Interpretable machine learning models: a physics-based view

• URL: http://arxiv.org/abs/2003.10025v1
• Date: Sun, 22 Mar 2020 23:17:19 GMT
• Title: Interpretable machine learning models: a physics-based view
• Authors: Ion Matei, Johan de Kleer, Christoforos Somarakis, Rahul Rai and John S. Baras
• Abstract summary: We use port Hamiltonian (p-H) formalism to describe the basic constructs that contain physically interpretable processes. We show how we can build models out of the p-H constructs and how we can train them.
• Score: 3.7431113857875755
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: To understand changes in physical systems and facilitate decisions, explaining how model predictions are made is crucial. We use model-based interpretability, where models of physical systems are constructed by composing basic constructs that explain locally how energy is exchanged and transformed. We use the port Hamiltonian (p-H) formalism to describe the basic constructs that contain physically interpretable processes commonly found in the behavior of physical systems. We describe how we can build models out of the p-H constructs and how we can train them. In addition we show how we can impose physical properties such as dissipativity that ensure numerical stability of the training process. We give examples on how to build and train models for describing the behavior of two physical systems: the inverted pendulum and swarm dynamics.

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