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In statistics, Self-Exciting Threshold AutoRegressive (SETAR) models are typically applied to time series data as an extension of autoregressive models, in order to allow for higher degree of flexibility in model parameters through a regime switching behaviour.
Given a time series of data xt, the SETAR model is a tool for understanding and, perhaps, predicting future values in this series, assuming that the behaviour of the series changes once the series enters a different regime. The switch from one regime to another depends on the past values of the x series (hence the Self-Exciting portion of the name).
The model consists of k autoregressive (AR) parts, each for a different regime. The model is usually referred to as the SETAR(k, p) model where k is the number of regimes and p is the order of the autoregressive part (since those can differ between regimes, the p portion is sometimes dropped and models are denoted simply as SETAR(k).
Definition
Autoregressive Models
Consider a simple AR(p) model for a time series yt
where:
- for i=1,2,...,p are autoregressive coefficients, assumed to be constant over time;
- stands for white-noise error term with constant variance.
written in a following vector form:
where:
- is a column vector of variables;
- is the vector of parameters :;
- stands for white-noise error term with constant variance.
SETAR as an Extension of the Autoregressive Model
SETAR models were introduced by Howell Tong in 1977 and more fully developed in the seminal paper (Tong and Lim, 1980). They can be thought of in terms of extension of autoregressive models, allowing for changes in the model parameters according to the value of weakly exogenous threshold variable zt, assumed to be past values of y, e.g. yt-d, where d is the delay parameter, triggering the changes.
Defined in this way, SETAR model can be presented as follows:
where:
- is a column vector of variables;
- are k+1 non-trivial thresholds dividing the domain of zt into k different regimes.
The SETAR model is a special case of Tong's general threshold autoregressive models (Tong and Lim, 1980, p. 248). The latter allows the threshold variable to be very flexible, such as an exogenous time series in the open-loop threshold autoregressive system (Tong and Lim, 1980, p. 249), a Markov chain in the Markov-chain driven threshold autoregressive model (Tong and Lim, 1980, p. 285), which is now also known as the Markov switching model.
For a comprehensive review of developments over the 30 years since the birth of the model, see Tong (2011).
Basic Structure
In each of the k regimes, the AR(p) process is governed by a different set of p variables :. In such setting, a change of the regime (because the past values of the series yt-d surpassed the threshold) causes a different set of coefficients : to govern the process y.
See also
References
- Hansen, B.E. (1997). Inference in TAR Models, Studies in Nonlinear Dynamics and Econometrics, 2, 1-14.
- Tong, H. & Lim, K. S. (1980) "Threshold Autoregression, Limit Cycles and Cyclical Data (with discussion)", Journal of the Royal Statistical Society, Series B, 42, 245-292.
- Tong, H. (1983) "Threshold Models in Non-linear Time Series Analysis". Lecture Notes in Statistics, Springer-Verlag.
- Tong, H. (1990). Non-Linear Time Series: A Dynamical System Approach. Oxford University Press.
- Tong, H. (2007). "Birth of the time series model". Statistica Sinica, 17, 8-14.
- Tong, H. (2011). "Threshold models in time series analysis —30 years on (with discussions by P.Whittle, M.Rosenblatt, B.E.Hansen, P.Brockwell, N.I.Samia & F.Battaglia)". Statistics & Its Interface, 4, 107-136.
[1] [2] http://www.ssc.wisc.edu/~bhansen/papers/saii_11.pdf
- Tsay, R.S. (1989). Testing and Modeling Threshold Autoregressive Processes, Journal of the American Statistical Association, 84 (405), 231-240.