Based on joint work with Andreas Kreuml and Elisabeth M. Werner.

In order to show that the random normal is “good” we prove that the set of “bad” vectors is small: we construct a net on it of small cardinality. This net is a subset of a net on the sphere with simple lattice structure, and its construction relies on the method of random rounding. To show that the cardinality of this subset is small, we show that most of the vectors on a lattice are “good”, and therefore cannot be close to “bad” vectors. This key step is done via harmonic-analytic techniques from discrepancy theory. This is a joint work with K. Tikhomirov and R. Vershynin.

In this talk, I will present a recent work in which we prove a new upper bound for $N(n)$. This bound improves Rogers' previous best bound, which is of the order of ${2n \choose n} n\ln n$, by a sub-exponential factor. Our approach combines ideas from previous work with tools from asymptotic geometric analysis. As a key step, we use thin-shell estimates for isotropic log-concave measures to prove a new lower bound for the maximum volume of the intersection of a convex body $K$ with a translate of $-K$. We further show that the same bound holds for the volume of $K\cap(-K)$ if the center of mass of $K$ is at the origin.

If time permits we shall discuss some other methods and results concerning this problem and its relatives.

Joint work with H. Huang, B. Vritsiou, and T. Tkocz

In this talk we consider a class of $\lambda$-concave bodies in $\mathbb R^{n+1}$; that is, convex bodies with the property that each of their boundary points supports a tangent ball of radius $1/\lambda$ that lies locally (around the boundary point) inside the body. In this class, we solve a reverse isoperimetric problem: we show that the convex hull of two balls of radius $1/\lambda$ (a sausage body) is a unique volume minimizer among all $\lambda$-concave bodies of given surface area. This is joint work with Roman Chernov and Kostiantyn Drach.

Based on joint work with U. Caglar and A. V. Kolesnikov.

Under what conditions on a nonzero finite Borel measure $\mu$ defined on the unit sphere, continuous functions $\varphi: (0, \infty)\rightarrow (0, \infty)$ and $G:\ (0,\infty)\times S^{n-1}\rightarrow(0,\infty)$ can we find a convex body $K$ (with the origin in its interior) solving the following optimization problems \[\inf /\sup \left\{ \int_{S^{n-1}}\varphi(h_{Q}(u))d\mu(u): Q\in \widetilde{\mathcal{B}} \right\}, \] where $ \widetilde{\mathcal{B}}=\big\{Q\in\mathcal{K}_{(o)}^n:\ \widetilde{V}_G{(Q^\circ)}=\widetilde{V}_G{(B^n)}\big\}$ with $B^n$ the unit ball and $\widetilde{V}_G$ the general dual volume. In particular, we will present the existence, continuity and uniqueness of the solutions for the general dual-polar Orlicz-Minkowski problem. This talk is based on a joint work with Deping Ye and Baocheng Zhu.

This talk is based on a joint paper with Luo and Zhu.