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1987 | Buch

Introduction Kapitel lesen Erstes Kapitel lesen

State Space Modeling of Time Series

verfasst von: Prof. Masanao Aoki

Verlag: Springer Berlin Heidelberg

Buchreihe : Universitext

Enthalten in: Professional Book Archive

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Über dieses Buch

model's predictive capability? These are some of the questions that need to be answered in proposing any time series model construction method. This book addresses these questions in Part II. Briefly, the covariance matrices between past data and future realizations of time series are used to build a matrix called the Hankel matrix. Information needed for constructing models is extracted from the Hankel matrix. For example, its numerically determined rank will be the di­ mension of the state model. Thus the model dimension is determined by the data, after balancing several sources of error for such model construction. The covariance matrix of the model forecasting error vector is determined by solving a certain matrix Riccati equation. This matrix is also the covariance matrix of the innovation process which drives the model in generating model forecasts. In these model construction steps, a particular model representation, here referred to as balanced, is used extensively. This mode of model representation facilitates error analysis, such as assessing the error of using a lower dimensional model than that indicated by the rank of the Hankel matrix. The well-known Akaike's canonical correlation method for model construc­ tion is similar to the one used in this book. There are some important differ­ ences, however. Akaike uses the normalized Hankel matrix to extract canonical vectors, while the method used in this book does not normalize the Hankel ma­ trix.

Inhaltsverzeichnis

Frontmatter
1. Introduction
Abstract
Study of time series has a history much older than modem system theory. Probability theorists, statisticians and economitricians have all contributed to our understanding of time series over the past several decades, as is evidenced by many well established books. One may wonder what system theory can add to this well established field and doubt if any new perspective or insight can be gained by this relative newcomer to the field. The history of science shows us, however, that a given problem can fruitfully be examined by different disciplines, partly because when it is viewed from new perspectives, implications of alternative assumptions are explored by researchers with different backgrounds or interests, and partly because new techniques developed elsewhere are imported to explore areas left untouched by the discipline in which the problem originated. Although a latecomer to the field of time series analysis, system theory has introduced a set of viewpoints, concepts and tools sufficiently different from the traditional ones, and these have proved effective in dealing with vector-valued time-indexed data.
Masanao Aoki
2. The Notion of State
Abstract
Behavior of dynamic systems can be conveniently and succinctly described by introducing the notions of state space and state vectors. Time series behavior may be so complex that its description may go beyond the framework of finite-dimensional state space, i.e., of finite dimensional dynamic models. When a finite dimensional state space does not suffice to capture time series behavior, then the dynamics are of infinite dimensions. In the transform domain description, spectral density functions of finite dimensional dynamics are rational functions of frequencies. They are irrational functions for infinite dimensional dynamics.
Masanao Aoki
3. Representation of Time Series
Abstract
Basically, one can describe time series either in the time domain or in the frequency domain. Difference equations are used in the former, and frequency spectra or transfer functions are used in the latter to specify the dynamic structure of time series. Both representations are used in this book. This chapter discusses time series models first in the time-domain, then using transfer functions in the frequency domain. The time domain representation of time series can further be divided into two broad and different modes: the traditional and the newer Markovian, i.e., state space representation mentioned in Chapter 2.
Masanao Aoki
4. State Space and ARMA Representation
Abstract
This chapter establishes the equivalence of time series model descriptions in terms of well-known ARMA models and less familiar Markovian (state space) models, introduces the notion of minimal dimensional models and the associated minimal dimensional state vectors, and presents several methods for putting models into state space forms in general and into the observable canonical form in particular. Although econometricians and statisticians are perhaps less accustomed to the state space representation of time series, this representation is quite useful in building innovation models of times series.
Masanao Aoki
5. Properties of State Space Models
Abstract
This chapter briefly discusses three properties of dynamic systems in state space form that are important in our model building procedure. They are stability, observability and reachability (controllability). The notion of stability is well known. A dynamic system is asymptotically stable if the effects of initial conditions vanish asymptotically over time. The other two properties are less familiar to statisticians and econometricians. They may be motivated by requiring that state space model representations be parsimonious, i.e., by the “minimality” of state vector dimension. More on these properties, as well as economic examples of state space models, are found in Aoki [1976].
Masanao Aoki
6. Innovation Processes
Abstract
The desire to predict future realizations of time series is one of the basic motivations for analyzing a time series and building its model. In general, predicting time series with any degree of accuracy is rather difficult for several reasons, some of which are mentioned in Chapter 3. This chapter considers a special class of time series for which prediction is relatively straightforward. A more general class of time series is taken up in Chapter 7.
Masanao Aoki
7. Kalman Filters
Abstract
This chapter derives Kalman filters in two stages; first, for innovation models, and then for general state space models. The first stage also serves to introduce a particular way of summarizing information contained in a data set as an output of a Kalman filter, a topic also elaborated upon in Chapter 8. Finally, this chapter introduces a non-recursive method for solving the matrix Riccati equation needed to determine the optimal filter gain matrix.
Masanao Aoki
8. State Vectors and Optimality Measures
Abstract
The state vector introduced in Chapter 7 is by no means the only way of summarizing information in data sets. Two other choices, one used by Akaike and the other by Arun et al., and the implied state transition dynamics, are discussed in this chapter.
Masanao Aoki
9. Computation of System Matrices
Abstract
This chapter is central to this book and describes how to compute system matrices of state space models from given sets of time series data. The dimensions of the models are determined by the numerical ranks of the Hankel matrices constructed from the sample covariance matrices of data sets. In this way the dimensions of the models are data determined. Among equivalent representations of models of given dimensions, the one called (intenally) balanced is chosen for its advantages in conducting error analysis and in constructing lower dimensional approximate models.
Masanao Aoki
10. Approximate Models and Error Analysis
Abstract
Exogenous disturbances affect time series variables in complex and varied ways. Their relationships are usually only approximately captured by models. In the frequency domain, rational transfer functions of the models are best viewed as approximations to more complex rational, or possibly irrational, transfer functions. In the time domain, finite-dimensional state space (innovation) models merely approximate dynamic phenomena of greater complexity that can not be conveniently captured. Model builders can only hope to reproduce some salient features of actual dynamics by judicious choice of the dimension and the values of model system matrices, and by analyzing the consequences of adding (deleting) a time series from the data vector, or of retaining (dropping) correlations between some of the data components.
Masanao Aoki
11. Numerical Examples
Abstract
This chapter presents examples of models constructed from time series available in the literature and from macroeconomic time series of the United States of America, the United Kingdom, West Germany, and Japan. Actual macroeconomic time series used in model construction are described in the data appendix. Small scale examples are presented first. Some of the models constructed by the method of this book are also compared with the vector autoregressive (VAR) models computed by a commercially available computer program later in this chapter. Models of dimension n* constructed using K sub-blocks of Hankel matrices are denoted hy m(K, n*). These models thus utilize information contained in the first 2K-1 covariance matrices of the data vectors.
Masanao Aoki
Erratum to: Properties of State Space Models
Masanao Aoki
Erratum to: Computation of System Matrices
Masanao Aoki
Erratum
Masanao Aoki
Backmatter
Metadaten
Titel
State Space Modeling of Time Series
verfasst von
Prof. Masanao Aoki
Copyright-Jahr
1987
Verlag
Springer Berlin Heidelberg
Electronic ISBN
978-3-642-96985-0
Print ISBN
978-3-540-17257-4
DOI
https://doi.org/10.1007/978-3-642-96985-0