2024-03-29T11:07:05Zhttps://eprints.lib.hokudai.ac.jp/dspace-oai/requestoai:eprints.lib.hokudai.ac.jp:2115/841852023-11-20T05:50:46Zhdl_2115_20057hdl_2115_148On a numerical bifurcation analysis of a particle reaction-diffusion model for a motion of two self-propelled disksYasugahira, Yusuke1000020314289Nagayama, Masaharumetadata only accessParticle reaction-diffusion modelNumerical bifurcation analysisSelf-propelled motionChaotic motion420Theoretical analysis using mathematical models is often used to understand a mechanism of collective motion in a self-propelled system. In the experimental system using camphor disks, several kinds of characteristic motions have been observed due to the interaction of two camphor disks. In this paper, we understand the emergence mechanism of the motions caused by the interaction of two self-propelled bodies by analyzing the global bifurcation structure using the numerical bifurcation method for a mathematical model. Finally, it is also shown that the irregular motion, which is one of the characteristic motions, is chaotic motion and that it arises from periodic bifurcation phenomena and quasi-periodic motions due to torus bifurcation.Springer2022-01-17engjournal articleNAhttp://hdl.handle.net/2115/84185https://doi.org/10.1007/s13160-021-00498-40916-7005Japan journal of industrial and applied mathematics39631652