A Data-Driven Approach to PDE-Constrained Optimization Under Uncertainty
Abstract not provided.
Publications
A Data-Driven Approach to PDE-Constrained Optimization under Uncertainty
Abstract not provided.
A Data-Driven Approach to PDE-Constrained Optimization under Uncertainty
Abstract not provided.
A Data-Driven Approach to PDE-Constrained Optimization under Uncertainty
Abstract not provided.
A Data-Driven Approach to PDE-Constrained Optimization under Uncertainty
Abstract not provided.
A Data-Driven Approach to PDE-Constrained Optimization under Uncertainty
Abstract not provided.
A Data-Driven Approach to PDE-Constrained Optimization under Uncertainty
Abstract not provided.
A Data-Driven Approach to PDE-Constrained Optimization under Uncertainty
Abstract not provided.
A Full-Space Approach to Stochastic Optimization with Simulation Constraints
Abstract not provided.
A Locally Adapted Reduced Basis Method for Solving Risk-Averse PDE-Constrained Optimization Problems
Abstract not provided.
A Locally Adapted Reduced Basis Method for Solving Risk-Averse PDE-Constrained Optimization Problems
Abstract not provided.
A massively parallel framework for source and material inverse problems in structural acoustics
Abstract not provided.
A measure approximation for distributionally robust PDE-constrained optimization problems
SIAM Journal on Numerical Analysis
In numerous applications, scientists and engineers acquire varied forms of data that partially characterize the inputs to an underlying physical system. This data is then used to inform decisions such as controls and designs. Consequently, it is critical that the resulting control or design is robust to the inherent uncertainties associated with the unknown probabilistic characterization of the model inputs. In this paper, we consider optimal control and design problems constrained by partial differential equations with uncertain inputs. We do not assume a known probabilistic model for the inputs, but rather we formulate the problem as a distributionally robust optimization problem where the outer minimization problem determines the control or design, while the inner maximization problem determines the worst-case probability measure that matches desired characteristics of the data. We analyze the inner maximization problem in the space of measures and introduce a novel measure approximation technique, based on the approximation of continuous functions, to discretize the unknown probability measure. We prove consistency of our approximated min-max problem and conclude with numerical results.
A Primal-Dual Algorithm for Large-Scale Risk Minimization
Abstract not provided.
A Primal-Dual Algorithm for Large-Scale Risk Minimization
Abstract not provided.
A Primal-Dual Algorithm for Large-Scale Risk Minimization
Abstract not provided.
A Primal-Dual Algorithm for Large-Scale Risk Minimization
Abstract not provided.
A Primal-Dual Algorithm for Large-Scale Risk Minimization
Abstract not provided.
A Primal-Dual Algorithm for Large-Scale Risk Minimization
Abstract not provided.
A primal–dual algorithm for risk minimization
Mathematical Programming
In this paper, we develop an algorithm to efficiently solve risk-averse optimization problems posed in reflexive Banach space. Such problems often arise in many practical applications as, e.g., optimization problems constrained by partial differential equations with uncertain inputs. Unfortunately, for many popular risk models including the coherent risk measures, the resulting risk-averse objective function is nonsmooth. This lack of differentiability complicates the numerical approximation of the objective function as well as the numerical solution of the optimization problem. To address these challenges, we propose a primal–dual algorithm for solving large-scale nonsmooth risk-averse optimization problems. This algorithm is motivated by the classical method of multipliers and by epigraphical regularization of risk measures. As a result, the algorithm solves a sequence of smooth optimization problems using derivative-based methods. We prove convergence of the algorithm even when the subproblems are solved inexactly and conclude with numerical examples demonstrating the efficiency of our method.
Adjoint-based Deterministic Inversion for Ice Sheets
Abstract not provided.
An adaptive local reduced basis method for solving PDEs with uncertain inputs and evaluating risk
Computer Methods in Applied Mechanics and Engineering
Many physical systems are modeled using partial differential equations (PDEs) with uncertain or random inputs. For such systems, naively propagating a fixed number of samples of the input probability law (or an approximation thereof) through the PDE is often inadequate to accurately quantify the “risk” associated with critical system responses. In this paper, we develop a goal-oriented, adaptive sampling and local reduced basis approximation for PDEs with random inputs. Our method determines a set of samples and an associated (implicit) Voronoi partition of the parameter domain on which we build local reduced basis approximations of the PDE solution. The samples are selected in an adaptive manner using an a posteriori error indicator. A notable advantage of the proposed approach is that the computational cost of the approximation during the adaptive process remains constant. We provide theoretical error bounds for our approximation and numerically demonstrate the performance of our method when compared to widely used adaptive sparse grid techniques. In addition, we tailor our approach to accurately quantify the risk of quantities of interest that depend on the PDE solution. We demonstrate our method on an advection–diffusion example and a Helmholtz example.
An Adaptive Sampling Approach for Solving PDEs with Uncertain Inputs and Evaluating Risk
Abstract not provided.
An Adaptive Sampling Approach for Solving PDEs with Uncertain Inputs and Evaluating Risk
Abstract not provided.
An Adaptive Sampling Approach for Solving PDEs with Uncertain Inputs and Evaluating Risk
Abstract not provided.
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