The role of intrinsic distances in the relaxation of L∞-functionals

Abstract

We consider a supremal functional of the form F(u)= ess\: sup x ∈ f(x,Du(x)) where ⊂eq RN is a regular bounded open set, u∈ W1,∞() and f is a Borel function. Assuming that the intrinsic distances dλF(x,y):= \ u(x) - u(y): \, F(u)≤ λ \ are locally equivalent to the euclidean one for every λ>∈fW1,∞() F, we give a description of the sublevel sets of the weak*-lower semicontinuous envelope of F in terms of the sub-level sets of the difference quotient functionals RdλF(u):=x =y u(x)-u(y)dλF(x,y). As a consequence we prove that the relaxed functional of positive 1-homogeneous supremal functionals coincides with Rd1F. Moreover, for a more general supremal functional F (a priori non coercive), we prove that the sublevel sets of its relaxed functionals with respect to the weak* topology, the weak* convergence and the uniform convergence are convex. The proof of these results relies both on a deep analysis of the intrinsic distances associated to F and on a careful use of variational tools such as -convergence.