在高维问题中改进自适应代用模型的主动学习。

IF 3.6 2区 工程技术 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Yulin Guo, Paromita Nath, Sankaran Mahadevan, Paul Witherell
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引用次数: 0

摘要

本文研究了一种新方法,用于在具有高维输入和输出的问题中高效构建和改进代理模型。在这种方法中,首先要确定高维输出的主成分和相应特征。对于每个特征,使用主动子空间技术识别输入域的相应低维子空间;然后在相应的主动子空间中为每个特征建立代用模型。我们提出了一种低维自适应学习策略,用于识别训练样本以改进代理模型。与关注标量输出或少量输出的现有自适应学习方法相比,本文针对高维输入和输出的自适应学习,采用了一种新的学习函数,在探索和利用之间取得了平衡,即分别考虑了未探索区域和高误差区域。自适应学习以低维空间中的活动变量为单位,新添加的训练样本可以很容易地映射回原始空间,以运行昂贵的物理模型。所提出的方法在增材制造部件的数值模拟中得到了验证,该部件的高维场输出量(残余应力)由于多个输入变量(包括过程变量和材料属性)的随机性而具有空间可变性。研究了自适应学习过程中的各种因素,包括训练样本的数量、自适应训练样本的范围和分布、各种误差的贡献以及学习函数中探索与利用的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Active learning for adaptive surrogate model improvement in high-dimensional problems.

This paper investigates a novel approach to efficiently construct and improve surrogate models in problems with high-dimensional input and output. In this approach, the principal components and corresponding features of the high-dimensional output are first identified. For each feature, the active subspace technique is used to identify a corresponding low-dimensional subspace of the input domain; then a surrogate model is built for each feature in its corresponding active subspace. A low-dimensional adaptive learning strategy is proposed to identify training samples to improve the surrogate model. In contrast to existing adaptive learning methods that focus on a scalar output or a small number of outputs, this paper addresses adaptive learning with high-dimensional input and output, with a novel learning function that balances exploration and exploitation, i.e., considering unexplored regions and high-error regions, respectively. The adaptive learning is in terms of the active variables in the low-dimensional space, and the newly added training samples can be easily mapped back to the original space for running the expensive physics model. The proposed method is demonstrated for the numerical simulation of an additive manufacturing part, with a high-dimensional field output quantity of interest (residual stress) in the component that has spatial variability due to the stochastic nature of multiple input variables (including process variables and material properties). Various factors in the adaptive learning process are investigated, including the number of training samples, range and distribution of the adaptive training samples, contributions of various errors, and the importance of exploration versus exploitation in the learning function.

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来源期刊
Structural and Multidisciplinary Optimization
Structural and Multidisciplinary Optimization 工程技术-工程:综合
CiteScore
7.60
自引率
15.40%
发文量
304
审稿时长
3.6 months
期刊介绍: The journal’s scope ranges from mathematical foundations of the field to algorithm and software development, and from benchmark examples to case studies of practical applications in structural, aero-space, mechanical, civil, chemical, naval and bio-engineering. Fields such as computer-aided design and manufacturing, uncertainty quantification, artificial intelligence, system identification and modeling, inverse processes, computer simulation, bio-mechanics, bio-medical applications, nano-technology, MEMS, optics, chemical processes, computational biology, meta-modeling, DOE and active control of structures are covered when the topic is closely related to the optimization of structures or fluids. Structural and Multidisciplinary Optimization publishes original research papers, review articles, industrial applications, brief notes, educational articles, book reviews, conference diary, forum section, discussions on papers, authors´ replies, obituaries, announcements and society news.
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