Aggregation of predictors for non stationary sub-linear processes and application to online adaptive forecasting of locally stationary time varying autoregressive processes
Résumé
In this work, we study the problem of aggregating a finite number of predictors for non stationary sub-linear processes. We provide oracle inequalities relying essentially on three ingredients: 1) a uniform bound of the $\ell^1$ norm of the time-varying sub-linear coefficients, 2) a Lipschitz assumption on the predictors and 3) moment conditions on the noise appearing in the linear representation. Two kinds of aggregations are considered giving raise to different moment conditions on the noise and more or less sharp oracle inequalities. We apply this approach for deriving an adaptive predictor for locally stationary time varying autoregressive (TVAR) processes. It is obtained by aggregating a finite number of well chosen predictors, each of them enjoying an optimal minimax rate under specific smoothness conditions on the TVAR coefficients. We show that the obtained aggregated estimator achieves a minimax rate while adapting to the unknown smoothness. To prove this result, a lower bound is established for the minimax rate of the prediction risk for the TVAR process. An important feature of this approach is that the aggregated predictor can be computed recursively and is thus applicable in an online prediction context.
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