# Optimal frame designs for multitasking devices with weight restrictions

**Authors:** Mar\'ia Jos\'e Benac, Pedro Massey, Mariano Ruiz, Demetrio, Stojanoff

arXiv: 1705.03376 · 2020-07-10

## TL;DR

This paper introduces a framework for designing optimal frames for multitasking devices with weight restrictions, providing algorithms to find universally optimal configurations minimizing convex potentials and energy use.

## Contribution

It characterizes the existence of such designs via majorization relations and develops a finite-step algorithm for constructing universally optimal frames.

## Key findings

- Existence of optimal $(	ext{alpha}, 	extbf{d})$-designs characterized by majorization.
- Development of a finite-step algorithm for universal optimality.
- Optimal designs minimize joint convex potentials, including frame potential and mean square error.

## Abstract

Let $\mathbf d=(d_j)_{j\in\mathbb I_m}\in\mathbb N^m$ be a finite sequence (of dimensions) and $\alpha=(\alpha_i)_{i\in\mathbb I_n}$ be a sequence of positive numbers (of weights), where $\mathbb I_k=\{1,\ldots,k\}$ for $k\in\mathbb N$. We introduce the $(\alpha\, , \,\mathbf d)$-designs i.e., $m$-tuples $\Phi=(\mathcal F_j)_{j\in\mathbb I_m}$ such that $\mathcal F_j=\{f_{ij}\}_{i\in\mathbb I_n}$ is a finite sequence in $\mathbb C^{d_j}$, $j\in\mathbb I_m$, and such that the sequence of non-negative numbers $(\|f_{ij}\|^2)_{j\in\mathbb I_m}$ forms a partition of $\alpha_i$, $i\in\mathbb I_n$. We characterize the existence of $(\alpha\, , \, \mathbf d)$-designs with prescribed properties in terms of majorization relations. We show, by means of a finite-step algorithm, that there exist $(\alpha\, , \, \mathbf d)$-designs $\Phi^{\rm op}=(\mathcal F_j^{\rm op})_{j\in\mathbb I_m}$ that are universally optimal; that is, for every convex function $\varphi:[0,\infty)\rightarrow [0,\infty)$ then $\Phi^{\rm op}$ minimizes the joint convex potential induced by $\varphi$ among $(\alpha\, , \, \mathbf d)$-designs, namely $$ \sum_{j\in\mathbb I_m}\text{P}_\varphi(\mathcal F_j^{\rm op})\leq \sum_{j\in \mathbb I_m}\text{P}_\varphi(\mathcal F_j) $$ for every $(\alpha\, , \, \mathbf d)$-design $\Phi=(\mathcal F_j)_{j\in\mathbb I_m}$, where $\text{P}_\varphi(\mathcal F)=tr(\varphi(S_{\mathcal F}))$; in particular, $\Phi^{\rm op}$ minimizes both the joint frame potential and the joint mean square error among $(\alpha\, , \, \mathbf d)$-designs. We show that in this case $\mathcal F_j^{\rm op}$ is a frame for $\mathbb C^{d_j}$, for $j\in\mathbb I_m$. This corresponds to the existence of optimal encoding-decoding schemes for multitasking devices with energy restrictions.

## Full text

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## Figures

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## References

27 references — full list in the complete paper: https://tomesphere.com/paper/1705.03376/full.md

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Source: https://tomesphere.com/paper/1705.03376