Geodesic
Pensive Billiards, Point Vortices, And The Silver Ratio
Forum of Mathematics, Sigma, Tome 13 (2025) no. 1, p. e171

Voir la notice de l'article provenant de la source Cambridge University Press

We define a new class of plane billiards – the “pensive billiard” – in which the billiard ball travels along the boundary for some distance depending on the incidence angle before reflecting, while preserving the billiard rule of equality of the angles of incidence and reflection. This generalizes so-called “puck billiards” proposed by M. Bialy, as well as a “vortex billiard,” that is, the motion of a point vortex dipole in two-dimensional hydrodynamics on domains with boundary. We prove the variational origin and invariance of a symplectic structure for pensive billiards, as well as study their properties including conditions for a twist map, the existence of periodic orbits, etc. We also demonstrate the appearance of both the golden and silver ratios in the corresponding hydrodynamical vortex setting. Finally, we introduce and describe basic properties of pensive outer billiards. 
Drivas, Theodore; Glukhovskiy, Daniil; Khesin, Boris. Pensive Billiards, Point Vortices, And The Silver Ratio. Forum of Mathematics, Sigma, Tome 13 (2025) no. 1, p. e171. doi: 10.1017/fms.2025.10119
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[1] Ashbee, T., Esler, J. and Mcdonald, N., ‘Generalized hamiltonian point vortex dynamics on arbitrary domains using the method of fundamental solutions’, J. Comput. Phys. 246(2013), 289–303. Google Scholar | DOI

[2] Ashbee, T. L., Dynamics and statistical mechanics of point vortices in bounded domains, PhD thesis, UCL (University College London), 2014. Google Scholar

[3] Barbieri, S. and Clarke, A., ‘Existence and nonexistence of invariant curves of coin billiards’, preprint (2024). . Google Scholar | arXiv

[4] Bialy, M., Fierobe, C., Glutsyuk, A., Levi, M., Plakhov, A. and Tabachnikov, S., ‘Open problems on billiards and geometric optics’, preprint (2021). . Google Scholar | arXiv

[5] Blaschke, W., Kreis und Kugel (de Gruyter, Berlin, 1916). Google Scholar | DOI

[6] Boatto, S. and Koiller, J., ‘Vortices on closed surfaces’, Fields Inst. Commun. 73 (2015), 185–237. Google Scholar | DOI

[7] Dragović, V. and Radnović, M., ‘Magic billiards: the case of elliptical boundaries’, preprint (2025). . Google Scholar | arXiv

[8] Drivas, T. D. and Elgindi, T. M., ‘Singularity formation in the incompressible Euler equation in finite and infinite time’, EMS Surv. Math. Sci. 101 (2023), 1–100. Google Scholar | DOI

[9] Drivas, T. D., Glukhovskiy, D. and Khesin, B., ‘Singular vortex pairs follow magnetic geodesics’, Int. Math. Res. Not. (2024), rnae106. Google Scholar

[10] Drivas, T. D., Iyer, S. and Nguyen, T. T., ‘The Feynman–Lagerstrom criterion for boundary layers’, Arch. Ration. Mech. Anal. 2483 (2024), 55. Google Scholar | DOI

[11] Flucher, M. and Gustafsson, B., ‘Vortex motion in two-dimensional hydromechanics’, preprint TRITA-MAT-1997-MA-02 (1997). Google Scholar

[12] Fomenko, A. T., Vedyushkina, V. V. and Zav’Yalov, V. N.Liouville foliations of topological billiards with slipping’, Russ. J. Math. Phys. 281 (2021), 37–55. Google Scholar | DOI

[13] Geshev, P. and Chernykh, A., ‘The motion of vortices in a two-dimensional bounded region’, Thermophys. Aeromech. 25 (2018), 809–822. Google Scholar | DOI

[14] Grotta-Ragazzo, C., Gustafsson, B. and Koiller, J., ‘On the interplay between vortices and harmonic flows: Hodge decomposition of Euler’s equations in 2d’, Regul. Chaotic Dyn. 292 (2024), 241–303. Google Scholar | DOI

[15] Gustafsson, B., ‘On the motion of a vortex in two-dimensional flow of an ideal fluid in simply and multiply connected domains’, preprint TRITA-MAT-1979-7, see also (1979), 1–112. Google Scholar | arXiv

[16] Katok, A., ‘Interval exchange transformations and some special flows are not mixing’, Isr. J. Math. 354 (1980), 301–310. Google Scholar | DOI

[17] Katok, A. and Hasselblatt, B., Introduction to the Modern Theory of Dynamical Systems, Encyclopedia of Mathematics and its Applications (Cambridge Univ. Press, Cambridge, 1995). Google Scholar | DOI

[18] Katok, A., Strelcyn, J.-M., Ledrappier, F. and Przytycki, F., Invariant Manifolds, Entropy and Billiards; Smooth Maps with Singularities (Springer, Berlin, 1986). Google Scholar | DOI

[19] Khesin, B. and Wang, H., ‘The golden ratio and hydrodynamics’, Math. Intelligencer 441 (2021), 22–27. Google Scholar

[20] Kimura, Y., ‘Vortex motion on surfaces with constant curvature’, Proc. R. Soc. Lond. Ser. A 4551981 (1999), 245–259. Google Scholar | DOI

[21] Love, A., ‘On the motion of paired vortices with a common axis’, Proc. Lond. Math. Soc. 11 (1893), 185–194. Google Scholar | DOI

[22] Marchioro, C. and Pulvirenti, M., Mathematical Theory of Incompressible Nonviscous Fluids (Springer, New York, 1993). Google Scholar

[23] Mavroyiakoumou, C. and Berkshire, F., ‘Collinear interaction of vortex pairs with different strengths—criteria for leapfrogging’, Phys. Fluids 322 (2020), None. Google Scholar

[24] Modin, K. and Viviani, M., ‘Integrability of point-vortex dynamics via symplectic reduction: a survey’, Arnold Math. J. 73 (2021), 357–385. Google Scholar | DOI

[25] Newton, P., The N-Vortex Problem: Analytical Techniques, vol. 145 of Applied Mathematical Sciences (Springer, New York, 2001). Google Scholar | DOI

[26] Ryabov, P. E. and Shadrin, A. A., ‘Bifurcation diagram of one generalized integrable model of vortex dynamics’, Regul. Chaotic Dyn. 24 (2019), 418–431. Google Scholar | DOI

[27] Ryabov, P. E., Sokolov, S. V. and Palshin, G. P., ‘Dynamics of a few vortices in an ideal fluid and in a Bose–Einstein condensate’, preprint (2021). . Google Scholar | arXiv

[28] Sokolov, S. V. and Ryabov, P. E., ‘Bifurcation analysis of the dynamics of two vortices in a Bose–Einstein condensate. the case of intensities of opposite signs’, Regul. Chaotic Dyn. 22 (2017), 976–995. Google Scholar | DOI

[29] Tabachnikov, S., Geometry and Billiards, vol. 30 (Amer. Math. Soc., Providence, RI, 2005). Google Scholar

[30] Yang, C., ‘Vortex motion of the Euler and lake equations’, J. Nonlinear Sci. 313 (2021), None. Google Scholar

[31] Zemlyakov, A. N. and Katok, A. B., ‘Topological transitivity of billiards in polygons’, Math. Notes Acad. Sci. USSR 182 (1975), 760–764. Google Scholar

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