
doi: 10.1007/bf02776056
handle: 20.500.14243/157771 , 2158/3077
For \(\varepsilon> 0\), let \(N(n,\varepsilon)\) be the minimum number of successive Steiner symmetrizations sufficient to transform any convex body in \(\mathbb{R}^n\), with volume equal to the volume of the unit ball \(B^n\), into a convex body whose Hausdorff distance from \(B^n\) is at most \(\varepsilon\). Complementing known upper estimates of this number, the authors first construct, for any positive integers \(n\geq 2\) and \(m\), an \(n\)-dimensional convex body with the property that any \(m\) successive Steiner symmetrizations do not decrease the distance of the transformed body from a ball. From this, they deduce that \[ N(n,\varepsilon)\geq {\log(\log(1/\varepsilon))\over\log 2} \,(1+ o(1))\qquad\text{as}\quad\varepsilon\to 0. \]
Steiner symmetrization, Convex sets in \(n\) dimensions (including convex hypersurfaces)
Steiner symmetrization, Convex sets in \(n\) dimensions (including convex hypersurfaces)
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