Litcius/Paper detail

A general framework for quantifying uncertainty at scale

Ionuț-Gabriel Farcaș, G. Merlo, F. Jenko

2022Communications Engineering16 citationsDOIOpen Access PDF

Abstract

In many fields of science, comprehensive and realistic computational models are available nowadays. Often, the respective numerical calculations call for the use of powerful supercomputers, and therefore only a limited number of cases can be investigated explicitly. This prevents straightforward approaches to important tasks like uncertainty quantification and sensitivity analysis. This challenge can be overcome via our recently developed sensitivity-driven dimension-adaptive sparse grid interpolation strategy. The method exploits, via adaptivity, the structure of the underlying model (such as lower intrinsic dimensionality and anisotropic coupling of the uncertain inputs) to enable efficient and accurate uncertainty quantification and sensitivity analysis at scale. Here, we demonstrate the efficiency of this adaptive approach in the context of fusion research, in a realistic, computationally expensive scenario of turbulent transport in a magnetic confinement tokamak device with eight uncertain parameters, reducing the effort by at least two orders of magnitude. In addition, we show that this refinement method intrinsically provides an accurate surrogate model that is nine orders of magnitude cheaper than the high-fidelity model.

Topics & Concepts

Sensitivity (control systems)Computer scienceUncertainty quantificationCurse of dimensionalityContext (archaeology)Interpolation (computer graphics)Surrogate modelScale (ratio)GridDimension (graph theory)Sparse gridExploitMathematical optimizationAlgorithmMachine learningMathematicsArtificial intelligencePhysicsElectronic engineeringGeometryPaleontologyPure mathematicsEngineeringBiologyComputer securityMotion (physics)Quantum mechanicsNuclear reactor physics and engineeringProbabilistic and Robust Engineering DesignMagnetic confinement fusion research