@online{Esmer2206.13481,
TITLE = {Faster Exponential-Time Approximation Algorithms Using Approximate Monotone Local Search},
AUTHOR = {Esmer, Bar{\i}{\c s} Can and Kulik, Ariel and Marx, D{\'a}niel and Neuen, Daniel and Sharma, Roohani},
LANGUAGE = {eng},
URL = {https://arxiv.org/abs/2206.13481},
EPRINT = {2206.13481},
EPRINTTYPE = {arXiv},
YEAR = {2022},
ABSTRACT = {We generalize the monotone local search approach of Fomin, Gaspers,<br>Lokshtanov and Saurabh [J.ACM 2019], by establishing a connection between<br>parameterized approximation and exponential-time approximation algorithms for<br>monotone subset minimization problems. In a monotone subset minimization<br>problem the input implicitly describes a non-empty set family over a universe<br>of size $n$ which is closed under taking supersets. The task is to find a<br>minimum cardinality set in this family. Broadly speaking, we use approximate<br>monotone local search to show that a parameterized $\alpha$-approximation<br>algorithm that runs in $c^k \cdot n^{O(1)}$ time, where $k$ is the solution<br>size, can be used to derive an $\alpha$-approximation randomized algorithm that<br>runs in $d^n \cdot n^{O(1)}$ time, where $d$ is the unique value in $d \in<br>(1,1+\frac{c-1}{\alpha})$ such that<br>$\mathcal{D}(\frac{1}{\alpha}\|\frac{d-1}{c-1})=\frac{\ln c}{\alpha}$ and<br>$\mathcal{D}(a \|b)$ is the Kullback-Leibler divergence. This running time<br>matches that of Fomin et al. for $\alpha=1$, and is strictly better when<br>$\alpha >1$, for any $c > 1$. Furthermore, we also show that this result can be<br>derandomized at the expense of a sub-exponential multiplicative factor in the<br>running time.<br> We demonstrate the potential of approximate monotone local search by deriving<br>new and faster exponential approximation algorithms for Vertex Cover,<br>$3$-Hitting Set, Directed Feedback Vertex Set, Directed Subset Feedback Vertex<br>Set, Directed Odd Cycle Transversal and Undirected Multicut. For instance, we<br>get a $1.1$-approximation algorithm for Vertex Cover with running time $1.114^n<br>\cdot n^{O(1)}$, improving upon the previously best known $1.1$-approximation<br>running in time $1.127^n \cdot n^{O(1)}$ by Bourgeois et al. [DAM 2011].<br>},
}