English

Encoding Tasks and R\'enyi Entropy

Information Theory 2014-10-07 v2 math.IT

Abstract

A task is randomly drawn from a finite set of tasks and is described using a fixed number of bits. All the tasks that share its description must be performed. Upper and lower bounds on the minimum ρ\rho-th moment of the number of performed tasks are derived. The case where a sequence of tasks is produced by a source and nn tasks are jointly described using nRnR bits is considered. If RR is larger than the R\'enyi entropy rate of the source of order 1/(1+ρ)1/(1+\rho) (provided it exists), then the ρ\rho-th moment of the ratio of performed tasks to nn can be driven to one as nn tends to infinity. If RR is smaller than the R\'enyi entropy rate, this moment tends to infinity. The results are generalized to account for the presence of side-information. In this more general setting, the key quantity is a conditional version of R\'enyi entropy that was introduced by Arimoto. For IID sources two additional extensions are solved, one of a rate-distortion flavor and the other where different tasks may have different nonnegative costs. Finally, a divergence that was identified by Sundaresan as a mismatch penalty in the Massey-Arikan guessing problem is shown to play a similar role here.

Keywords

Cite

@article{arxiv.1401.6338,
  title  = {Encoding Tasks and R\'enyi Entropy},
  author = {Christoph Bunte and Amos Lapidoth},
  journal= {arXiv preprint arXiv:1401.6338},
  year   = {2014}
}

Comments

12 pages; accepted for publication in the IEEE Transactions on Information Theory; minor changes in the presentation; added a section on tasks with costs; presented in part at ITW 2013; to be presented in part at ISIT 2014

R2 v1 2026-06-22T02:54:07.714Z