Showing total 7 results

1. Almost optimal query algorithm for hitting set using a subset query.

Author

Bishnu, Arijit, Ghosh, Arijit, Kolay, Sudeshna, Mishra, Gopinath, and Saurabh, Saket

Subjects

*HYPERGRAPHS, *INDEPENDENT sets, *COMBINATORIAL optimization, *ALGORITHMS

Abstract

In this paper, we focus on Hitting-Set , a fundamental problem in combinatorial optimization, through the lens of sublinear time algorithms. Given access to the hypergraph through a subset query oracle in the query model, we give sublinear time algorithms for Hitting-Set with almost tight parameterized query complexity. In parameterized query complexity , we estimate the number of queries to the oracle based on the parameter k , the size of the Hitting-Set. The subset query oracle we use in this paper is called Generalized d -partite Independent Set query oracle (GPIS) and it was introduced by Bishnu et al. (ISAAC'18). GPIS is a generalization to hypergraphs of the Bipartite Independent Set query oracle (BIS) introduced by Beame et al. (ITCS'18 and TALG'20) for estimating the number of edges in graphs. Since its introduction GPIS query oracle has been used for estimating the number of hyperedges independently by Dell et al. (SODA'20 and SICOMP'22) and Bhattacharya et al. (STACS'22), and for estimating the number of triangles in a graph by Bhattacharya et al. (ISAAC'19 and TOCS'21). Formally, GPIS is defined as follows: GPIS oracle for a d-uniform hypergraph H takes as input d pairwise disjoint non-empty subsets A 1 , ... , A d of vertices in H and answers whether there is a hyperedge in H that intersects each set A i , where i ∈ { 1 , 2 , ... , d }. For d = 2 , the GPIS oracle is nothing but BIS oracle. We show that d - Hitting-Set , the hitting set problem for d -uniform hypergraphs, can be solved using O ˜ d (k d log ⁡ n) GPIS queries. Additionally, we also showed that d - Decision-Hitting-Set , the decision version of d - Hitting-Set can be solved with O ˜ d (min ⁡ { k d log ⁡ n , k 2 d 2 }) GPIS queries. We complement these parameterized upper bounds with an almost matching parameterized lower bound that states that any algorithm that solves d - Decision-Hitting-Set requires Ω (( k + d d )) GPIS queries. [ABSTRACT FROM AUTHOR]

Published

2023

2. Markov chains and unambiguous automata.

Author

Baier, Christel, Kiefer, Stefan, Klein, Joachim, Müller, David, and Worrell, James

Subjects

*MARKOV processes, *ALGORITHMS

Abstract

Unambiguous automata are nondeterministic automata in which every word has at most one accepting run. In this paper we give a polynomial-time algorithm for model checking discrete-time Markov chains against ω -regular specifications represented as unambiguous automata. We furthermore show that the complexity of this model checking problem lies in NC: the subclass of P comprising those problems solvable in poly-logarithmic parallel time. These complexity bounds match the known bounds for model checking Markov chains against specifications given as deterministic automata, notwithstanding the fact that unambiguous automata can be exponentially more succinct than deterministic automata. We report on an implementation of our procedure, including an experiment in which the implementation is used to model check LTL formulas on Markov chains. [ABSTRACT FROM AUTHOR]

Published

2023

3. Deletion to scattered graph classes II - improved FPT algorithms for deletion to pairs of graph classes.

Author

Jacob, Ashwin, Majumdar, Diptapriyo, and Raman, Venkatesh

Subjects

*ALGORITHMS, *APPROXIMATION algorithms, *BIPARTITE graphs, *LOGIC

Abstract

The problem of deletion of vertices to a hereditary graph class is a well-studied problem in parameterized complexity. Recently, a natural extension of the problem was initiated where we are given a finite set of hereditary graph classes and we determine whether k vertices can be deleted from a given graph so that the connected components of the resulting graph belong to one of the given hereditary graph classes. The problem is shown to be fixed parameter tractable (FPT) when the deletion problem to each of the given hereditary graph classes is fixed-parameter tractable, and the property of being in any of the graph classes is expressible in the counting monodic second order (CMSO) logic. This paper focuses on pairs of specific graph classes (Π 1 , Π 2) in which we would like the connected components of the resulting graph to belong to, and design simpler and more efficient FPT algorithms. [ABSTRACT FROM AUTHOR]

