Graph dynamical networks for forecasting collective behavior of active matter

doi:10.1088/1674-1056/ac7cce

Abstract After decades of theoretical studies, the rich phase states of active matter and cluster kinetic processes are still of research interest. How to efficiently calculate the dynamical processes under their complex conditions becomes an open problem. Recently, machine learning methods have been proposed to predict the degree of coherence of active matter systems. In this way, the phase transition process of the system is quantified and studied. In this paper, we use graph network as a powerful model to determine the evolution of active matter with variable individual velocities solely based on the initial position and state of the particles. The graph network accurately predicts the order parameters of the system in different scale models with different individual velocities, noise and density to effectively evaluate the effect of diverse condition. Compared with the classical physical deduction method, we demonstrate that graph network prediction is excellent, which could save significantly computing resources and time. In addition to active matter, our method can be applied widely to other large-scale physical systems.

Keywords: active matter graph network improvement of Vicsek collective motion

Received: 18 February 2022
Revised: 13 June 2022
Accepted manuscript online: 29 June 2022

PACS:	64.75.-g	(Phase equilibria)
	07.05.Mh	(Neural networks, fuzzy logic, artificial intelligence)
	05.65.+b	(Self-organized systems)
	87.64.Aa	(Computer simulation)

Corresponding Authors: Cai Zhao, Wen Zheng
E-mail: zhaocai@tyut.edu.cn;zhengwen@tyut.edu.cn

Cite this article:

Yanjun Liu(刘彦君), Rui Wang(王瑞), Cai Zhao(赵偲), and Wen Zheng(郑文) Graph dynamical networks for forecasting collective behavior of active matter 2022 Chin. Phys. B 31 116401

[1] Genkin M M, Sokolov A, Lavrentovich O D and Aranson I S 2017 Phys. Rev. X 7 011029
[2] Jolles J W, Boogert N J, Sridhar V H, Couzin I D and Manica A 2017 Current Biology 27 2862
[3] Bajec I L and Heppner F H 2009 Animal Behaviour 78 777
[4] Dombrowski C, Cisneros L, Chatkaew S, Goldstein R E and Kessler J O 2004 Phys. Rev. Lett. 93 098103
[5] Kumar S, Singh J P, Giri D and Mishra S 2021 Phys. Rev. E 104 024601
[6] Cichos F, Gustavsson K, Mehlig B and Volpe G 2020 Nat. Mach. Intell. 2 94
[7] Keta Y E, Fodor van Wijland F, Cates M E and Jack R L 2021 Phys. Rev. E 103 022603
[8] Zhang J, Zheng W, Zhang S, Xu D, Nie Y, Jiang Z and Xu N 2021 Sci. Adv. 7 eabg6766
[9] Speck T 2020 Soft Matter 16 2652
[10] Chepizhko O, Saintillan D and Peruani F 2021 Soft Matter 17 3113
[11] Zhang J, Zhao Y, Tian B, Peng L, Zhang H T, Wang B H and Zhou T 2009 Physica A 388 1237
[12] Chen D 2018 Research on Evolutionary Analysis and Pattern Control of Collective Dynamic System (Ph.D. thesis) (Wuhan:Huazhong University of Science and Technolog) (in Chinese)
[13] Shankar S, Souslov A, Bowick M J, Marchetti M C and Vitelli V 2020 arXiv:2010.00364[cond-mat.soft]
[14] Vicsek T, Czirók A, Ben-Jacob E, Cohen I and Shochet O 1995 Phys. Rev. Lett. 75 1226
[15] Meakin P, Vicsek T and Family F 1985 Phys. Rev. B 31 564
[16] Boccaletti S, Latora V, Moreno Y, Chavez M and Hwang D U 2006 Phys. Rep. 424 175
[17] Liu B, Pu Z, Wu S, Shi L, Wang L and Yang W 2022 Improved Self-Propelled Swarms Model with Enhanced Convergence Efficiency:Advances in Guidance, Navigation and Control (Berlin:Springer) pp. 4933-4942
[18] Chen Q S and Ji M 2017 Chin. Phys. B 26 098903
[19] Gro?]mann R, Aranson I S and Peruani F 2020 Nat. Commun. 11 1
[20] Czirók A, Stanley H E and Vicsek T 1997 J. Phys. A:Math. Gen. 30 1375
[21] Zhang H T, Chen M Z and Zhou T 2007 arXiv:0707.3402[physics.data-an]
[22] Hou F, Zhang Y, Fu X, Jiao L and Zheng W 2021 J. Adv. Transport. 2021 9513170
[23] Willard J, Jia X, Xu S, Steinbach M and Kumar V 2020 arXiv:2003.04919[physics.comp-ph]
[24] Zhang Y, Ren J, Wang R, Fang F and Zheng W 2021 Water 13 2095
[25] LeCun Y, Bengio Y. and Hinton G 2015 Nature 521 436
[26] Sarker I H 2021 SN Comput. Sci. 2 1
[27] Mahesh B 2020 Int. J. Sci. Res. 9 381
[28] Chen K and Meng X 2020 J. Comput. Res. Develop. 57 1971 (in Chinese)
[29] Xu R 2018 Application of Machine Learning to Phase Transition Problems (Master thesis) (Xiamen:Xiamen University) (in Chinese)
[30] Z?ttl A 2020 Chin. Phys. B 29 074701
[31] Canabarro A, Fanchini F F, Malvezzi A L, Pereira R and Chaves R 2019 Phys. Rev. B 100 045129
[32] Shchur O, Mumme M, Bojchevski A and Günemann S 2018 arXiv:1811.05868[cs.LG]
[33] Zhang C, Song D, Huang C, Swami A and Chawla N V 2019 Heterogeneous Graph Neural Network:Proceedings of the 25th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining KDD'19 (New York, USA:Association for Computing Machinery) pp. 793-803
[34] Xu Y and Xiaodong Q 2020 Data Analysis and Knowledge Discovery 4 119 (in Chinese)
[35] Deng L, Bing G and Wen Z 2021 International Journal of Web Services Research (IJWSR) 18 63
[36] Chang M B, Ullman T, Torralba A and Tenenbaum J B 2016 arXiv:1612.00341[cs.AI]
[37] Zhang T, Song A and Lan Y 2020 Sci. Sin. Inf. 50 347
[38] Reinhard P G and Suraud E 2008 Introduction to Cluster Dynamics (New York:John Wiley & Sons)
[39] Dulaney A R and Brady J F 2021 Soft Matter 17 6808
[40] Wang R, Fang F, Cui J and Zheng W 2022 Sci. Rep. 12 500
[41] Wang R, Cui J, Zhang Y and Zheng W 2021 J. University of Electronic Science and Technology of China 50 768 (in Chinese)
[42] Battaglia P W, Hamrick J B, Bapst V, et al. 2018 arXiv:1806.01261[cs.LG]
[43] Maron H, Ben-Hamu H, Serviansky H and Lipman Y 2019 arXiv:1905.11136[cs.LG]
[44] Que-Salinas U, Ramírez-Gonzáez P E and Torres-Carbajal A 2021 Soft Matter 17 1975
[45] Dulaney A R and Brady J F 2021 Soft Matter 17 6808
[46] Sanchez-Gonzalez A, Godwin J, Pfaff T, Ying R, Leskovec J and Battaglia P 2020 arXiv:2002.09405[cs.LG]
[47] Zheng W, Zhang S and Xu N 2018 Chin. Phys. B 27 066102
[48] Xu Z, Wang R, Cui J, Liu Y and Zheng W 2021 Chin. Phys. B 30 066101

