Rado's covering problem for cubes and balls: a semi-survey

Abstract

What is the largest constant c∈ [0,1] with the property that every finite collection C of axis-parallel squares in the plane admits a disjoint sub-collection S occupying at least a fraction c of the area covered by C? This problem was first raised by T.~Rad\'o in 1928, who was motivated by a classical covering lemma in real analysis due to Vitali. R.~Rado later generalized the problem from axis-parallel squares in the plane to homothetic copies of any given convex body K in Rd, where now we are looking for an optimal constant F(K). Our utmost interest is for cubes and balls in the high-dimensional regime d→ ∞. The estimates that we currently have for cubes are much more precise than those for balls: namely if Qd is a d-dimensional cube, then \[ (e-1+o(1))2-dd d ≤ F(Qd)≤ 2-d, \] while denoting Bd a d-dimensional Euclidean ball, then \[ (1+εd)3-d≤ F(Bd)≤ 2.447-d, \] where εd>0 vanishes exponentially fast as d→ ∞. The latter upper bound is obtained here by using the Kabatiansky--Levenshtein bound for the sphere packing problem.