Published

2023

4. Grid recognition: Classical and parameterized computational perspectives.

Author

Gupta, Siddharth, Sa'ar, Guy, and Zehavi, Meirav

Subjects

*PARAMETERIZATION, *ALGORITHMS, *TREES

Abstract

Over the past few decades, a large body of works studied the (in)tractability of various computational problems on grid graphs, which often yield substantially faster algorithms than general graphs. Unfortunately, the recognition of a grid graph is hard—it was shown to be NP-hard already in 1987. In this paper, we provide several positive results in this regard in the framework of parameterized complexity. Specifically, our contribution is threefold. First, we show that the problem is FPT parameterized by k + mcc where mcc is the maximum size of a connected component of G. Second, we present a new parameterization, denoted a G , relating graph distance to geometric distance. We show that the problem is para-NP-hard parameterized by a G , but FPT parameterized by a G on trees, as well as FPT parameterized by k + a G. Third, we show that the recognition of k × r grid graphs is NP-hard on graphs of pathwidth 2 where k = 3. [ABSTRACT FROM AUTHOR]

Published

2023

5. Medians in median graphs and their cube complexes in linear time.

Author

Bénéteau, Laurine, Chalopin, Jérémie, Chepoi, Victor, and Vaxès, Yann

Subjects

*CUBES, *CHARTS, diagrams, etc., *TIME, *ALGORITHMS

Abstract

The median of a set of vertices P of a graph G is the set of all vertices x of G minimizing the sum of distances from x to all vertices of P. In this paper, we present a linear time algorithm to compute medians in median graphs. We also present a linear time algorithm to compute medians in the associated ℓ 1 -cube complexes. Our algorithm is based on the majority rule characterization of medians in median graphs and on a fast computation of parallelism classes of edges (Θ-classes) via Lexicographic Breadth First Search (LexBFS). We show that any LexBFS ordering of the vertices of a median graph satisfies the following fellow traveler property : the parents of any two adjacent vertices are also adjacent. Using the fast computation of the Θ-classes, we also compute the Wiener index (total distance) in linear time and the distance matrix in optimal quadratic time. [ABSTRACT FROM AUTHOR]

Published

2022

6. Word equations in non-deterministic linear space.

Author

Jeż, Artur

Subjects

*VECTOR spaces, *LINEAR equations, *ALGORITHMS, *COMPUTATIONAL complexity, *HUFFMAN codes, *VOCABULARY, *DETERMINISTIC algorithms

Abstract

Satisfiability of word equations problem is: Given two sequences consisting of letters and variables decide whether there is a substitution for the variables that turns this equation into true equality. The exact computational complexity of this problem remains unknown, with the best lower and upper bounds being, respectively, NP and PSPACE. Recently, the novel technique of recompression was applied to this problem, simplifying the known proofs and lowering the space complexity to (non-deterministic) O (n log ⁡ n). In this paper we show that satisfiability of word equations is in non-deterministic linear space, thus the language of satisfiable word equations is context-sensitive. We use the known recompression-based algorithm and additionally employ Huffman coding for letters. The proof, however, uses analysis of how the fragments of the equation depend on each other as well as a new strategy for non-deterministic choices of the algorithm. [ABSTRACT FROM AUTHOR]

Published

2022

7. Frameworks for designing in-place graph algorithms.

Author

Chakraborty, Sankardeep, Mukherjee, Anish, Raman, Venkatesh, and Satti, Srinivasa Rao

Subjects

*GRAPH algorithms, *REDUCED-order models, *ALGORITHMS

Abstract

Read-only memory (ROM) model is a classical model of computation to study time-space tradeoffs of algorithms. More recently, several graph algorithms have been studied under ROM model. In this paper, we study graph algorithms under two different relaxations of ROM model, referred to as the implicit and rotate models, and show that these simple relaxations allow us to implement fundamental graph search methods like BFS and DFS more space efficiently than in ROM model. All our algorithms are simple but quite subtle, and we believe that these models are practical enough to spur interest for other graph problems in these models. [ABSTRACT FROM AUTHOR]

Published

2022