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Rotation Invariant Minkowski Classes of Convex Bodies

Rotation Invariant Minkowski Classes of Convex Bodies. Franz Schuster Vienna University of Technology joint work with Rolf Schneider. Def inition. Notation.

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Rotation Invariant Minkowski Classes of Convex Bodies

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  1. Rotation Invariant Minkowski Classes of Convex Bodies Franz Schuster Vienna University of Technology joint work with Rolf Schneider

  2. Definition Notation The elements of a Minkowski class will be called -bodies. A convex body K will be called a generalized -body if there exist -bodies T1, T2 such that Let denote the space of convex bodies, i.e. compact, convex sets in n-dimensional Euclidean space , n  2. K + T1 = T2. Minkowski Classes Definition A Minkowski class is a subset of , which is closed in the Hausdorff metric and closed under Minkowski linear combinations, i.e. K, L  , ,   0  K + L  .

  3. Remarks: A convex body L is an -body if and only if L can be approximated by bodies of the form 1g1K + ... + mgmK, i  0, gi  G. Invariant and Generated Minkowski Classes Definition Let G be a group of transformations of . We call a Minkowski class G-invariant if K   gK   g  G. The smallest G-invariant Minkowski class containing a given convex body K is said to be the G-invariant Minkowski class generated by K.

  4. Remarks: A convex body L is an -body if and only if L can be approximated by bodies of the form A convex body L is a generalized -body if and only if h(L, . )  clspan{h(gK, . ): g  G}. 1g1K + ... + mgmK, i  0, gi  G. Invariant and Generated Minkowski Classes Definition Let G be a group of transformations of . We call a Minkowski class G-invariant if K   gK   g  G. The smallest G-invariant Minkowski class containing a given convex body K is said to be the G-invariant Minkowski class generated by K.

  5. Facts: = but is nowhere dense in for n  3 2 2 c c The set of generalized zonoids is dense in for every n  2. c Zonoids and Generalized Zonoids Reminder A convex body in is called a zonoid if it can be approximated by Minkowski sums of finitely many closed line segments. Let denote the set of zonoids. A convex body K in is called a generalized zonoid if there are Z1, Z2  such that K + Z1 = Z2.

  6. Fact: For n  3, the affine invariant Minkowski class generated by a convex body is nowhere dense in . c as a Minkowski Class Reminder The set of zonoids is the rigid motion invariant Minkowski class generated by a segment. is also the affine invariant Minkowski class generated by a segment. A convex body is a generalized zonoid if it is a generalized -body.

  7. Theorem [Alesker, 2003]: If is the SL(n)-invariant Minkowski class generated by a non-symmetric convex body, then the set of generalized -bodies is dense in . K A3T A1T A2T SL(n)-Invariant Minkowski Classes

  8. K SL(n)- vs. SO(n)-Invariant Minkowski Classes Theorem [Schneider, 1996]: LetT beatriangle.Thenthereexistsanaffinemap A such that for the SO(n)-invariant Minkowski class generated by AT, the set of generalized -bodies is dense in . AT

  9. Remark: The perturbation by the linear transformation A is necessary in general, as shown by bodies of constant width (or the ball). SO(n)-Invariant Minkowski Classes Theorem [Schneider & S., 2006]: LetK benon-symmetric.Thenthereexistsalinear map A, arbitrarily close to the identity, such that for the SO(n)-invariant Minkowski class generated by AK, the set of generalized -bodies is dense in .

  10. Universal Convex Bodies Definition A convex body K  is called universal, if m h(K, . )  0  m  0. Notation n Letm:C(Sn–1) denotetheorthogonal projection onto the space of spherical harmonics of dimension n and order m. m n m

  11. Theorem 1 Idea of the Proof of Theorem 2: Let K be a convex body and let be the SO(n) invariant Minkowski class generated by K. Then the set of generalized -bodies is dense in if and only if K is universal. n Let {Ym1, …, YmN} be an orthonormal basis of . Then m A hAK,Ymj=hAKYmj d Sn – 1 is real analytic in a neighborhood of Id in . 2 Theorem 2 Let K  be non-symmetric. Then there exists a linear map A, arbitrarily close to the identity, such that AK is universal. Universal Convex Bodies

  12. Let f  C(Sn – 1), then  ftij() d = f , YmjYmi. m SO(n) 1 N(n,m) Basic Facts on Spherical Harmonics Facts: n is invariant under the action of SO(n), thus there are real numbers tij () such that for   SO(n) m m Ymj = tij()Ymi. N(n,m) m i = 1

  13. Since K is universal, cmj(m)  0 for some j(m) and every m. Define bij = if j = j(m) and 0 otherwise and let m ami g() = N(n,m)  bij tij(). k N(n,m) m m cmj(m) m = 0 i, j = 1 Result: h(K,u)g()d = h(L,u) SO(n) The Proof of Theorem 1 Definitions: Let K  be universal, cmj=hK ,Ymj and let L  , i.e. n h(L, . ) = amjYmj. k N(n,m) m = 0 j = 1

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