Solving Sequential Greedy Problems Distributedly with Sub-Logarithmic Energy Cost
Abstract
We study the awake complexity of graph problems that belong to the class O-LOCAL, which includes a subset of problems solvable by sequential greedy algorithms, such as (+1)-coloring and maximal independent set. It is known from previous work that, in n-node graphs of maximum degree , any problem in the class O-LOCAL can be solved by a deterministic distributed algorithm with awake complexity O(+ n). In this paper, we show that any problem belonging to the class O-LOCAL can be solved by a deterministic distributed algorithm with awake complexity O( n· n). This leads to a polynomial improvement over the state of the art when 2 n, e.g., =nε for some arbitrarily small ε>0. The key ingredient for achieving our results is the computation of a network decomposition, that uses a small-enough number of colors, in sub-logarithmic time in the Sleeping model, which can be of independent interest.
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