurrent perceptron, 356

      13.4.1. Examples of recurrent neural network models, 357

      13.4.2. A unifying view, 359

      PART III MULTIVARIATE TIME SERIES

      14. Vector ARMA Models 365
      G. C. Tiao

      14.1. Introduction, 365

      14.2. Transfer function or unidirectional models, 366

      14.3. The vector ARMA model, 368

      14.3.1. Some simple examples, 368

      14.3.2. Relationship to transfer function model, 371

      14.3.3. Cross-covariance and correlation matrices, 371

      14.3.4. The partial autoregression matrices, 372

      14.4. Model building strategy for multiple time series, 373

      14.4.1. Tentative specification, 373

      14.4.2. Estimation, 378

      14.4.3. Diagnostic checking, 379

      14.5. Analyses of three examples, 380

      14.5.1. The SCC data, 380

      14.5.2. The gas furnace data, 383

      14.5.3. The census housing data, 387

      14.6. Structural analysis of multivariate time series, 392

      14.6.1. A canonical analysis of multiple time series, 395

      14.7. Scalar component models in multiple time series, 396

      14.7.1. Scalar component models, 398

      14.7.2. Exchangeable models and overparameterization, 400

      14.7.3. Model specification via canonical correlation analysis, 402

      14.7.4. An illustrative example, 403

      14.7.5. Some further remarks, 404

      15. Cointegration in the VAR Model 408
      5. Johansen

      15.1. Introduction, 408

      15.1.1. Basic definitions, 409

      15.2. Solving autoregressive equations, 412

      15.2.1. Some examples, 412

      15.2.2. An inversion theorem for matrix polynomials, 414

      15.2.3. Granger's representation, 417

      15.2.4. Prediction, 419

      15.3. The statistical model for / ( l ) variables, 420

      15.3.1. Hypotheses on cointegrating relations, 421

      15.3.2. Estimation of cointegrating vectors and calculation of test statistics, 422

      15.3.3. Estimation of â under restrictions, 426

      15.4. Asymptotic theory, 426

      15.4.1. Asymptotic results, 427

      15.4.2. Test for cointegrating rank, 427

      15.4.3. Asymptotic distribution of â and test for restrictions on â, 429

      15.5. Various applications of the cointegration model, 432

      15.5.1. Rational expectations, 432

      15.5.2. Arbitrage pricing theory, 433

      15.5.3. Seasonal cointegration, 433

      16. Identification of Linear Dynamic Multiinput/Multioutput Systems 436
      M. Deistler

      16.1. Introduction and problem statement, 436

      16.2. Representations of linear systems, 438

      16.2.1. Input/output representations, 438

      16.2.2. Solutions of linear vector difference equations (VDEs), 440

      16.2.3. ARMA and state-space representations, 441

      16.3. The structure of state-space systems, 443

      16.4. The structure of ARMA systems, 444

      16.5. The realization of state-space systems, 445

      16.5.1. General structure, 445

      16.5.2. Echelon forms, 447

      16.6. The realization of ARMA systems, 448

      16.7. Parametrization, 449

      16.8. Estimation of real-valued parameters, 452

      16.9. Dynamic specification, 454

      INDEX 457

      Recently viewed products

      © 2026 Book Curl

        • American Express
        • Apple Pay
        • Diners Club
        • Discover
        • Google Pay
        • Maestro
        • Mastercard
        • PayPal
        • Shop Pay
        • Union Pay
        • Visa

        Login

        Forgot your password?

        Don't have an account yet?
        Create account