English

Symmetric separable convex resource allocation problems with structured disjoint interval bound constraints

Optimization and Control 2023-07-31 v1

Abstract

Motivated by the problem of scheduling electric vehicle (EV) charging with a minimum charging threshold in smart distribution grids, we introduce the resource allocation problem (RAP) with a symmetric separable convex objective function and disjoint interval bound constraints. In this RAP, the aim is to allocate an amount of resource over a set of nn activities, where each individual allocation is restricted to a disjoint collection of mm intervals. This is a generalization of classical RAPs studied in the literature where in contrast each allocation is only restricted by simple lower and upper bounds, i.e., m=1m=1. We propose an exact algorithm that, for four special cases of the problem, returns an optimal solution in O((n+m2m2)(nlogn+nF))O \left(\binom{n+m-2}{m-2} (n \log n + nF) \right) time, where the term nFnF represents the number of flops required for one evaluation of the separable objective function. In particular, the algorithm runs in polynomial time when the number of intervals mm is fixed. Moreover, we show how this algorithm can be adapted to also output an optimal solution to the problem with integer variables without increasing its time complexity. Computational experiments demonstrate the practical efficiency of the algorithm for small values of mm and in particular for solving EV charging problems.

Keywords

Cite

@article{arxiv.2307.15459,
  title  = {Symmetric separable convex resource allocation problems with structured disjoint interval bound constraints},
  author = {Martijn H. H. Schoot Uiterkamp},
  journal= {arXiv preprint arXiv:2307.15459},
  year   = {2023}
}

Comments

20 pages, 4 figures

R2 v1 2026-06-28T11:42:45.120Z