The paper investigates asymptotically efficient inference in general likelihood models with time varying parameters. Parameter path estimators and tests of parameter constancy are evaluated by their weighted average risk and weighted average power, respectively. The weight function is proportional to the distribution of a Gaussian process, and focusses on local parameter instabilities that cannot be detected with certainty even in the limit. It is shown that asymptotically, the sample information about the parameter path is efficiently summarized by a Gaussian pseudo model. This approximation leads to computationally convenient formulas for efficient path estimators and test statistics, and unifies the theory of stability testing and parame...
in pressInternational audienceWe develop a complete methodology for detecting time varying or non-ti...
Dynamic regression or state space models provide a flexible framework for analyzing non-Gaussian tim...
Very preliminary draft: comments welcome, please do not quote without permission of authors. We prop...
The paper investigates asymptotically efficient inference in general likelihood models with time var...
The paper considers time series GMM models where a subset of the parameters are time varying. The ma...
This dissertation addresses various issues related to statistical inference in the context of param...
There are a large number of tests for parameter instability designed for specific types of unstable ...
The paper offers a novel unified approach to studying the accuracy of parameter estimation for a tim...
In the following article we consider approximate Bayesian parameter inference for observation driven...
We develop non-parametric instrumental variable estimation and inferential theory for econometric mo...
In this paper we derive tests for parameter constancy when the data generating process is non-statio...
The dissertation consists of three chapters on econometric methods related to parameter instability,...
We develop a novel asymptotic theory for local polynomial (quasi-) maximum-likelihood estimators of ...
In this article, we consider approximate Bayesian parameter inference for observation-driven time se...
In this article, we consider approximate Bayesian parameter inference for observation-driven time se...
in pressInternational audienceWe develop a complete methodology for detecting time varying or non-ti...
Dynamic regression or state space models provide a flexible framework for analyzing non-Gaussian tim...
Very preliminary draft: comments welcome, please do not quote without permission of authors. We prop...
The paper investigates asymptotically efficient inference in general likelihood models with time var...
The paper considers time series GMM models where a subset of the parameters are time varying. The ma...
This dissertation addresses various issues related to statistical inference in the context of param...
There are a large number of tests for parameter instability designed for specific types of unstable ...
The paper offers a novel unified approach to studying the accuracy of parameter estimation for a tim...
In the following article we consider approximate Bayesian parameter inference for observation driven...
We develop non-parametric instrumental variable estimation and inferential theory for econometric mo...
In this paper we derive tests for parameter constancy when the data generating process is non-statio...
The dissertation consists of three chapters on econometric methods related to parameter instability,...
We develop a novel asymptotic theory for local polynomial (quasi-) maximum-likelihood estimators of ...
In this article, we consider approximate Bayesian parameter inference for observation-driven time se...
In this article, we consider approximate Bayesian parameter inference for observation-driven time se...
in pressInternational audienceWe develop a complete methodology for detecting time varying or non-ti...
Dynamic regression or state space models provide a flexible framework for analyzing non-Gaussian tim...
Very preliminary draft: comments welcome, please do not quote without permission of authors. We prop...