基于局部惩罚的批处理贝叶斯主动学习可行区域识别

Jixiang Qing, Nicolas Knudde, I. Couckuyt, Tom Dhaene, Kohei Shintani
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引用次数: 1

摘要

识别满足一组约束条件的所有设计是工程设计过程的重要组成部分。对于基于物理的仿真代码,评估约束变得相当昂贵。主动学习可以提供一种优雅的方法来有效地表征可行区域,即可行设计集。虽然主动学习策略已被提出用于此任务,但大多数都是处理每次迭代只添加一个样本,而不是每次迭代选择多个样本,也称为批处理主动学习。虽然就每次迭代获得的信息量而言,这是有效的,但它忽略了可用的计算资源。在假设约束函数为Lipschitz连续的前提下,提出了一种批量贝叶斯主动学习方法用于可行区域识别。此外,我们扩展了目前最先进的批处理方法,也处理可行的区域识别。实验结果表明,该方法优于扩展批处理方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Batch Bayesian Active Learning For Feasible Region Identification by Local Penalization
Identifying all designs satisfying a set of constraints is an important part of the engineering design process. With physics-based simulation codes, evaluating the constraints becomes considerable expensive. Active learning can provide an elegant approach to efficiently characterize the feasible region, i.e., the set of feasible designs. Although active learning strategies have been proposed for this task, most of them are dealing with adding just one sample per iteration as opposed to selecting multiple samples per iteration, also known as batch active learning. While this is efficient with respect to the amount of information gained per iteration, it neglects available computation resources. We propose a batch Bayesian active learning technique for feasible region identification by assuming that the constraint function is Lipschitz continuous. In addition, we extend current state-of-the-art batch methods to also handle feasible region identification. Experiments show better performance of the proposed method than the extended batch methods.
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