1. Twin-width and Polynomial Kernels.
- Author
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Bonnet, Édouard, Kim, Eun Jung, Reinald, Amadeus, Thomassé, Stéphan, and Watrigant, Rémi
- Subjects
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POLYNOMIAL time algorithms , *POLYNOMIALS , *DOMINATING set , *STATISTICAL decision making - Abstract
We study the existence of polynomial kernels, for parameterized problems without a polynomial kernel on general graphs, when restricted to graphs of bounded twin-width. Our main result is that a polynomial kernel for k-Dominating Set on graphs of twin-width at most 4 would contradict a standard complexity-theoretic assumption. The reduction is quite involved, especially to get the twin-width upper bound down to 4, and can be tweaked to work for Connectedk-Dominating Set and Totalk-Dominating Set (albeit with a worse upper bound on the twin-width). The k-Independent Set problem admits the same lower bound by a much simpler argument, previously observed [ICALP '21], which extends to k-Independent Dominating Set, k-Path, k-Induced Path, k-Induced Matching, etc. On the positive side, we obtain a simple quadratic vertex kernel for Connectedk-Vertex Cover and Capacitatedk-Vertex Cover on graphs of bounded twin-width. Interestingly the kernel applies to graphs of Vapnik–Chervonenkis density 1, and does not require a witness sequence. We also present a more intricate O (k 1.5) vertex kernel for Connectedk-Vertex Cover. Finally we show that deciding if a graph has twin-width at most 1 can be done in polynomial time, and observe that most optimization/decision graph problems can be solved in polynomial time on graphs of twin-width at most 1. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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