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Statistically Optimal Force Aggregation for Coarse-Graining Molecular Dynamics

Andreas Krämer, Aleksander E. P. Durumeric, Nicholas E. Charron, Yaoyi Chen, Cecilia Clementi, Frank Noé

2023The Journal of Physical Chemistry Letters37 citationsDOI

Abstract

Machine-learned coarse-grained (CG) models have the potential for simulating large molecular complexes beyond what is possible with atomistic molecular dynamics. However, training accurate CG models remains a challenge. A widely used methodology for learning bottom-up CG force fields maps forces from all-atom molecular dynamics to the CG representation and matches them with a CG force field on average. We show that there is flexibility in how to map all-atom forces to the CG representation and that the most commonly used mapping methods are statistically inefficient and potentially even incorrect in the presence of constraints in the all-atom simulation. We define an optimization statement for force mappings and demonstrate that substantially improved CG force fields can be learned from the same simulation data when using optimized force maps. The method is demonstrated on the miniproteins chignolin and tryptophan cage and published as open-source code.

Topics & Concepts

Force field (fiction)Molecular dynamicsGranularityFlexibility (engineering)Representation (politics)Computer scienceAtom (system on chip)Field (mathematics)Potential of mean forceCode (set theory)AlgorithmStatistical physicsBiological systemPhysicsArtificial intelligenceChemistryMathematicsComputational chemistrySet (abstract data type)Parallel computingStatisticsPure mathematicsOperating systemProgramming languagePolitical scienceLawPoliticsBiologyMachine Learning in Materials ScienceBlock Copolymer Self-AssemblyProtein Structure and Dynamics
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