Deep Learning-Based Meta-Modeling for Multi-Objective Technology Optimization of Electrical Machines

被引:1
|
作者
Parekh, Vivek [1 ,2 ]
Flore, Dominik [2 ]
Schoeps, Sebastian [1 ]
机构
[1] Tech Univ Darmstadt, Computat Electromagnet Grp, D-64289 Darmstadt, Germany
[2] Robert Bosch GmbH, Powertrain Solut, Mech Engn & Reliabil, D-70442 Stuttgart, Germany
来源
IEEE ACCESS | 2023年 / 11卷
关键词
Optimization; Stator windings; Training; Rotors; Metamodeling; Windings; Deep learning; AC machines; Artificial neural networks; Asynchronous machine; deep neural network; key performance indicators; multi-objective optimization; permanent magnet synchronous machine; variational auto-encoder;
D O I
10.1109/ACCESS.2023.3307499
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
Optimization of rotating electrical machines is both time- and computationally expensive. Because of the different parametrization, design optimization is commonly executed separately for each machine technology. In this paper, we present the application of a variational auto-encoder (VAE) to optimize two different machine technologies simultaneously, namely an asynchronous machine and a permanent magnet synchronous machine. After training, we employ a deep neural network and a decoder as meta-models to predict global key performance indicators (KPIs) and generate associated new designs, respectively, through unified latent space in the optimization loop. Numerical results demonstrate concurrent parametric multi-objective technology optimization in the high-dimensional design space. The VAE-based approach is quantitatively compared to a classical deep learning-based direct approach for KPIs prediction.
引用
收藏
页码:93420 / 93430
页数:11
相关论文
共 50 条
  • [1] Multi-objective optimization based on meta-modeling by using support vector regression
    Yun, Yeboon
    Yoon, Min
    Nakayama, Hirotaka
    [J]. OPTIMIZATION AND ENGINEERING, 2009, 10 (02) : 167 - 181
  • [2] Multi-objective optimization based on meta-modeling by using support vector regression
    Yeboon Yun
    Min Yoon
    Hirotaka Nakayama
    [J]. Optimization and Engineering, 2009, 10 : 167 - 181
  • [3] Integrated Product Design through Multi-Objective Optimization Incorporated with Meta-Modeling Technique
    Shimizu, Yoshiaki
    Nomachi, Takayuki
    [J]. JOURNAL OF CHEMICAL ENGINEERING OF JAPAN, 2008, 41 (11) : 1068 - 1074
  • [4] Multi-Objective Topology Optimization of Rotating Machines Using Deep Learning
    Doi, Shuhei
    Sasaki, Hidenori
    Igarashi, Hajime
    [J]. IEEE TRANSACTIONS ON MAGNETICS, 2019, 55 (06)
  • [5] A Deep Learning-Based Multi-objective Optimization Model for PM2.5 Prediction
    Wenkai Xu
    Fengchen Fu
    Qingqing Zhang
    Lei Wang
    [J]. International Journal of Computational Intelligence Systems, 16
  • [6] A Deep Learning-Based Multi-objective Optimization Model for PM2.5 Prediction
    Xu, Wenkai
    Fu, Fengchen
    Zhang, Qingqing
    Wang, Lei
    [J]. INTERNATIONAL JOURNAL OF COMPUTATIONAL INTELLIGENCE SYSTEMS, 2023, 16 (01)
  • [7] Multi-objective data enhancement for deep learning-based ultrasound analysis
    Piao, Chengkai
    Lv, Mengyue
    Wang, Shujie
    Zhou, Rongyan
    Wang, Yuchen
    Wei, Jinmao
    Liu, Jian
    [J]. BMC BIOINFORMATICS, 2022, 23 (01)
  • [8] Multi-objective data enhancement for deep learning-based ultrasound analysis
    Chengkai Piao
    Mengyue Lv
    Shujie Wang
    Rongyan Zhou
    Yuchen Wang
    Jinmao Wei
    Jian Liu
    [J]. BMC Bioinformatics, 23
  • [9] Robust Design Optimization of Electrical Machines: Multi-Objective Approach
    Lei, Gang
    Bramerdorfer, Gerd
    Ma, Bo
    Guo, Youguang
    Zhu, Jianguo
    [J]. IEEE TRANSACTIONS ON ENERGY CONVERSION, 2021, 36 (01) : 390 - 401
  • [10] Machine learning-based multi-objective parameter optimization for indium electrorefining
    Fan, Hong-Qiang
    Zhu, Xuan
    Zheng, Hong-Xing
    Lu, Peng
    Wu, Mei-Zhen
    Peng, Ju-Bo
    Zhang, He-Sheng
    Qian, Quan
    [J]. SEPARATION AND PURIFICATION TECHNOLOGY, 2024, 328
12345