H. T. Moges, M. Katsanikas, P. A. Patsis, M. Hillebrand, Ch. Skokos
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By utilizing the color and rotation technique to visualize the Four-Dimensional (4D) Poincaré surfaces of section of the system, i.e. projecting them onto a 3D subspace and employing color to represent the fourth dimension, we can identify distinct structural patterns. Perturbations of parent and bifurcating stable POs result in the creation of tori characterized by a smooth color variation on their surface. Furthermore, perturbations of simple unstable parent POs beyond the bifurcation point, which lead to the birth of new stable families of POs, result in the formation of figure-8 structures of smooth color variations. These figure-8 formations surround well-shaped tori around the bifurcated stable POs, losing their well-defined forms for energies further away from the bifurcation point. We also observe that even slight perturbations of highly unstable POs create a cloud of mixed color points, which rapidly move away from the location of the PO. 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引用次数: 0
摘要
我们研究了三维(3D)自主哈密顿系统的相空间结构如何在一系列连续的二维(2D)和三维杈形分叉和周期加倍分叉中演变,因为周期轨道(POs)母族从稳定到简单不稳定的转变导致了新稳定 POs 的产生。我们的研究表明,随着周期轨道主族稳定性的变化,周期轨道附近的相空间结构也会发生连续变化。这一过程在系统中产生了新的 POs 族,与其母族相比,这些 POs 要么保持不变,要么表现出更高的多重性。在三维系统中,跟踪这样的相空间转换具有挑战性。通过利用颜色和旋转技术将系统剖面的四维(4D)Poincaré曲面可视化,即把它们投影到三维子空间,并用颜色来表示四维空间,我们可以识别出独特的结构模式。对母波和分叉稳定波的扰动会产生环状结构,其表面具有平滑的颜色变化。此外,对分叉点以外的简单不稳定母波长的扰动会导致新的稳定波长族的诞生,从而形成具有平滑颜色变化的 "8 "字形结构。这些 "8 "字形结构环绕在分叉稳定 PO 周围的形状良好的环状结构周围,当能量进一步远离分叉点时,这些环状结构就会失去其明确的形式。我们还观察到,即使对高度不稳定的 PO 进行轻微扰动,也会产生一团混合色点,并迅速远离 PO 的位置。我们的研究首次对高倍率 PO 附近的 4D 截面进行了系统可视化。它阐明了在这些情况下,规则轨道和混沌轨道的共存是如何塑造相空间景观的。
The Evolution of the Phase Space Structure Along Pitchfork and Period-Doubling Bifurcations in a 3D-Galactic Bar Potential
We investigate how the phase space structure of a Three-Dimensional (3D) autonomous Hamiltonian system evolves across a series of successive Two-Dimensional (2D) and 3D pitchfork and period-doubling bifurcations, as the transition of the parent families of Periodic Orbits (POs) from stability to simple instability leads to the creation of new stable POs. Our research illustrates the consecutive alterations in the phase space structure near POs as the stability of the main family of POs changes. This process gives rise to new families of POs within the system, either maintaining the same or exhibiting higher multiplicity compared to their parent families. Tracking such a phase space transformation is challenging in a 3D system. By utilizing the color and rotation technique to visualize the Four-Dimensional (4D) Poincaré surfaces of section of the system, i.e. projecting them onto a 3D subspace and employing color to represent the fourth dimension, we can identify distinct structural patterns. Perturbations of parent and bifurcating stable POs result in the creation of tori characterized by a smooth color variation on their surface. Furthermore, perturbations of simple unstable parent POs beyond the bifurcation point, which lead to the birth of new stable families of POs, result in the formation of figure-8 structures of smooth color variations. These figure-8 formations surround well-shaped tori around the bifurcated stable POs, losing their well-defined forms for energies further away from the bifurcation point. We also observe that even slight perturbations of highly unstable POs create a cloud of mixed color points, which rapidly move away from the location of the PO. Our study introduces, for the first time, a systematic visualization of 4D surfaces of section within the vicinity of higher multiplicity POs. It elucidates how, in these cases, the coexistence of regular and chaotic orbits contributes to shaping the phase space landscape.
期刊介绍:
The International Journal of Bifurcation and Chaos is widely regarded as a leading journal in the exciting fields of chaos theory and nonlinear science. Represented by an international editorial board comprising top researchers from a wide variety of disciplines, it is setting high standards in scientific and production quality. The journal has been reputedly acclaimed by the scientific community around the world, and has featured many important papers by leading researchers from various areas of applied sciences and engineering.
The discipline of chaos theory has created a universal paradigm, a scientific parlance, and a mathematical tool for grappling with complex dynamical phenomena. In every field of applied sciences (astronomy, atmospheric sciences, biology, chemistry, economics, geophysics, life and medical sciences, physics, social sciences, ecology, etc.) and engineering (aerospace, chemical, electronic, civil, computer, information, mechanical, software, telecommunication, etc.), the local and global manifestations of chaos and bifurcation have burst forth in an unprecedented universality, linking scientists heretofore unfamiliar with one another''s fields, and offering an opportunity to reshape our grasp of reality.