Geometry and integrability of quadratic systems with invariant hyperbolas
Let QSH be the family of non-degenerate planar quadratic differential systems possessing an invariant hyperbola. We study this class from the viewpoint of integrability. This is a rich family with a variety of integrable systems with either polynomial, rational, Darboux or more general Liouvillian f...
Elmentve itt :
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Dokumentumtípus: | Folyóirat |
Megjelent: |
2021
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Sorozat: | Electronic journal of qualitative theory of differential equations
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Kulcsszavak: | Másodfokú differenciálegyenlet |
doi: | 10.14232/ejqtde.2021.1.6 |
Online Access: | http://acta.bibl.u-szeged.hu/73658 |
Tartalmi kivonat: | Let QSH be the family of non-degenerate planar quadratic differential systems possessing an invariant hyperbola. We study this class from the viewpoint of integrability. This is a rich family with a variety of integrable systems with either polynomial, rational, Darboux or more general Liouvillian first integrals as well as nonintegrable systems. We are interested in studying the integrable systems in this family from the topological, dynamical and algebraic geometric viewpoints. In this work we perform this study for three of the normal forms of QSH, construct their topological bifurcation diagrams as well as the bifurcation diagrams of their configurations of invariant hyperbolas and lines and point out the relationship between them. We show that all systems in one of the three families have a rational first integral. For another one of the three families, we give a global answer to the problem of Poincaré by producing a geometric necessary and sufficient condition for a system in this family to have a rational first integral. Our analysis led us to raise some questions in the last section, relating the geometry of the invariant algebraic curves (lines and hyperbolas) in the systems and the expression of the corresponding integrating factors. |
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Terjedelem/Fizikai jellemzők: | 56 |
ISSN: | 1417-3875 |