Belt diameter of some class of space lling zonotopes

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Belt diameter of some class of space lling zonotopes Alexey Garber Moscow State University and Delone Laboratory of Yaroslavl State University, Russia Alexandro Readings, Moscow State University May 22, 2012

Polytopes with centrally symmetric facets Consider a family P C of all d-dimensional polytopes with centrally symmetric facets. Theorem (A.D. Alexandrov anf G.C. Shephard) Every polytope from P C is centrally symmetric itself. Let P be any polytope from P C.

Polytopes with centrally symmetric facets Consider a family P C of all d-dimensional polytopes with centrally symmetric facets. Theorem (A.D. Alexandrov anf G.C. Shephard) Every polytope from P C is centrally symmetric itself. Let P be any polytope from P C. Denition For any (d 2)-dimensional face F of P we can dene a belt B P (F ) as a set of all facets of P parallel to F.

Polytopes with centrally symmetric facets Consider a family P C of all d-dimensional polytopes with centrally symmetric facets. Theorem (A.D. Alexandrov anf G.C. Shephard) Every polytope from P C is centrally symmetric itself. Let P be any polytope from P C. Denition For any (d 2)-dimensional face F of P we can dene a belt B P (F ) as a set of all facets of P parallel to F. We can construct it by moving from one facet to another across (d 2)-faces parallel to F.

Constructing belts

Constructing belts

Constructing belts

Constructing belts

Constructing belts

Constructing belts

Constructing belts

Belt distance and belt diameter Denition Belt distance between two facets of P is the minimal number of belts that we need to travel from one facets to another.

Belt distance and belt diameter Denition Belt distance between two facets of P is the minimal number of belts that we need to travel from one facets to another.

Belt distance and belt diameter Denition Belt distance between two facets of P is the minimal number of belts that we need to travel from one facets to another. Denition Belt diameter of P is the maximal belt distance between its facets.

Why this is interesting? Conjecture (G.Voronoi, 1909) Every convex polytope that tiles space with translation copies is anely equivalent to Dirichlet-Voronoi polytope of some lattice.

Why this is interesting? Conjecture (G.Voronoi, 1909) Every convex polytope that tiles space with translation copies is anely equivalent to Dirichlet-Voronoi polytope of some lattice. One of the most popular (and one the most successful for now) approaches to prove the Voronoi conjecture in parallelohedra theory uses a canonical scaling function. And values of canonical scaling can be uniquely dened on facets in one belt of length equal to 6.

Questions Problem What is the maximal belt diameter of d-dimensional polytope?

Questions Problem What is the maximal belt diameter of d-dimensional polytope? It is easy to see that answer for d = 3 is 2.

Questions Problem What is the maximal belt diameter of d-dimensional polytope? It is easy to see that answer for d = 3 is 2. We can add some restriction for maximal length of any belt or we can restrict ourselves only to certain subfamily of polytopes with centrally symmetric facets. Or both.

Small belt lengths There is only one d-dimensional polytope with all belts consist of 4 facets. It is the d-dimensional cube and its belt diameter is equal to 1.

Small belt lengths There is only one d-dimensional polytope with all belts consist of 4 facets. It is the d-dimensional cube and its belt diameter is equal to 1. The situation is much more interesting for those polytopes who has belts of length 4 or 6. It was proved that conditions to have centrally symmetric facets and belts of length at most 6 are necessary (H.Minkowski, 1897) and sucient (B.Venkov, 1954) for convex polytope to be a parallelohedron, i.e. to tile R d with parallel copies.

Small belt lengths There is only one d-dimensional polytope with all belts consist of 4 facets. It is the d-dimensional cube and its belt diameter is equal to 1. The situation is much more interesting for those polytopes who has belts of length 4 or 6. It was proved that conditions to have centrally symmetric facets and belts of length at most 6 are necessary (H.Minkowski, 1897) and sucient (B.Venkov, 1954) for convex polytope to be a parallelohedron, i.e. to tile R d with parallel copies. There are 5 three-dimensional parallelohedra, 52 four-dimensional and dozens of thousands of ve-dimensional. And maximal belt diameter is unknown for all cases except R 3.

Zonotopes Denition A polytope is called a zonotope if it is a porjection of cube. Or equivalently it is a Minkowski sum of nite number of segments. In that case we will denote this polytope as Z(U) where U is the correspondent vector set.

Zonotopes Denition A polytope is called a zonotope if it is a porjection of cube. Or equivalently it is a Minkowski sum of nite number of segments. In that case we will denote this polytope as Z(U) where U is the correspondent vector set. The equivalent property is the following. Theorem (P. McMullen, 1980) For d > 3 a d-dimensional polytope is a zonotope if and only if all (d 2)-faces of P are centrally symmetric.

Questions about belt diameter of zonotopes Problem What is the maximal belt diameter of d-dimensional space-lling zonotopes, i.e. for zonotopes with belt length at most 6?

Questions about belt diameter of zonotopes Problem What is the maximal belt diameter of d-dimensional space-lling zonotopes, i.e. for zonotopes with belt length at most 6? Problem What is the maximal belt diameter of d-dimensional zonotopes with belt length at most 2k, k > 3?

Questions about belt diameter of zonotopes Problem What is the maximal belt diameter of d-dimensional space-lling zonotopes, i.e. for zonotopes with belt length at most 6? Problem What is the maximal belt diameter of d-dimensional zonotopes with belt length at most 2k, k > 3? Claim If k d or if we do not restrict he maximal value of belt length then the answer is d 1 and it is sharp.

An idea how to get an upper bound Denition Two sets E and F of d 1 vectors in R d each are called conjugated if dim(e fi) = dim(f ej = d. Correspondent zonotope Z(E F ) is called symmetric. Theorem (A.G.) The maximal belt diameter for zonotope is also achieved on some symmetric zonotope of smaller or equal dimension.

A new basis for symmetric zonotopes Lemma For space-lling zonotopes we can nd an upper bound only for zonotopes with set of zone vectors V = ( Ed 1 A 0... 0 1... 1 ), where A is a 0/1-matrix with at least half of zeros in each row.

Results on belt diameter of zonotopes Theorem (A.G.) Belt diameter of d-dimensional space-lling zonotope is not greater than log 2 ( 45 d ).

Results on belt diameter of zonotopes Theorem (A.G.) Belt diameter of d-dimensional space-lling zonotope is not greater than log 2 ( 45 d ). Using similar technique for arbitrary belt length we can prove Claim Belt diameter of d-dimensional zonotope with belt length at most k does not exceed log 1+ 1 d k 2

Π-zonotopes and their diameters Denition If U is a subset of the vector set E(d) = {ei ej} d+1 i,j=1 where e i is the standard basis in R d+1 then zonotope Z(U) is called a Π-zonotope.

Π-zonotopes and their diameters Denition If U is a subset of the vector set E(d) = {ei ej} d+1 i,j=1 where e i is the standard basis in R d+1 then zonotope Z(U) is called a Π-zonotope. Theorem (A.G.) Belt diameter of d-dimensional Π-zonotope is not greater than 2 if d 6 and 3 if d > 6. These bounds are sharp in any dimension.

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