{"title":"UTVPI约束系统中的约束只读一次驳斥:并行视角","authors":"K. Subramani, Piotr Wojciechowski","doi":"10.1017/s0960129523000300","DOIUrl":null,"url":null,"abstract":"Abstract In this paper, we analyze two types of refutations for Unit Two Variable Per Inequality (UTVPI) constraints. A UTVPI constraint is a linear inequality of the form: $a_{i}\\cdot x_{i}+a_{j} \\cdot x_{j} \\le b_{k}$ , where $a_{i},a_{j}\\in \\{0,1,-1\\}$ and $b_{k} \\in \\mathbb{Z}$ . A conjunction of such constraints is called a UTVPI constraint system (UCS) and can be represented in matrix form as: ${\\bf A \\cdot x \\le b}$ . UTVPI constraints are used in many domains including operations research and program verification. We focus on two variants of read-once refutation (ROR). An ROR is a refutation in which each constraint is used at most once. A literal-once refutation (LOR), a more restrictive form of ROR, is a refutation in which each literal ( $x_i$ or $-x_i$ ) is used at most once. First, we examine the constraint-required read-once refutation (CROR) problem and the constraint-required literal-once refutation (CLOR) problem. In both of these problems, we are given a set of constraints that must be used in the refutation. RORs and LORs are incomplete since not every system of linear constraints is guaranteed to have such a refutation. This is still true even when we restrict ourselves to UCSs. In this paper, we provide NC reductions between the CROR and CLOR problems in UCSs and the minimum weight perfect matching problem. The reductions used in this paper assume a CREW PRAM model of parallel computation. As a result, the reductions establish that, from the perspective of parallel algorithms, the CROR and CLOR problems in UCSs are equivalent to matching. In particular, if an NC algorithm exists for either of these problems, then there is an NC algorithm for matching.","PeriodicalId":49855,"journal":{"name":"Mathematical Structures in Computer Science","volume":"25 1","pages":"0"},"PeriodicalIF":0.4000,"publicationDate":"2023-09-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Constrained read-once refutations in UTVPI constraint systems: A parallel perspective\",\"authors\":\"K. Subramani, Piotr Wojciechowski\",\"doi\":\"10.1017/s0960129523000300\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Abstract In this paper, we analyze two types of refutations for Unit Two Variable Per Inequality (UTVPI) constraints. A UTVPI constraint is a linear inequality of the form: $a_{i}\\\\cdot x_{i}+a_{j} \\\\cdot x_{j} \\\\le b_{k}$ , where $a_{i},a_{j}\\\\in \\\\{0,1,-1\\\\}$ and $b_{k} \\\\in \\\\mathbb{Z}$ . A conjunction of such constraints is called a UTVPI constraint system (UCS) and can be represented in matrix form as: ${\\\\bf A \\\\cdot x \\\\le b}$ . UTVPI constraints are used in many domains including operations research and program verification. We focus on two variants of read-once refutation (ROR). An ROR is a refutation in which each constraint is used at most once. A literal-once refutation (LOR), a more restrictive form of ROR, is a refutation in which each literal ( $x_i$ or $-x_i$ ) is used at most once. First, we examine the constraint-required read-once refutation (CROR) problem and the constraint-required literal-once refutation (CLOR) problem. In both of these problems, we are given a set of constraints that must be used in the refutation. RORs and LORs are incomplete since not every system of linear constraints is guaranteed to have such a refutation. This is still true even when we restrict ourselves to UCSs. 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引用次数: 0
摘要
摘要本文分析了Unit two Variable Per Inequality (UTVPI)约束的两类反驳。UTVPI约束是如下形式的线性不等式:$a_{i}\cdot x_{i}+a_{j} \cdot x_{j} \le b_{k}$,其中$a_{i},a_{j}\in \{0,1,-1\}$和$b_{k} \in \mathbb{Z}$。这些约束的结合称为UTVPI约束系统(UCS),可以用矩阵形式表示为:${\bf A \cdot x \le b}$。UTVPI约束被广泛应用于运筹学和程序验证等领域。我们重点讨论了两次读一次驳斥(ROR)的变体。ROR是一种驳斥,其中每个约束最多使用一次。一次字面量反驳(LOR)是一种更严格的ROR形式,它是一种反驳,其中每个字面量($x_i$或$-x_i$)最多使用一次。首先,我们研究了约束要求读一次反驳(CROR)问题和约束要求字面一次反驳(CLOR)问题。在这两个问题中,我们都给定了一组必须在反驳中使用的约束。error和lor是不完全的,因为不是每个线性约束系统都保证有这样的反驳。即使我们将自己限制为ucs,这仍然是正确的。在本文中,我们提供了ucs中CROR和CLOR问题之间的NC约简以及最小权值完美匹配问题。本文所使用的缩减假设了并行计算的CREW PRAM模型。因此,约简表明,从并行算法的角度来看,ucs中的CROR和CLOR问题等价于匹配。特别地,如果对于这两个问题中的任何一个存在NC算法,那么就存在匹配的NC算法。
Constrained read-once refutations in UTVPI constraint systems: A parallel perspective
Abstract In this paper, we analyze two types of refutations for Unit Two Variable Per Inequality (UTVPI) constraints. A UTVPI constraint is a linear inequality of the form: $a_{i}\cdot x_{i}+a_{j} \cdot x_{j} \le b_{k}$ , where $a_{i},a_{j}\in \{0,1,-1\}$ and $b_{k} \in \mathbb{Z}$ . A conjunction of such constraints is called a UTVPI constraint system (UCS) and can be represented in matrix form as: ${\bf A \cdot x \le b}$ . UTVPI constraints are used in many domains including operations research and program verification. We focus on two variants of read-once refutation (ROR). An ROR is a refutation in which each constraint is used at most once. A literal-once refutation (LOR), a more restrictive form of ROR, is a refutation in which each literal ( $x_i$ or $-x_i$ ) is used at most once. First, we examine the constraint-required read-once refutation (CROR) problem and the constraint-required literal-once refutation (CLOR) problem. In both of these problems, we are given a set of constraints that must be used in the refutation. RORs and LORs are incomplete since not every system of linear constraints is guaranteed to have such a refutation. This is still true even when we restrict ourselves to UCSs. In this paper, we provide NC reductions between the CROR and CLOR problems in UCSs and the minimum weight perfect matching problem. The reductions used in this paper assume a CREW PRAM model of parallel computation. As a result, the reductions establish that, from the perspective of parallel algorithms, the CROR and CLOR problems in UCSs are equivalent to matching. In particular, if an NC algorithm exists for either of these problems, then there is an NC algorithm for matching.
期刊介绍:
Mathematical Structures in Computer Science is a journal of theoretical computer science which focuses on the application of ideas from the structural side of mathematics and mathematical logic to computer science. The journal aims to bridge the gap between theoretical contributions and software design, publishing original papers of a high standard and broad surveys with original perspectives in all areas of computing, provided that ideas or results from logic, algebra, geometry, category theory or other areas of logic and mathematics form a basis for the work. The journal welcomes applications to computing based on the use of specific mathematical structures (e.g. topological and order-theoretic structures) as well as on proof-theoretic notions or results.