Date:
Thu, 12/01/202317:15-19:00
Location:
Zoom
Zoom Link: https://ucph-ku.zoom.us/j/69937085835
Password: 123456
Abstract:
Consider a real bivariate polynomial function that has a strict local minimum at the origin and that vanishes at this point. In a sufficiently small neighborhood of the origin, the non-zero level curves of this function are smooth Jordan curves. Whenever the origin is a Morse strict local minimum, the small enough level curves become boundaries of convex topological disks. Otherwise, the levels may be non-convex, as was proven by M. Coste. In order to measure this non-convexity, we introduce a combinatorial object called the Poincaré-Reeb tree associated to a level curve and to a projection direction. Our goal is to characterize all topological types of Poincaré-Reeb trees. I will explain how to construct a family of polynomials that realizes a large class of these trees. Moreover, in a joint work with Arnaud Bodin and Patrick Popescu-Pampu, we extend the previous method of study of non-convexity to real algebraic domains.
Password: 123456
Abstract:
Consider a real bivariate polynomial function that has a strict local minimum at the origin and that vanishes at this point. In a sufficiently small neighborhood of the origin, the non-zero level curves of this function are smooth Jordan curves. Whenever the origin is a Morse strict local minimum, the small enough level curves become boundaries of convex topological disks. Otherwise, the levels may be non-convex, as was proven by M. Coste. In order to measure this non-convexity, we introduce a combinatorial object called the Poincaré-Reeb tree associated to a level curve and to a projection direction. Our goal is to characterize all topological types of Poincaré-Reeb trees. I will explain how to construct a family of polynomials that realizes a large class of these trees. Moreover, in a joint work with Arnaud Bodin and Patrick Popescu-Pampu, we extend the previous method of study of non-convexity to real algebraic domains.