有效的调度，以尽量减少校准

Proceedings of the twenty-fifth annual ACM symposium on Parallelism in algorithms and architectures Pub Date : 2013-07-23 DOI:10.1145/2486159.2486193

M. A. Bender, David P. Bunde, V. Leung, Samuel McCauley, C. Phillips

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引用次数: 21

摘要

综合储备评估(ISE)是一项定期测试核武器的计划。测试由可能需要偶尔校准的机器执行。这些校准是昂贵的，因此找到一个最小化校准的时间表可以在给定的金额下完成更多的测试。本文介绍了ISE的理论框架。机器运行具有发布时间和截止日期的作业。校准机器需要单位成本。机器保持校准T个时间步，之后必须重新校准，然后才能恢复运行的作业。目标是在完成所有工作的同时尽量减少校准的次数。针对作业具有单位处理时间的情况，给出了几种求解ISE问题的算法。对于一台可用的机器，存在一个最优多项式时间算法。对于多台机器，存在一个2逼近算法，该算法在所有作业具有不同的截止日期时找到最优解。

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Efficient scheduling to minimize calibrations

Integrated Stockpile Evaluation (ISE) is a program to test nuclear weapons periodically. Tests are performed by machines that may require occasional calibration. These calibrations are expensive, so finding a schedule that minimizes calibrations allows more testing to be done for a given amount of money. This paper introduces a theoretical framework for ISE. Machines run jobs with release times and deadlines. Calibrating a machine requires unit cost. The machine remains calibrated for T time steps, after which it must be recalibrated before it can resume running jobs. The objective is to complete all jobs while minimizing the number of calibrations. The paper gives several algorithms to solve the ISE problem for the case where jobs have unit processing times. For one available machine, there is an optimal polynomial-time algorithm. For multiple machines, there is a 2-approximation algorithm, which finds an optimal solution when all jobs have distinct deadlines.

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Proceedings of the twenty-fifth annual ACM symposium on Parallelism in algorithms and architectures

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