This paper deals with the application of the support vector machine (SVM) and the least-squares SVM regressions to the uncertainty quantification of complex systems with a high-dimensional parameter space. The above regression techniques are used to build accurate and compact surrogate models of the system responses from a limited set of training samples. The accuracy and the feasibility of the proposed modeling techniques are then investigated by comparing their results with the ones predicted by a sparse polynomial chaos expansion by considering two real-life problems with 8 and 30 random variables, respectively
In the context of complex industrial systems and civil infrastructures, taking into account uncerta...
In this paper, we adopt the so-called sparse polynomial chaos metamodel for the uncertainty quantifi...
Complex computational models are used nowadays in all fields of applied sciences to predict the beha...
This paper presents a preliminary version of a probabilistic model for the uncertainty quantificatio...
This paper presents a preliminary application of the support vector machine regression to the modeli...
This paper presents a preliminary version of a probabilistic model for the uncertainty quantificatio...
Today’s spread of power distribution networks, with the installation of a significant number of rene...
This paper presents an innovative modeling strategy for the construction of efficient and compact su...
This paper provides a quick overview on three machine learning regression techniques for the uncerta...
Nowadays, computational models are used in virtually all fields of applied sciences and engineering ...
This paper investigates the application of support vector machine to the modeling of high-speed inte...
This paper introduces a probabilistic machine learning framework for the uncertainty quantification ...
Nowadays computational models are used in virtually all fields of applied sciences and engineering t...
Computational models are used in virtually all fields of applied sciences and engineering to predict...
This paper discusses the application of a probabilistic surrogate modeling technique, based on Gauss...
In the context of complex industrial systems and civil infrastructures, taking into account uncerta...
In this paper, we adopt the so-called sparse polynomial chaos metamodel for the uncertainty quantifi...
Complex computational models are used nowadays in all fields of applied sciences to predict the beha...
This paper presents a preliminary version of a probabilistic model for the uncertainty quantificatio...
This paper presents a preliminary application of the support vector machine regression to the modeli...
This paper presents a preliminary version of a probabilistic model for the uncertainty quantificatio...
Today’s spread of power distribution networks, with the installation of a significant number of rene...
This paper presents an innovative modeling strategy for the construction of efficient and compact su...
This paper provides a quick overview on three machine learning regression techniques for the uncerta...
Nowadays, computational models are used in virtually all fields of applied sciences and engineering ...
This paper investigates the application of support vector machine to the modeling of high-speed inte...
This paper introduces a probabilistic machine learning framework for the uncertainty quantification ...
Nowadays computational models are used in virtually all fields of applied sciences and engineering t...
Computational models are used in virtually all fields of applied sciences and engineering to predict...
This paper discusses the application of a probabilistic surrogate modeling technique, based on Gauss...
In the context of complex industrial systems and civil infrastructures, taking into account uncerta...
In this paper, we adopt the so-called sparse polynomial chaos metamodel for the uncertainty quantifi...
Complex computational models are used nowadays in all fields of applied sciences to predict the beha...