Brief announcement: pan and scan

Proceedings of the 29th ACM SIGACT-SIGOPS symposium on Principles of distributed computing Pub Date : 2010-07-25 DOI:10.1145/1835698.1835729

Matthew P. Johnson, A. Bar-Noy

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Abstract

We introduce the pan and scan problem, in which cameras are configured to observe multiple target locations. A camera's configuration consists of its orientation and its zoom factor or field or view (its position is given); the quality of a target's reading by a camera depends (inversely) on both the distance and field of view. After briefly discussing an easy setting in which a target accumulates measurement quality from all cameras observing it, we move on to a more challenging setting in which for each target only the best measurement of it is counted, for which we give various results. Although both variants admit continuous solutions, we observe that we may restrict our attention to solutions based on pinned cones. For a geometrically constrained setting, we give an optimal dynamic programming algorithm. For the unconstrained setting of this problem, we prove NP-hardness, present efficient centralized and distributed 2-approximation algorithms, and observe that a PTAS exists under certain assumptions. For a synchronized distributed setting, we give a 2-approximation protocol and a (2β)/(1-α)-approximation protocol (for all 0 ≤ α ≤ 1 and β ≥ 1) with the stability feature that no target's camera assignment changes more than logβ(m/α) times. We also discuss the running times of the algorithms and study the speed-ups that are possible in certain situations.

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简短公告:平移和扫描

我们介绍了平移和扫描问题，其中摄像机被配置为观察多个目标位置。相机的配置包括它的方向和它的变焦系数或视野或视图(它的位置是给定的);相机读取目标的质量(反比)取决于距离和视场。在简要讨论了一种简单的设置后，目标从观察它的所有相机中积累测量质量，我们继续讨论一种更具挑战性的设置，其中每个目标只计算最佳测量结果，我们给出各种结果。虽然这两种变体都承认连续解，但我们注意到，我们可以将注意力限制在基于固定锥的解上。对于几何约束条件，给出了一种最优动态规划算法。对于该问题的无约束设置，我们证明了np -硬度，给出了有效的集中式和分布式2-逼近算法，并观察到在一定的假设条件下存在PTAS。对于同步分布设置，我们给出了2-逼近协议和(2β)/(1-α)-逼近协议(对于所有0≤α≤1和β≥1)，其稳定性特征是目标的相机分配变化不超过logβ(m/α)次。我们还讨论了算法的运行时间，并研究了在某些情况下可能的加速。

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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Proceedings of the 29th ACM SIGACT-SIGOPS symposium on Principles of distributed computing

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