International audienceIn parameter estimation, it is often desirable to supplement the estimates with an assessment of their quality. A new family of methods proposed by Campi et al. for this purpose is particularly attractive, as it makes it possible to obtain exact, non-asymptotic confidence regions under mild assumptions on the noise distribution. A bottleneck of this approach, however, is the numerical characterization of these confidence regions. So far, it has been carried out by gridding, which provides no guarantee as to its results and is only applicable to low dimensional spaces. This paper shows how interval analysis can contribute to removing this bottleneck
Abstract — In this paper we propose an algorithm for con-structing non-asymptotic confidence regions...
In this paper we propose an algorithm for constructing non-asymptotic confidence regions for paramet...
Sign-Perturbed Sums (SPS) is a recently developed finite sample system identification method that ca...
International audienceIn parameter estimation, it is often desirable to supplement the estimates wit...
accepté à AutomaticaIn parameter estimation, it is often desirable to supplement the estimates with ...
International audienceRecently, a new family of methods has been proposed for characterizing accurac...
International audienceSPS is one of the two methods proposed recently by Campi et al. to obtain exac...
Sign-Perturbed Sums (SPS) is a system identification method that constructs non-asymptotic confidenc...
In this paper we offer a unified approach to the problem of nonparametric regression on the unit in...
In this paper we offer a unified approach to the problem of nonparametric regression on the unit int...
© 2020 Masoud Moravej KhorasaniSystem identification deals with the problem of building mathematical...
In this paper we consider the problem of constructing confidence regions for the parameters of ident...
In this paper, the distributed computation of confidence regions for parameter estimation is conside...
This lecture presents some methods which we can apply in searching for confidence regions and interv...
Sign-Perturbed Sums (SPS) is a system identification method that constructs non-asymptotic confidenc...
Abstract — In this paper we propose an algorithm for con-structing non-asymptotic confidence regions...
In this paper we propose an algorithm for constructing non-asymptotic confidence regions for paramet...
Sign-Perturbed Sums (SPS) is a recently developed finite sample system identification method that ca...
International audienceIn parameter estimation, it is often desirable to supplement the estimates wit...
accepté à AutomaticaIn parameter estimation, it is often desirable to supplement the estimates with ...
International audienceRecently, a new family of methods has been proposed for characterizing accurac...
International audienceSPS is one of the two methods proposed recently by Campi et al. to obtain exac...
Sign-Perturbed Sums (SPS) is a system identification method that constructs non-asymptotic confidenc...
In this paper we offer a unified approach to the problem of nonparametric regression on the unit in...
In this paper we offer a unified approach to the problem of nonparametric regression on the unit int...
© 2020 Masoud Moravej KhorasaniSystem identification deals with the problem of building mathematical...
In this paper we consider the problem of constructing confidence regions for the parameters of ident...
In this paper, the distributed computation of confidence regions for parameter estimation is conside...
This lecture presents some methods which we can apply in searching for confidence regions and interv...
Sign-Perturbed Sums (SPS) is a system identification method that constructs non-asymptotic confidenc...
Abstract — In this paper we propose an algorithm for con-structing non-asymptotic confidence regions...
In this paper we propose an algorithm for constructing non-asymptotic confidence regions for paramet...
Sign-Perturbed Sums (SPS) is a recently developed finite sample system identification method that ca...