Extreme value oriented random field discretization based on an hybrid polynomial chaos expansion — Kriging approach

TL;DR: A hybrid Random Field–Polynomial Chaos Expansion surrogate model is proposed for uncertainty quantification and sensitivity assessment of dams and can improve the results of system identification and dynamic analysis by properly determining the vibration characteristics.

TL;DR: This work develops an original mathematical framework, based on Gaussian Process (GP) models, to construct a global surrogate model of the uncertain directed SoS, with a significantly reduced construction cost compared to the direct GP model approximation of the SoS.

TL;DR: In this paper , the concept of multi-fidelity is proposed to merge different levels of fidelity within a single model with controlled variance, allowing for additional flexibility in choosing the degree of fidelity required in different zones of the design space.

TL;DR: Multi-objective design under uncertainty problems that adopt probabilistic quantities as performance objectives and consider their estimation through stochastic simulation are examined in this paper, focusing on development of a surrogate modeling framework to reduce computational burden for the numerical optimization.

TL;DR: In this article, a representation of stochastic processes and response statistics are represented by finite element method and response representation, respectively, and numerical examples are provided for each of them.

TL;DR: In this paper, the authors used the representations of the noise currents given in Section 2.8 to derive some statistical properties of I(t) and its zeros and maxima.

TL;DR: This work represents the stochastic processes with an optimum trial basis from the Askey family of orthogonal polynomials that reduces the dimensionality of the system and leads to exponential convergence of the error.

TL;DR: A new method for solving stochastic differential equations based on Galerkin projections and extensions of Wiener's polynomial chaos is presented. This method reduces the dimensionality of the system and leads to exponential convergence of the error.