Solving Problems on Graphs of High Rank-Width

Eiben, Eduard; Ganian, Robert; Szeider, Stefan

doi:10.1007/s00453-017-0290-8

Cited by 5 publications

(4 citation statements)

References 38 publications

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“…Our results fall in a recent line of work of using hybrid parameterizations [17,18,32,33,42,43,44,46,47,48,54] which simultaneously capture the connectivity structure of the input instance and properties of its optimal solutions. Several of these works give decomposition algorithms for parameterizations similar to ours; we discuss those which are most relevant.…”

Section: Related Worksupporting

confidence: 59%

“…Eiben, Ganian, and Szeider [33] introduced the hybrid parameter H-well-structure number of a graph G, which is a hybrid of the vertex-deletion distance and rankwidth of a graph. They give FPT algorithms with unspecified parameter dependence f (k) to compute the corresponding graph decomposition for classes H defined by a finite set of forbidden induced subgraphs, forests, and chordal graphs, and use this to solve Vertex cover parameterized by the H-well-structure number.…”

Section: Related Workmentioning

confidence: 99%

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Vertex Deletion Parameterized by Elimination Distance and Even Less

Jansen¹,

Kroon²,

Włodarczyk³

2021

Preprint

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We study the parameterized complexity of various classic vertex-deletion problems such as Odd cycle transversal, Vertex planarization, and Chordal vertex deletion under hybrid parameterizations. Existing FPT algorithms for these problems either focus on the parameterization by solution size, detecting solutions of size k in time f (k) • n O(1) , or width parameterizations, finding arbitrarily large optimal solutions in time f (w) • n O(1) for some width measure w like treewidth. We unify these lines of research by presenting FPT algorithms for

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Section: Related Worksupporting

confidence: 59%

Section: Related Workmentioning

confidence: 99%

Vertex Deletion Parameterized by Elimination Distance and Even Less

Jansen¹,

Kroon²,

Włodarczyk³

2021

Preprint

View full text Add to dashboard Cite

show abstract

“…A subset of the authors previously studied modulator-based parameters that used graph splits and rank-width. The resulting well-structured modulators could either dominate rank-width [19], or (depending on the specific constants used) be used to obtain polynomial kernels for a variety of problems [18]. Since R c -treewidth lies "between" treewidth and rank-width, it is clear that our class of parameters is different from these previously studied ones.…”

Section: Introductionmentioning

confidence: 99%

Measuring what Matters: A Hybrid Approach to Dynamic Programming with Treewidth

Eiben¹,

Ganian²,

Hamm³

et al. 2019

Preprint

Self Cite

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We develop a framework for applying treewidth-based dynamic programming on graphs with "hybrid structure", i.e., with parts that may not have small treewidth but instead possess other structural properties. Informally, this is achieved by defining a refinement of treewidth which only considers parts of the graph that do not belong to a pre-specified tractable graph class. Our approach allows us to not only generalize existing fixed-parameter algorithms exploiting treewidth, but also fixedparameter algorithms which use the size of a modulator as their parameter. As the flagship application of our framework, we obtain a parameter that combines treewidth and rank-width to obtain fixed-parameter algorithms for CHROMATIC NUMBER, HAMILTONIAN CYCLE, and MAX-CUT.

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“…On the algorithmic side, the study of heterogeneous parameterizations has been gaining traction [6,7,22,24,23,32,39], yielding the notions of H-treewidth and H-elimination distance, which is a generalization of treedepth, where H is a class of graphs. In particular, the problem of computing H-elimination distance is receiving considerable attention [1,2,3,25,38].…”

Section: Introductionmentioning

confidence: 99%

Towards exact structural thresholds for parameterized complexity

Hegerfeld¹,

Kratsch²

2021

Preprint

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Parameterized complexity seeks to optimally use input structure to obtain faster algorithms for NP-hard problems. This has been most successful for graphs of low treewidth, i.e., graphs decomposable by small separators: Many problems admit fast algorithms relative to treewidth and many of them are optimal under the Strong Exponential-Time Hypothesis (SETH). Fewer such results are known for more general structure such as low clique-width (decomposition by possibly large and dense but structured separators) and more restrictive structure such as low deletion distance to some sparse graph class.Despite these successes, such results remain "islands" within the realm of possible structure. Rather than adding more islands, we seek to determine the transitions between them, that is, we aim for structural thresholds where the complexity increases as input structure becomes more general. Going from deletion distance to treewidth, is a single deletion set to a graph with simple components enough to yield the same lower bound as for treewidth or does it take many disjoint separators? Going from treewidth to clique-width, how much more density entails the same complexity as clique-width? Conversely, what is the most restrictive structure that yields the same lower bound?For treewidth, we obtain both refined and new lower bounds that apply already to graphs with a single separator X such that G− X has treewidth at most r = O(1), while G has treewidth |X| + O(1). We rule out algorithms running in time O * ((r + 1 − ε) k ) for Deletion to r-Colorable parameterized by k = |X|; this implies the same lower bound relative to treedepth and (hence) also to treewidth. It specializes to O * ((3 − ε) k ) for Odd Cycle Transversal where tw(G − X) ≤ r = 2 is best possible. For cliquewidth, an extended version of the above reduction rules out time O * ((4 − ε) k ), where X is allowed to be a possibly large separator consisting of k (true) twinclasses, while the treewidth of G − X remains r; this is proved also for the more general Deletion to r-Colorable and it implies the same lower bound relative to clique-width. Further results complement what is known for Vertex Cover, Dominating Set and Maximum Cut. All lower bounds are matched by existing and newly designed algorithms.

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Solving Problems on Graphs of High Rank-Width

Cited by 5 publications

References 38 publications

Vertex Deletion Parameterized by Elimination Distance and Even Less

Vertex Deletion Parameterized by Elimination Distance and Even Less

Measuring what Matters: A Hybrid Approach to Dynamic Programming with Treewidth

Towards exact structural thresholds for parameterized complexity

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