Date:
Thu, 23/11/202314:30-15:30
Location:
Manchester Building (Hall 2), Hebrew University Jerusalem
Title: Boxing inequality
Abstract:
Recall the definition of the $m$th Hausdorff content of a metric space $X$: it is the infimum of $\sum d_i^m$, where
the infimum is taken over all coverings of $X$ by a finite collection of open metric balls, and $d_i$
denote the diameters of these balls.
A metric subspace $X$ of a Banach space (of finite or infinite dimension) can always be contracted via a homotopy to an $(m-1)$-dimensional subpolyhedron. The boxing inequality states that the $m$th Hausdorff content of the homotopy can be bounded in terms of the $m$th Hausdorff content of $X$. Note, that this differs from the classical isoperimetric case where the $(m+1)$th volume of the filling is bounded.
I will discuss the proof of this result and its connections to the notions of Gromov's filling radius, Urysohn width, systole, relations between these notions, and corresponding geometric inequalities.
Location: Manchester Building (Hall 2), Hebrew University Jerusalem
Abstract:
Recall the definition of the $m$th Hausdorff content of a metric space $X$: it is the infimum of $\sum d_i^m$, where
the infimum is taken over all coverings of $X$ by a finite collection of open metric balls, and $d_i$
denote the diameters of these balls.
A metric subspace $X$ of a Banach space (of finite or infinite dimension) can always be contracted via a homotopy to an $(m-1)$-dimensional subpolyhedron. The boxing inequality states that the $m$th Hausdorff content of the homotopy can be bounded in terms of the $m$th Hausdorff content of $X$. Note, that this differs from the classical isoperimetric case where the $(m+1)$th volume of the filling is bounded.
I will discuss the proof of this result and its connections to the notions of Gromov's filling radius, Urysohn width, systole, relations between these notions, and corresponding geometric inequalities.
Location: Manchester Building (Hall 2), Hebrew University Jerusalem