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Paper detail

MD-GAN with multi-particle input: the machine learning of long-time molecular behavior from short-time MD data

MD-GAN is a machine learning-based method that can evolve part of the system at any time step, accelerating the generation of molecular dynamics data. For the accurate prediction of MD-GAN, sufficient information on the dynamics of a part of the system should be included with the training data. Therefore, the selection of the part of the system is important for efficient learning. In a previous study, only one particle (or vector) of each molecule was extracted as part of the system. Therefore, we investigated the effectiveness of adding information from other particles to the learning process. In the experiment of the polyethylene system, when the dynamics of three particles of each molecule were used, the diffusion was successfully predicted using one-third of the time length of the training data, compared to the single-particle input. Surprisingly, the unobserved transition of diffusion in the training data was also predicted using this method.

preprint2022arXivOpen access
Ryo KawadaKatsuhiro EndoDaisuke YuharaKenji Yasuoka
physics.comp-phMachine Learningphysics.chem-ph
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Ryo KawadaKatsuhiro EndoDaisuke YuharaKenji Yasuoka

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