English

Fully Dynamic Bin Packing Revisited

Data Structures and Algorithms 2015-01-15 v2

Abstract

We consider the fully dynamic bin packing problem, where items arrive and depart in an online fashion and repacking of previously packed items is allowed. The goal is, of course, to minimize both the number of bins used as well as the amount of repacking. A recently introduced way of measuring the repacking costs at each timestep is the migration factor, defined as the total size of repacked items divided by the size of an arriving or departing item. Concerning the trade-off between number of bins and migration factor, if we wish to achieve an asymptotic competitive ration of 1+ϵ1 + \epsilon for the number of bins, a relatively simple argument proves a lower bound of Ω(1ϵ)\Omega(\frac{1}{\epsilon}) for the migration factor. We establish a nearly matching upper bound of O(1ϵ4log1ϵ)O(\frac{1}{\epsilon}^4 \log \frac{1}{\epsilon}) using a new dynamic rounding technique and new ideas to handle small items in a dynamic setting such that no amortization is needed. The running time of our algorithm is polynomial in the number of items nn and in 1ϵ\frac{1}{\epsilon}. The previous best trade-off was for an asymptotic competitive ratio of 54\frac{5}{4} for the bins (rather than 1+ϵ1+\epsilon) and needed an amortized number of O(logn)O(\log n) repackings (while in our scheme the number of repackings is independent of nn and non-amortized).

Keywords

Cite

@article{arxiv.1411.0960,
  title  = {Fully Dynamic Bin Packing Revisited},
  author = {Sebastian Berndt and Klaus Jansen and Kim-Manuel Klein},
  journal= {arXiv preprint arXiv:1411.0960},
  year   = {2015}
}
R2 v1 2026-06-22T06:47:47.955Z