New Results on the Remote Set Problem and Its Applications in Complexity Study

IF 0.6 4区 计算机科学 Q4 COMPUTER SCIENCE, THEORY & METHODS
Yijie Chen, Kewei Lv
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Abstract

In 2015, Haviv introduced the Remote set problem (RSP) and studied the complexity of the covering radius problem (CRP), which is a classical problem in lattices. The RSP aims to identify a set containing a point that is sufficiently distant from a given lattice \(\pmb {\mathcal {L}}\). It introduced a new method for analyzing the complexity of CRP. An open question in RSP is whether we can obtain the approximation factor \(\gamma =1/2\). This paper investigates this question and proposes a probabilistic polynomial-time algorithm for RSP with an approximation factor of \(1/2-1/(c\lambda ^{(p)}_n)\), where \(c\in \mathbb {Z}^{+}\) and \(\lambda ^{(p)}_n\) is the n-th successive minima in lattice under \(l_p\)-norm. For a given lattice \(\pmb {\mathcal {L}}\) with rank n and positive integer d, our algorithm outputs a set S of size d in polynomial time. This set S includes a point at least \((\frac{1}{2}-\frac{1}{c\lambda ^{(p)}_n}){{\rho }^{(p)}}(\pmb {\mathcal {L}})\) from lattice \(\pmb {\mathcal {L}}\) with a probability greater than \(1-1/2^d\). Here, c is a positive integer and \(\rho ^{(p)}(\pmb {\mathcal {L}})\) denotes the covering radius of \(\pmb {\mathcal {L}}\) in \(l_p\)-norm(\(1\le p\le \infty \)). Based on this, we obtain that \(\text {GAPCRP}_{2+1/2^{O(n)}}\) belongs to the complexity class coRP, and we provide new reductions from GAPCRP to GAPCVP.

Abstract Image

远程集问题的新成果及其在复杂性研究中的应用
2015 年,哈维夫提出了远程集问题(RSP),并研究了覆盖半径问题(CRP)的复杂性,这是网格中的一个经典问题。RSP 的目的是找出一个包含一个点的集合,该点与给定的网格有足够的距离(\pmb {math\cal {L}}\)。它引入了一种分析 CRP 复杂性的新方法。RSP 中一个悬而未决的问题是我们能否得到近似因子 \(\gamma =1/2/\)。本文研究了这个问题,并提出了一种 RSP 的概率多项式时间算法,其近似因子为 (1/2-1/(c\lambda ^{(p)}_n)\) ,其中 (c\in \mathbb {Z}^{+}\) 和 (lambda ^{(p)}_n\) 是 \(l_p\)-norm 下网格中的 n 次连续最小值。对于秩为 n、正整数为 d 的给定网格 \(\pmb {\mathcal {L}}\) ,我们的算法会在多项式时间内输出一个大小为 d 的集合 S。这个集合 S 包含了至少一个来自网格 \(\pmb {\mathcal {L}}\)的点,且概率大于 \(1-1/2^d\)。这里,c 是一个正整数,(rho ^{(p)}(\pmb {mathcal {L}})表示 \(\pmb {mathcal {L}})在 \(l_p\)-norm(\(1\le p\le \infty \))中的覆盖半径。)在此基础上,我们得到(text {GAPCRP}_{2+1/2^{O(n)}} )属于复杂度类 coRP,并提供了从 GAPCRP 到 GAPCVP 的新还原。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Theory of Computing Systems
Theory of Computing Systems 工程技术-计算机:理论方法
CiteScore
1.90
自引率
0.00%
发文量
36
审稿时长
6-12 weeks
期刊介绍: TOCS is devoted to publishing original research from all areas of theoretical computer science, ranging from foundational areas such as computational complexity, to fundamental areas such as algorithms and data structures, to focused areas such as parallel and distributed algorithms and architectures.
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