Data-Driven Physical Inquiry: Discovering Relevant Dimensionless Numbers With Physics-Constrained Machine Learning
ORAL
Abstract
Machine learning offers enormously popular methods for interrogating data. However, researchers in the physical sciences remain skeptical of these techniques, as they often produce inscrutable, black-box results. In this work, we present a case study of data-driven physical inquiry -- leveraging machine learning techniques to explore complex data sets, but anchored by physical principles.
As an illustration, we investigate the particle-laden flow conditions that lead to turbulence augmentation or attenuation, inspired by the work of Tanaka and Eaton (2008). We leverage a modern ridge function formulation of the Buckingham Pi Theorem that enables tight coupling with classification algorithms, transforming black-box prediction into an interpretable form.
As an illustration, we investigate the particle-laden flow conditions that lead to turbulence augmentation or attenuation, inspired by the work of Tanaka and Eaton (2008). We leverage a modern ridge function formulation of the Buckingham Pi Theorem that enables tight coupling with classification algorithms, transforming black-box prediction into an interpretable form.
*Funding provided by the U.S. Department of Energy under grant no. DENA0002373-1.
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Presenters
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Zachary del Rosario
- Stanford University