par Nisol, Gilles 
Président du jury Gassner, Marjorie
Promoteur Hörmann, Siegfried
Co-Promoteur Paindaveine, Davy
Publication Non publié, 2018-12-20
Président du jury Gassner, Marjorie
Promoteur Hörmann, Siegfried
Co-Promoteur Paindaveine, Davy
Publication Non publié, 2018-12-20
Thèse de doctorat
| Résumé : | The thesis is dedicated to time series analysis for functional data and contains three original parts. In the first part, we derive statistical tests for the presence of a periodic component in a time series of functions. We consider both the traditional setting in which the periodic functional signal is contaminated by functional white noise, and a more general setting of a contaminating process which is weakly dependent. Several forms of the periodic component are considered. Our tests are motivated by the likelihood principle and fall into two broad categories, which we term multivariate and fully functional. Overall, for the functional series that motivate this research, the fully functional tests exhibit a superior balance of size and power. Asymptotic null distributions of all tests are derived and their consistency is established. Their finite sample performance is examined and compared by numerical studies and application to pollution data. In the second part, we consider vector autoregressive processes (VARs) with innovations having a singular covariance matrix (in short singular VARs). These objects appear naturally in the context of dynamic factor models. The Yule-Walker estimator of such a VAR is problematic, because the solution of the corresponding equation system tends to be numerically rather unstable. For example, if we overestimate the order of the VAR, then the singularity of the innovations renders the Yule-Walker equation system singular as well. Moreover, even with correctly selected order, the Yule-Walker system tends be close to singular in finite sample. We show that this has a severe impact on predictions. While the asymptotic rate of the mean square prediction error (MSPE) can be just like in the regular (non-singular) case, the finite sample behavior is suffering. This effect turns out to be particularly dramatic in context of dynamic factor models, where we do not directly observe the so-called common components which we aim to predict. Then, when the data are sampled with some additional error, the MSPE often gets severely inflated. We explain the reason for this phenomenon and show how to overcome the problem. Our numerical results underline that it is very important to adapt prediction algorithms accordingly. In the third part, we set up theoretical foundations and a practical method to forecast multiple functional time series (FTS). In order to do so, we generalize the static factor model to the case where cross-section units are FTS. We first derive a representation result. We show that if the first r eigenvalues of the covariance operator of the cross-section of n FTS are unbounded as n diverges and if the (r+1)th eigenvalue is bounded, then we can represent the each FTS as a sum of a common component driven by r factors and an idiosyncratic component. We suggest a method of estimation and prediction of such a model. We assess the performances of the method through a simulation study. Finally, we show that by applying our method to a cross-section of volatility curves of the stocks of S&P100, we have a better prediction accuracy than by limiting the analysis to individual FTS. |
