988 resultados para Modèles ARMA
Resumo:
[Vente (Art). 1840-01-27. Paris]
Resumo:
[Vente (Art). 1841-02-19. Paris]
Resumo:
[Vente (Art). 1846-01-29. Paris]
Resumo:
[Vente (Art). 1845-08-04. Paris]
Resumo:
[Vente (Art). 1840-10-05. Paris]
Resumo:
Tesis (Maestría en Ciencias con Especialidad en Química Biomédica) UANL
Resumo:
Tesis (Maestría en Ciencias Penales) U.A.N.L.
Resumo:
Rapport de recherche
Resumo:
Rapport de recherche
Resumo:
In this paper, we introduce a new approach for volatility modeling in discrete and continuous time. We follow the stochastic volatility literature by assuming that the variance is a function of a state variable. However, instead of assuming that the loading function is ad hoc (e.g., exponential or affine), we assume that it is a linear combination of the eigenfunctions of the conditional expectation (resp. infinitesimal generator) operator associated to the state variable in discrete (resp. continuous) time. Special examples are the popular log-normal and square-root models where the eigenfunctions are the Hermite and Laguerre polynomials respectively. The eigenfunction approach has at least six advantages: i) it is general since any square integrable function may be written as a linear combination of the eigenfunctions; ii) the orthogonality of the eigenfunctions leads to the traditional interpretations of the linear principal components analysis; iii) the implied dynamics of the variance and squared return processes are ARMA and, hence, simple for forecasting and inference purposes; (iv) more importantly, this generates fat tails for the variance and returns processes; v) in contrast to popular models, the variance of the variance is a flexible function of the variance; vi) these models are closed under temporal aggregation.
Resumo:
La causalité au sens de Granger est habituellement définie par la prévisibilité d'un vecteur de variables par un autre une période à l'avance. Récemment, Lutkepohl (1990) a proposé de définir la non-causalité entre deux variables (ou vecteurs) par la non-prévisibilité à tous les délais dans le futur. Lorsqu'on considère plus de deux vecteurs (ie. lorsque l'ensemble d'information contient les variables auxiliaires), ces deux notions ne sont pas équivalentes. Dans ce texte, nous généralisons d'abord les notions antérieures de causalités en considérant la causalité à un horizon donné h arbitraire, fini ou infini. Ensuite, nous dérivons des conditions nécessaires et suffisantes de non-causalité entre deux vecteurs de variables (à l'intérieur d'un plus grand vecteur) jusqu'à un horizon donné h. Les modèles considérés incluent les autoregressions vectorielles, possiblement d'ordre infini, et les modèles ARIMA multivariés. En particulier, nous donnons des conditions de séparabilité et de rang pour la non-causalité jusqu'à un horizon h, lesquelles sont relativement simples à vérifier.
Resumo:
This note investigates the adequacy of the finite-sample approximation provided by the Functional Central Limit Theorem (FCLT) when the errors are allowed to be dependent. We compare the distribution of the scaled partial sums of some data with the distribution of the Wiener process to which it converges. Our setup is purposely very simple in that it considers data generated from an ARMA(1,1) process. Yet, this is sufficient to bring out interesting conclusions about the particular elements which cause the approximations to be inadequate in even quite large sample sizes.
Resumo:
The GARCH and Stochastic Volatility paradigms are often brought into conflict as two competitive views of the appropriate conditional variance concept : conditional variance given past values of the same series or conditional variance given a larger past information (including possibly unobservable state variables). The main thesis of this paper is that, since in general the econometrician has no idea about something like a structural level of disaggregation, a well-written volatility model should be specified in such a way that one is always allowed to reduce the information set without invalidating the model. To this respect, the debate between observable past information (in the GARCH spirit) versus unobservable conditioning information (in the state-space spirit) is irrelevant. In this paper, we stress a square-root autoregressive stochastic volatility (SR-SARV) model which remains true to the GARCH paradigm of ARMA dynamics for squared innovations but weakens the GARCH structure in order to obtain required robustness properties with respect to various kinds of aggregation. It is shown that the lack of robustness of the usual GARCH setting is due to two very restrictive assumptions : perfect linear correlation between squared innovations and conditional variance on the one hand and linear relationship between the conditional variance of the future conditional variance and the squared conditional variance on the other hand. By relaxing these assumptions, thanks to a state-space setting, we obtain aggregation results without renouncing to the conditional variance concept (and related leverage effects), as it is the case for the recently suggested weak GARCH model which gets aggregation results by replacing conditional expectations by linear projections on symmetric past innovations. Moreover, unlike the weak GARCH literature, we are able to define multivariate models, including higher order dynamics and risk premiums (in the spirit of GARCH (p,p) and GARCH in mean) and to derive conditional moment restrictions well suited for statistical inference. Finally, we are able to characterize the exact relationships between our SR-SARV models (including higher order dynamics, leverage effect and in-mean effect), usual GARCH models and continuous time stochastic volatility models, so that previous results about aggregation of weak GARCH and continuous time GARCH modeling can be recovered in our framework.
