Agent Arrangement Problem
Abstract
An {\em arrangement} of an ordered pair of graphs is defined as a function from to such that, for each vertex of , the vertex-set of either is (the case when ) or induces a connected subgraph of and that the family is a partition of . Let be an arrangement of , let be an edge of and let be a subset of such that each of the three graphs , and is ether connected or and that . A {\em transfer} of from to is defined as the modification of such that for every and for every . Two arrangements and of are called {\em t-equivalent} if they can be transformed into each other by a finite sequence of transfers. An ordered pair of graphs is called {\em almighty} if every two arrangements of the pair are t-equivalent. In this study, we consider the following two decision problems. [{\bf (P1)}]{For a given pair of arrangements and of a given ordered pair of graphs, decide whether is t-equivalent to or not.} [{\bf (P2)}]{For a given ordered pair of graphs, decide whether the pair is almighty or not.} We show an -time algorithm for {\bf (P1)}, and prove the -completeness of {\bf (P2)}.
Cite
@article{arxiv.1212.2306,
title = {Agent Arrangement Problem},
author = {Tomoki Nakamigawa and Tadashi Sakuma},
journal= {arXiv preprint arXiv:1212.2306},
year = {2012}
}
Comments
32 pages, 5 figures