TY - JOUR
T1 - Efficient compressed database of equilibrated configurations of ring-linear polymer blends for MD simulations
AU - Hagita, Katsumi
AU - Murashima, Takahiro
AU - Ogino, Masao
AU - Omiya, Manabu
AU - Ono, Kenji
AU - Deguchi, Tetsuo
AU - Jinnai, Hiroshi
AU - Kawakatsu, Toshihiro
N1 - Funding Information:
One of the authors (K.H.) gratefully acknowledge Prof. Yutaka Ishikawa at RIKEN Center for Computational Science for fruitful discussions for lossy compression of floating-point data in scientific simulations. The authors are partially supported by the Joint Usage/Research Center for Interdisciplinary Large-scale Information Infrastructures (JHPCN) and the High-Performance Computing Infrastructure (HPCI) in Japan: hp200048, hp200168 and hp210132. This work was partially supported by JSPS KAKENHI, Japan, grant nos.: JP18H04494, JP19H00905, and JP20H04649, and JST CREST, Japan, grant nos.: JPMJCR1993 and JPMJCR19T4.
Publisher Copyright:
© 2022, The Author(s).
PY - 2022/12
Y1 - 2022/12
N2 - To effectively archive configuration data during molecular dynamics (MD) simulations of polymer systems, we present an efficient compression method with good numerical accuracy that preserves the topology of ring-linear polymer blends. To compress the fraction of floating-point data, we used the Jointed Hierarchical Precision Compression Number - Data Format (JHPCN-DF) method to apply zero padding for the tailing fraction bits, which did not affect the numerical accuracy, then compressed the data with Huffman coding. We also provided a dataset of well-equilibrated configurations of MD simulations for ring-linear polymer blends with various lengths of linear and ring polymers, including ring complexes composed of multiple rings such as polycatenane. We executed 109 MD steps to obtain 150 equilibrated configurations. The combination of JHPCN-DF and SZ compression achieved the best compression ratio for all cases. Therefore, the proposed method enables efficient archiving of MD trajectories. Moreover, the publicly available dataset of ring-linear polymer blends can be employed for studies of mathematical methods, including topology analysis and data compression, as well as MD simulations.
AB - To effectively archive configuration data during molecular dynamics (MD) simulations of polymer systems, we present an efficient compression method with good numerical accuracy that preserves the topology of ring-linear polymer blends. To compress the fraction of floating-point data, we used the Jointed Hierarchical Precision Compression Number - Data Format (JHPCN-DF) method to apply zero padding for the tailing fraction bits, which did not affect the numerical accuracy, then compressed the data with Huffman coding. We also provided a dataset of well-equilibrated configurations of MD simulations for ring-linear polymer blends with various lengths of linear and ring polymers, including ring complexes composed of multiple rings such as polycatenane. We executed 109 MD steps to obtain 150 equilibrated configurations. The combination of JHPCN-DF and SZ compression achieved the best compression ratio for all cases. Therefore, the proposed method enables efficient archiving of MD trajectories. Moreover, the publicly available dataset of ring-linear polymer blends can be employed for studies of mathematical methods, including topology analysis and data compression, as well as MD simulations.
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U2 - 10.1038/s41597-022-01138-3
DO - 10.1038/s41597-022-01138-3
M3 - Article
C2 - 35136085
AN - SCOPUS:85124296141
SN - 2052-4463
VL - 9
JO - Scientific data
JF - Scientific data
IS - 1
M1 - 40
ER -