Fully dynamic approximation schemes on planar and apex-minor-free graphs
Abstract
The classic technique of Baker [J. ACM '94] is the most fundamental approach for designing approximation schemes on planar, or more generally topologically-constrained graphs, and it has been applied in a myriad of different variants and settings throughout the last 30 years. In this work we propose a dynamic variant of Baker's technique, where instead of finding an approximate solution in a given static graph, the task is to design a data structure for maintaining an approximate solution in a fully dynamic graph, that is, a graph that is changing over time by edge deletions and edge insertions. Specifically, we address the two most basic problems -- Maximum Weight Independent Set and Minimum Weight Dominating Set -- and we prove the following: for a fully dynamic n-vertex planar graph G, one can: * maintain a (1-)-approximation of the maximum weight of an independent set in G with amortized update time f()· no(1); and, * under the additional assumption that the maximum degree of the graph is bounded at all times by a constant, also maintain a (1+)-approximation of the minimum weight of a dominating set in G with amortized update time f()· no(1). In both cases, f() is doubly-exponential in poly(1/) and the data structure can be initialized in time f()· n1+o(1). All our results in fact hold in the larger generality of any graph class that excludes a fixed apex-graph as a minor.
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