Showing total 2 results

1. Improved algorithms for the general exact satisfiability problem.

Author

Hoi, Gordon and Stephan, Frank

Subjects

*ALGORITHMS, *POLYNOMIALS, *POLYNOMIAL time algorithms, *ASSIGNMENT problems (Programming)

Abstract

The Exact Satisfiability problem asks if we can find a satisfying assignment to each clause such that exactly one literal in each clause is assigned 1, while the rest are all assigned 0. We can generalise this problem further by defining that a C j clause is solved iff exactly j of the literals in the clause are 1 and all others are 0. We now introduce the family of Generalised Exact Satisfiability problems called G i XSAT as the problem to check whether a given instance consisting of C j clauses with j ∈ { 0 , 1 , ... , i } for each clause has a satisfying assignment. In this paper, we present faster exact polynomial space algorithms, using a nonstandard measure, to solve G i XSAT, for i ∈ { 2 , 3 , 4 } , in O (1.3674 n) time, O (1.5687 n) time and O (1.6545 n) time, respectively, using polynomial space, where n is the number of variables. This improves the current state of the art for polynomial space algorithms from O (1.4203 n) time for G2XSAT by Zhou, Jiang and Yin and from O (1.6202 n) time for G3XSAT by Dahllöf and from O (1.6844 n) time for G4XSAT which was by Dahllöf as well. In addition, we present faster exact algorithms solving G2XSAT, G3XSAT and G4XSAT in O (1.3188 n) time, O (1.3407 n) time and O (1.3536 n) time respectively at the expense of using exponential space. [ABSTRACT FROM AUTHOR]

Published

2021

2. Revisiting maximum satisfiability and related problems in data streams.

Author

Vu, Hoa T.

Subjects

*POLYNOMIAL time algorithms, *ASSIGNMENT problems (Programming), *DATA modeling

Abstract

We revisit the maximum satisfiability problem (Max-SAT) in the data stream model. In this problem, the stream consists of m clauses that are disjunctions of literals drawn from n Boolean variables. The objective is to find an assignment to the variables that maximizes the number of satisfied clauses. Chou et al. (FOCS 2020) showed that Ω (n) space is necessary to yield a 2 / 2 + ε approximation of the optimum value; they also presented an algorithm that yields a 2 / 2 − ε approximation of the optimum value using O (ε − 2 log ⁡ n) space. In this paper, we not only focus on approximating the optimum value, but also on obtaining the corresponding Boolean assignment using sublinear o (m n) space. We present randomized single-pass algorithms that w.h.p.1 yield: • A 1 − ε approximation using O ˜ (n / ε 3) space and exponential post-processing time • A 3 / 4 − ε approximation using O ˜ (n / ε) space and polynomial post-processing time. Our ideas also extend to dynamic streams. However, we show that the streaming k -SAT problem, which asks whether one can satisfy all size- k input clauses, must use Ω (n k) space. We also consider the related minimum satisfiability problem (Min-SAT), introduced by Kohli et al. (SIAM J. Discrete Math. 1994), that asks to find an assignment that minimizes the number of satisfied clauses. For this problem, we give a O ˜ (n 2 / ε 2) space algorithm, which is sublinear when m = ω (n) , that yields an α + ε approximation where α is the approximation guarantee of the offline algorithm. If each variable appears in at most f clauses, we show that a 2 f n approximation using O ˜ (n) space is possible. Finally, for the Max-AND-SAT problem where clauses are conjunctions of literals, we show that any single-pass algorithm that approximates the optimal value up to a factor better than 1/2 with success probability at least 2/3 must use Ω (m n) space. [ABSTRACT FROM AUTHOR]

Published

2024