图像连通性测试

IF 1.3 4区物理与天体物理 Q4 PHYSICS, APPLIED

Spin Pub Date : 2023-12-06 DOI:10.4230/LIPIcs.APPROX/RANDOM.2023.66

Piotr Berman, Meiram Murzabulatov, Sofya Raskhodnikova, Dragos Ristache

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引用次数: 0

摘要

我们研究了用于测试图像是否连接的算法。给定接近度参数λ∈(0,1)，以及对由布尔像素值的n × n矩阵表示的黑白图像的查询访问权，如果图像是连通的，则(单侧误差)连通度测试器接受，如果图像是远离连通的，则拒绝的概率至少为2/3。我们证明了连通性可以用O (1 λ 2)查询进行非自适应测试，也可以用O (1 λ 3 / 2p log 1 λ)查询进行自适应测试。迄今为止，由Berman、Raskhodnikova和Yaroslavtsev (STOC 2014)设计的最佳连通性测试仪的查询复杂度为O (1 λ 2 log 1 λ)，并且具有自适应性。我们也证明了每一个非自适应的、单侧的连通性误差测试仪必须进行Ω(1 λ log 1 λ)查询。

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Testing Connectedness of Images

We investigate algorithms for testing whether an image is connected. Given a proximity parameter $\epsilon\in(0,1)$ and query access to a black-and-white image represented by an $n\times n$ matrix of Boolean pixel values, a (1-sided error) connectedness tester accepts if the image is connected and rejects with probability at least 2/3 if the image is $\epsilon$-far from connected. We show that connectedness can be tested nonadaptively with $O(\frac 1{\epsilon^2})$ queries and adaptively with $O(\frac{1}{\epsilon^{3/2}} \sqrt{\log\frac{1}{\epsilon}})$ queries. The best connectedness tester to date, by Berman, Raskhodnikova, and Yaroslavtsev (STOC 2014) had query complexity $O(\frac 1{\epsilon^2}\log \frac 1{\epsilon})$ and was adaptive. We also prove that every nonadaptive, 1-sided error tester for connectedness must make $\Omega(\frac 1\epsilon\log \frac 1\epsilon)$ queries.

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来源期刊

Spin Materials Science-Electronic, Optical and Magnetic Materials

CiteScore

2.10

自引率

11.10%

发文量

期刊介绍： Spin electronics encompasses a multidisciplinary research effort involving magnetism, semiconductor electronics, materials science, chemistry and biology. SPIN aims to provide a forum for the presentation of research and review articles of interest to all researchers in the field. The scope of the journal includes (but is not necessarily limited to) the following topics: *Materials: -Metals -Heusler compounds -Complex oxides: antiferromagnetic, ferromagnetic -Dilute magnetic semiconductors -Dilute magnetic oxides -High performance and emerging magnetic materials *Semiconductor electronics *Nanodevices: -Fabrication -Characterization *Spin injection *Spin transport *Spin transfer torque *Spin torque oscillators *Electrical control of magnetic properties *Organic spintronics *Optical phenomena and optoelectronic spin manipulation *Applications and devices: -Novel memories and logic devices -Lab-on-a-chip -Others *Fundamental and interdisciplinary studies: -Spin in low dimensional system -Spin in medical sciences -Spin in other fields -Computational materials discovery