[1]	Active thermophoresis and diffusiophoresis Huan Liang(梁欢), Peng Liu(刘鹏), Fangfu Ye(叶方富), and Mingcheng Yang(杨明成). Chin. Phys. B, 2022, 31(10): 104702.
[2]	Simulation of microswimmer hydrodynamics with multiparticle collision dynamics Andreas Z?ttl. Chin. Phys. B, 2020, 29(7): 074701.
[3]	Symmetry properties of fluctuations in an actively driven rotor He Li(李赫), Xiang Yang(杨翔), Hepeng Zhang(张何朋). Chin. Phys. B, 2020, 29(6): 060502.
[4]	Molecular dynamics simulations on the dynamics of two-dimensional rounded squares Zhang-lin Hou(侯章林), Ying Ju(句颖), Yi-wu Zong(宗奕吾), Fang-fu Ye(叶方富), Kun Zhao(赵坤). Chin. Phys. B, 2018, 27(8): 088203.
[5]	Flowrate behavior and clustering of self-driven robots in a channel Bo Tian(田波), Wang-Ping Sun(孙王平), Ming Li(李明), Rui Jiang(姜锐), Mao-Bin Hu(胡茂彬). Chin. Phys. B, 2018, 27(3): 038902.
[6]	Collective motion of active particles in environmental noise Qiu-shi Chen(陈秋实), Ming Ji(季铭). Chin. Phys. B, 2017, 26(9): 098903.
[7]	Anomalous boundary deformation induced by enclosed active particles Wen-De Tian(田文得), Yan Gu(顾燕), Yong-Kun Guo(郭永坤), Kang Chen(陈康). Chin. Phys. B, 2017, 26(10): 100502.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Metrics
Related Articles

Graph dynamical networks for forecasting collective behavior of active matter

Cite this article:

Online attention