Autoregressive–moving-average model

The notation ARMA(p, q) refers to the model with p autoregressive terms and q moving-average terms. This model contains the AR(p) and MA(q) models,

$X_t = c %2B \varepsilon_t %2B \sum_{i=1}^p \varphi_i X_{t-i} %2B \sum_{i=1}^q \theta_i \varepsilon_{t-i}.\,$

Note about the error terms

The error terms $\varepsilon_t$ are generally assumed to be independent identically-distributed random variables (i.i.d.) sampled from a normal distribution with zero mean: $\varepsilon_t$ ~ N(0,σ²) where σ² is the variance. These assumptions may be weakened but doing so will change the properties of the model. In particular, a change to the i.i.d. assumption would make a rather fundamental difference.

Specification in terms of lag operator

In some texts the models will be specified in terms of the lag operator L. In these terms then the AR(p) model is given by

$\varepsilon_t = \left(1 - \sum_{i=1}^p \varphi_i L^i\right) X_t = \varphi X_t\,$

where $\varphi$ represents the polynomial

$\varphi = 1 - \sum_{i=1}^p \varphi_i L^i.\,$

The MA(q) model is given by

$X_t = \left(1 %2B \sum_{i=1}^q \theta_i L^i\right) \varepsilon_t = \theta \varepsilon_t , \,$

where θ represents the polynomial

$\theta= 1 %2B \sum_{i=1}^q \theta_i L^i .\,$

Finally, the combined ARMA(p, q) model is given by

$\left(1 - \sum_{i=1}^p \varphi_i L^i\right) X_t = \left(1 %2B \sum_{i=1}^q \theta_i L^i\right) \varepsilon_t \, ,$

or more concisely,

$\varphi X_t = \theta \varepsilon_t \, .$

Alternative notation

Some authors, including Box, Jenkins & Reinsel^[1] use a different convention for the autoregression coefficients. This allows all the polynomials involving the lag operator to appear in a similar form throughout. Thus the ARMA model would be written as

$\left(1 %2B \sum_{i=1}^p \phi_i L^i\right) X_t = \left(1 %2B \sum_{i=1}^q \theta_i L^i\right) \varepsilon_t \, .$

Fitting models

ARMA models in general can, after choosing p and q, be fitted by least squares regression to find the values of the parameters which minimize the error term. It is generally considered good practice to find the smallest values of p and q which provide an acceptable fit to the data. For a pure AR model the Yule-Walker equations may be used to provide a fit.

Finding appropriate values of p and q in the ARMA(p,q) model can be facilitated by plotting the partial autocorrelation functions for an estimate of p, and likewise using the autocorrelation functions for an estimate of q. Further information can be gleaned by considering the same functions for the residuals of a model fitted with an initial selection of p and q.

Brockwell and Davis^[2] (p.273) recommend using AICc for finding p and q.

Implementations in statistics packages

In R, the tseries package includes an arma function. The function is documented in "Fit ARMA Models to Time Series". or use stats::arima
Mathematica has a complete library of time series functions including ARMA ^[3]
MATLAB includes a function ar to estimate AR models, see here for more details.
IMSL Numerical Libraries are libraries of numerical analysis functionality including ARMA and ARIMA procedures implemented in standard programming languages like C, Java, C# .NET, and Fortran.
gretl can also estimate ARMA models, see here where it's mentioned.
GNU Octave can estimate AR models using functions from the extra package octave-forge.
SuanShu is a Java library of numerical methods, including comprehensive statistics packages, in which univariate/multivariate ARMA, ARIMA, ARMAX, etc. models are implemented in an object-oriented approach. These implementations are documented in "SuanShu, a Java numerical and statistical library".
SAS has a econometric package, ETS, that estimates ARIMA models see here for more details.

Applications

ARMA is appropriate when a system is a function of a series of unobserved shocks (the MA part) as well as its own behavior. For example, stock prices may be shocked by fundamental information as well as exhibiting technical trending and mean-reversion effects due to market participants.

Generalizations

The dependence of X_t on past values and the error terms ε_t is assumed to be linear unless specified otherwise. If the dependence is nonlinear, the model is specifically called a nonlinear moving average (NMA), nonlinear autoregressive (NAR), or nonlinear autoregressive–moving-average (NARMA) model.

Autoregressive–moving-average models can be generalized in other ways. See also autoregressive conditional heteroskedasticity (ARCH) models and autoregressive integrated moving average (ARIMA) models. If multiple time series are to be fitted then a vector ARIMA (or VARIMA) model may be fitted. If the time-series in question exhibits long memory then fractional ARIMA (FARIMA, sometimes called ARFIMA) modelling may be appropriate: see Autoregressive fractionally integrated moving average. If the data is thought to contain seasonal effects, it may be modeled by a SARIMA (seasonal ARIMA) or a periodic ARMA model.

Another generalization is the multiscale autoregressive (MAR) model. A MAR model is indexed by the nodes of a tree, whereas a standard (discrete time) autoregressive model is indexed by integers.

Note that the ARMA model is a univariate model. Extensions for the multivariate case are the Vector Autoregression (VAR) and Vector Autoregression Moving-Average (VARMA).

Autoregressive–moving-average model with exogenous inputs model (ARMAX model)

The notation ARMAX(p, q, b) refers to the model with p autoregressive terms, q moving average terms and b exogenous inputs terms. This model contains the AR(p) and MA(q) models and a linear combination of the last b terms of a known and external time series $d_t$ . It is given by:

$X_t = \varepsilon_t %2B \sum_{i=1}^p \varphi_i X_{t-i} %2B \sum_{i=1}^q \theta_i \varepsilon_{t-i} %2B \sum_{i=1}^b \eta_i d_{t-i}.\,$

where $\eta_1, \ldots, \eta_b$ are the parameters of the exogenous input $d_t$ .

Some nonlinear variants of models with exogenous variables have been defined: see for example Nonlinear autoregressive exogenous model.

Statistical packages implement the ARMAX model through the use of "exogenous" or "independent" variables. Care must be taken when interpreting the output of those packages, because the estimated parameters usually (for example, in R^[4] and gretl) refer to the regression:

$X_t - m_t = \varepsilon_t %2B \sum_{i=1}^p \varphi_i (X_{t-i} - m_{t-i}) %2B \sum_{i=1}^q \theta_i \varepsilon_{t-i}.\,$

where m_t incorporates all exogenous (or independent) variables:

$m_t = c %2B \sum_{i=1}^b \eta_i d_{t-i}.\,$

References

^ George Box, Gwilym M. Jenkins, and Gregory C. Reinsel. Time Series Analysis: Forecasting and Control, third edition. Prentice-Hall, 1994.
^ Brockwell, P.J., and Davis, R.A. Time Series: Theory and Methods, 2nd ed. Springer, 2009.
^ Time series features in Mathematica
^ ARIMA Modelling of Time Series, R documentation

Mills, Terence C. Time Series Techniques for Economists. Cambridge University Press, 1990.
Percival, Donald B. and Andrew T. Walden. Spectral Analysis for Physical Applications. Cambridge University Press, 1993.

Autoregressive–moving-average model

Contents

Autoregressive model

Moving-average model

Autoregressive–moving-average model

Note about the error terms

Specification in terms of lag operator

Alternative notation

Fitting models

Implementations in statistics packages

Applications

Generalizations

Autoregressive–moving-average model with exogenous inputs model (ARMAX model)

See also

References