Stationarity and ergodicity of Markov switching positive conditional mean models. (English) Zbl 07569201
Summary: A general Markov-Switching autoregressive conditional mean model, valued in the set of non-negative numbers, is considered. The conditional distribution of this model is a finite mixture of non-negative distributions whose conditional mean follows a GARCH-like dynamics with parameters depending on the state of a Markov chain. Three different variants of the model are examined depending on how the lagged-values of the mixing variable are integrated into the conditional mean equation. The model includes, in particular, Markov mixture versions of various well-known non-negative time series models such as the autoregressive conditional duration model, the integer-valued GARCH (INGARCH) model, and the Beta observation driven model. For the three variants of the model, conditions are given for the existence of a stationary and ergodic solution. The proposed conditions match those already known for Markov-switching GARCH models. We also give conditions for finite marginal moments. Applications to various mixture and Markov mixture count, duration and proportion models are provided.
MSC:
| 62Mxx | Inference from stochastic processes |
| 37M10 | Time series analysis of dynamical systems |
| 60G10 | Stationary stochastic processes |
Keywords:
autoregressive conditional duration; count time series models; finite mixture models; ergodicity; integer-valued GARCH; Markov mixture modelsReferences:
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