Independent Set Hardness in Graphs of Bounded Twin-Width and Low-Radius Merge-Width

Abstract

For every > 0, Max Independent Set admits a polynomial-time n-approximation algorithm on n-vertex graphs of effectively bounded twin-width [Bergé et al., STACS '23]. The approximation factor actually obtained is more precisely nO(1/ n). Prior to the current paper, no approximation hardness was known for this problem, and the existence of a polynomial-time approximation scheme (PTAS) was repeatedly raised as an open question. We answer this question in a strong sense: We show that there is a constant γ> 0 such that a polynomial-time nγ/ ( n)2-approximation algorithm for Max Independent Set on graphs of twin-width at most 4 would refute the Exponential-Time Hypothesis (ETH). This lower bound further holds if a 4-sequence is provided as part of the input. We show the same hardness of approximation for Min Coloring, which also has a nearly matching nO(1/ n)-approximation algorithm on graphs of effectively bounded twin-width. We also clarify the parameterized complexity of k-Independent Set on graphs of bounded radius-r merge-width when the range of r is limited. There is a fixed-parameter tractable algorithm for k-Independent Set on graphs given with radius-2O(k2) merge sequences of bounded width [Dreier and Toruńczyk, STOC '25]. We complement this result by showing that k-Independent Set is W[1]-hard on graphs given with radius-o(k) merge sequences of bounded width. We further show that this result also holds for k-Dominating Set.

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