Optimal frame designs for multitasking devices with weight restrictions

Abstract

Let d=(dj)j∈ Im∈ Nm be a finite sequence (of dimensions) and α=(αi)i∈ In be a sequence of positive numbers (of weights), where Ik=\1,…,k\ for k∈ N. We introduce the (α\, , \, d)-designs i.e., m-tuples =( Fj)j∈ Im such that Fj=\fij\i∈ In is a finite sequence in Cdj, j∈ Im, and such that the sequence of non-negative numbers (\|fij\|2)j∈ Im forms a partition of αi, i∈ In. We characterize the existence of (α\, , \, d)-designs with prescribed properties in terms of majorization relations. We show, by means of a finite-step algorithm, that there exist (α\, , \, d)-designs op=( Fj op)j∈ Im that are universally optimal; that is, for every convex function :[0,∞)→ [0,∞) then op minimizes the joint convex potential induced by among (α\, , \, d)-designs, namely Σj∈ ImP( Fj op)≤ Σj∈ ImP( Fj) for every (α\, , \, d)-design =( Fj)j∈ Im, where P( F)=tr((S F)); in particular, op minimizes both the joint frame potential and the joint mean square error among (α\, , \, d)-designs. We show that in this case Fj op is a frame for Cdj, for j∈ Im. This corresponds to the existence of optimal encoding-decoding schemes for multitasking devices with energy restrictions.