Pablo Pedregal
Published 2021-03-12Version 1
We provide an upper bound for the number of limit cycles that planar polynomial differential systems of a given degree may have. The bound turns out to be a polynomial of degree four in the degree of the system. The strategy of proof brings variational techniques into the differential-system field by transforming the task of counting limit cycles into counting critical points for a certain smooth, non-negative functional, through Morse inequalities, for which limit cycles are global minimizers. We thus solve the second part of Hilbert's 16th problem providing a uniform upper bound for the number of limit cycles which only depends on the degree of the polynomial differential system. We would like to highlight that the bound is sharp for quadratic systems yielding a maximum of four limit cycles for such subclass of differential systems.
Comments: arXiv admin note: substantial text overlap with arXiv:1904.01292
Upper bounds for the number of limit cycles of some planar polynomial differential systems
A restricted version of the Hilbert's 16th problem for quadratic vector fields
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