Litcius/Paper detail

Machine learning of independent conservation laws through neural deflation

Wei Zhu, Hong-Kun Zhang, P. G. Kevrekidis

2023Physical review. E11 citationsDOI

Abstract

We introduce a methodology for seeking conservation laws within a Hamiltonian dynamical system, which we term "neural deflation." Inspired by deflation methods for steady states of dynamical systems, we propose to iteratively train a number of neural networks to minimize a regularized loss function accounting for the necessity of conserved quantities to be in involution and enforcing functional independence thereof consistently in the infinite-sample limit. The method is applied to a series of integrable and nonintegrable lattice differential-difference equations. In the former, the predicted number of conservation laws extensively grows with the number of degrees of freedom, while for the latter, it generically stops at a threshold related to the number of conserved quantities in the system. This data-driven tool could prove valuable in assessing a model's conserved quantities and its potential integrability.

Topics & Concepts

Conservation lawIntegrable systemConserved quantityArtificial neural networkDynamical systems theoryApplied mathematicsHamiltonian (control theory)DeflationPhysicsMathematicsStatistical physicsMathematical analysisComputer scienceClassical mechanicsMathematical optimizationArtificial intelligenceQuantum mechanicsMonetary policyEconomicsMonetary economicsModel Reduction and Neural NetworksProtein Structure and DynamicsQuantum, superfluid, helium dynamics
Machine learning of independent conservation laws through neural deflation | Litcius