Minkowski norm and Hessian isometry induced by an isoparametric foliation on the unit sphere

Abstract

Let Mt be an isoparametric foliation on the unit sphere (Sn-1(1),gst) with d principal curvature values. Using the spherical coordinates induced by Mt, we construct a Minkowski norm with the presentation F=r2f(t), which generalizes the notions of (α,β)-norm and (α1,α2)-norm. Using the technique of spherical local frame, we give an exact and explicit answer for the question when F=r2f(t) really defines a Minkowski norm. Using the similar technique, we study the Hessian isometry between two Minkowski norms induced by Mt, which preserves the orientation and fixes the spherical -coordinates. There are two ways to describe this , either by a system of ODEs, or by its restriction to any normal plane for Mt, which is then reduced to a Hessian isometry between Minkowski norms on R2 satisfying certain symmetry and d-properties. When d>2, we prove this can be obtained by gluing positive scalar multiplications and compositions between the Legendre transformation and positive scalar multiplications, so it must satisfy the (d)-property for any orthogonal decomposition Rn=V'+V'', i.e., for any nonzero x=x'+x'' and (x)=x=x'+x'', with x',x'∈V' and x'',x''∈V'', we have gxF1(x'',x)=gxF2(x'',x) . As byproducts, we prove the following results. On the indicatrix (SF,g), where F is a Minkowski norm induced by Mt and g is the Hessian metric, the foliation Nt=SF R>0M0 is isoparametric. Laugwitz Conjecture is valid for a Minkowski norm F induced by Mt, i.e, if its Hessian metric g is flat on Rn\0\ with n>2, then F is Euclidean.