10.5 Higher Dimensional Volatility Models
In this section, we make use of the sequential nature of Cholesky decomposition to suggest a strategy for building a high-dimensional volatility model. Again write the vector return series as 
. The mean equations for 
can be specified by using the methods of Chapter 8. A simple vector AR model is often sufficient. Here we focus on building a volatility model using the shock process 
.
Based on the discussion of Cholesky decomposition in Section 10.3, the orthogonal transformation from ait to bit only involves bjt for j < i. In addition, the time-varying volatility models built in Section 10.4 appear to be nested in the sense that the model for gii, t depends only on quantities related to bjt for j < i. Consequently, we consider the following sequential procedure to build a multivariate volatility model:
1. Select a market index or a stock return that is of major interest. Build a univariate volatility model for the selected return series.
2. Augment a second return series to the system, perform the orthogonal transformation on the shock process of this new return series, and build a bivariate volatility model for the system. The parameter estimates ...
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