计算机科学
可扩展性
数学优化
分界
整数(计算机科学)
整数规划
上下界
规范(哲学)
航程(航空)
最优化问题
随机优化
随机规划
缩放比例
理论计算机科学
并行计算
算法
数学
程序设计语言
政治学
材料科学
数据库
复合材料
几何学
法学
数学分析
作者
Akhil Langer,Ramprasad Venkataraman,Udatta S. Palekar,Laxmikant V. Kalé
标识
DOI:10.1109/hipc.2013.6799130
摘要
Abstract---Many real-world planning problems require search-ing for an optimal solution in the face of uncertain input. One approach to is to express them as a two-stage stochastic optimization problem where the search for an optimum in one stage is informed by the evaluation of multiple possible scenarios in the other stage. If integer solutions are required, then branch-and-bound techniques are the accepted norm. However, there has been little prior work in parallelizing and scaling branch-and-bound algorithms for stochastic optimization problems. In this paper, we explore the parallelization of a two-stage stochastic integer program solved using branch-and-bound. We present a range of factors that influence the parallel design for such problems. Unlike typical, iterative scientific applications, we encounter several interesting characteristics that make it challenging to realize a scalable design. We present two design variations that navigate some of these challenges. Our designs seek to increase the exposed parallelism while delegating sequen-tial linear program solves to existing libraries. We evaluate the scalability of our designs using sample aircraft allocation problems for the US airfleet. It is important that these problems be solved quickly while evaluating large number of scenarios. Our attempts result in strong scaling to hundreds of cores for these datasets. We believe similar results are not common in literature, and that our experiences will feed usefully into further research on this topic. I.
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