SoSe 16: BasisM Diskrete Geometrie II
Günter Ziegler
Information for students
Zielgruppe:
The target audience are students with an interest in discrete mathematics and (convex) geometry. The course is a good entry point for a specialization in discrete geometry. The topics addressed in the course supplement and deepen the understanding for discrete-geometric structures appearing in differential geometry, topology, combinatorics, and algebraic geometry.
closeAdditional information / Pre-requisites
Solid background in linear algebra and some analysis. Basic knowledge and experience with polytopes and/or convexity (as from the course "Discrete Geometry I") will be helpful. .
Comments
Inhalt:
This is the second in a series of three courses on discrete geometry. The aim of the course is a skillful handling of discrete geometric structures with an emphasis on metric and convex geometric properties. In the course we will develop central themes in metric and convex geometry including proof techniques and applications to other areas in mathematics.
The material will be a selection of the following topics:
Linear programming and some applications
- Linear programming and duality
- Pivot rules and the diameter of polytopes
Subdivisions and triangulations
- Delaunay and Voronoi
- Delaunay triangulations and inscribable polytopes
- Weighted Voronoi diagrams and optimal transport
Basic structures in discrete geometr
- point configurations and arrangements
- incidence problems
- geometric selection theorems
- convexity and separation theorems
- convex bodies and polytopes/polyhedra
- polarity
- Mahler’s conjecture
- approximation by polytopes
- Hilbert’s third problem
- volumes and mixed volumes
- volume computations and estimates
- Löwner-John ellipsoids and roundness
- valuations
- Brunn-Minkowski and Alexandrov-Fenchel inequality
- isoperimetric inequalities
- measure concentration and phenomena in high-dimensions
- lattices
- Minkowski's (first) theorem
- successive minima
- lattice points in convex bodies and Ehrhart's theorem
- Ehrhart-Macdonald reciprocity
- lattice packings and coverings
- the Theorem of Minkowski-Hlawka
- analytic methods
- epsilon-nets
Basic structures in convex geometry
Volumes and roundness
Geometric inequalities
Geometry of numbers
Sphere packings
Applications in optimization, number theory, algebra, algebraic geometry, and functional analysis
closeSuggested reading
The course will use material from P. M. Gruber, " Convex and Discrete Geometry" (Springer 2007) and various other sources.
27 Class schedule
Regular appointments
Inhalt:
This is the second in a series of three courses on discrete geometry. The aim of the course is a skillful handling of discrete geometric structures with an emphasis on metric and ... read more