Abstract Parametric derivatives of statistics are highly desired quantities in prediction, design optimization and uncertainty quantification. In the presence of chaos, the rigorous computation of these quantities is certainly possible, but mathematically complicated and computationally expensive. Based on Ruelle’s formalism, this paper shows that the sophisticated linear response algorithm can be dramatically simplified in higher-dimensional systems featuring statistical homogeneity in the physical space. We argue that the contribution of the SRB (Sinai–Ruelle–Bowen) measure gradient, which is an integral yet the most cumbersome part of the full algorithm, is negligible if the objective function is appropriately aligned with u...
We present a general setting in which the formula describing the linear response of the physical mea...
Using the formalism of the Ruelle response theory, we study how the invariant measure of an Axiom A ...
International audienceUncertainties are present in the modeling of dynamical systems and they must b...
In this thesis we develop two algorithms,the non-intrusive shadowing and the fast linear response al...
A gradient of a quantity-of-interest J with respect to problem parameters can augment the utility of...
We consider linear dynamical systems defined by differential algebraic equations. The associated inp...
Abstract—A computationally efficient means for propaga-tion of uncertainty in computational models i...
Uncertainty quantification seeks to provide a quantitative means to understand complex systems that ...
ABSTRACT: Sparse polynomial chaos expansions have recently emerged in uncertainty quantification ana...
Using numerical simulations we show that the response to weak perturbations of a variable of Hamilto...
It is interesting to analyze the parameter sensitivity of mathematical models that describe physical...
We consider linear dynamical systems including random parameters for uncertainty quantification. A s...
International audienceDifferential equations with random parameters have gained significant prominen...
We consider the linear and quadratic higher-order terms associated with the response of the statisti...
We present a general setting in which the formula describing the linear response of the physical mea...
Using the formalism of the Ruelle response theory, we study how the invariant measure of an Axiom A ...
International audienceUncertainties are present in the modeling of dynamical systems and they must b...
In this thesis we develop two algorithms,the non-intrusive shadowing and the fast linear response al...
A gradient of a quantity-of-interest J with respect to problem parameters can augment the utility of...
We consider linear dynamical systems defined by differential algebraic equations. The associated inp...
Abstract—A computationally efficient means for propaga-tion of uncertainty in computational models i...
Uncertainty quantification seeks to provide a quantitative means to understand complex systems that ...
ABSTRACT: Sparse polynomial chaos expansions have recently emerged in uncertainty quantification ana...
Using numerical simulations we show that the response to weak perturbations of a variable of Hamilto...
It is interesting to analyze the parameter sensitivity of mathematical models that describe physical...
We consider linear dynamical systems including random parameters for uncertainty quantification. A s...
International audienceDifferential equations with random parameters have gained significant prominen...
We consider the linear and quadratic higher-order terms associated with the response of the statisti...
We present a general setting in which the formula describing the linear response of the physical mea...
Using the formalism of the Ruelle response theory, we study how the invariant measure of an Axiom A ...
International audienceUncertainties are present in the modeling of dynamical systems and they must b...