Time Series: Theory and Methods pp 391-446 | Cite as

# Multivariate Time Series

## Abstract

Many time series arising in practice are best considered as components of some vector-valued (multivariate) time series {**X** _{ t }} whose specification includes not only the serial dependence of each component series {*X* _{ ti }} but also the interdependence between different component series {*X* _{ ti }} and {*X* _{ tj }}. From a second order point of view a stationary multivariate time series is determined by its mean vector, μ = *E* **X** _{ t } and its covariance matrices Г(*h*) = *E*(**X** _{ t }+_{ h } **X** ^{′} _{t}) — μμ′, *h* = 0, ±1,.... Most of the basic theory of univariate time series extends in a natural way to multivariate series but new problems arise. In this chapter we show how the techniques developed earlier for univariate series are extended to the multivariate case. Estimation of the basic quantities μ and Г(·) is considered in Section 11.2. In Section 11.3 we introduce multivariate **ARMA** processes and develop analogues of some of the univariate results in Chapter 3. The prediction of stationary multivariate processes, and in particular of **ARMA** processes, is treated in Section 11.4 by means of a multivariate generalization of the innovations algorithm used in Chapter 5. This algorithm is then applied in Section 11.5 to simplify the calculation of the likelihood of the observations {**X** _{1}, **X** _{2},..., **X** _{n}} of a multivariate **ARMA** process. Estimation of parameters using maximum likelihood and (for autoregressive models) the Yule-Walker equations is briefly considered. In Section 11.6 we discuss the cross spectral density of a bivariate stationary process {**X** _{ t }} and its interpretation in terms of the spectral representation of {**X** _{ t }}.

## Keywords

Spectral Representation Phase Spectrum Multivariate Time Series Cross Spectrum ARMA Process## Preview

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